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Tbarkin121/GuardDog/stm32/AnymalNet/X-CUBE-AI/App/app_x-cube-ai.c |
/**
******************************************************************************
* @file app_x-cube-ai.c
* @author X-CUBE-AI C code generator
* @brief AI program body
******************************************************************************
* @attention
*
* Copyright (c) 2024 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/*
* Description
* v1.0 - Minimum template to show how to use the Embedded Client API
* model. Only one input and one output is supported. All
* memory resources are allocated statically (AI_NETWORK_XX, defines
* are used).
* Re-target of the printf function is out-of-scope.
* v2.0 - add multiple IO and/or multiple heap support
*
* For more information, see the embeded documentation:
*
* [1] %X_CUBE_AI_DIR%/Documentation/index.html
*
* X_CUBE_AI_DIR indicates the location where the X-CUBE-AI pack is installed
* typical : C:\Users\<user_name>\STM32Cube\Repository\STMicroelectronics\X-CUBE-AI\7.1.0
*/
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#if defined ( __ICCARM__ )
#elif defined ( __CC_ARM ) || ( __GNUC__ )
#endif
/* System headers */
#include <stdint.h>
#include <stdlib.h>
#include <stdio.h>
#include <inttypes.h>
#include <string.h>
#include "app_x-cube-ai.h"
#include "main.h"
#include "ai_datatypes_defines.h"
#include "network.h"
#include "network_data.h"
/* USER CODE BEGIN includes */
/* USER CODE END includes */
/* IO buffers ----------------------------------------------------------------*/
#if !defined(AI_NETWORK_INPUTS_IN_ACTIVATIONS)
AI_ALIGNED(4) ai_i8 data_in_1[AI_NETWORK_IN_1_SIZE_BYTES];
ai_i8* data_ins[AI_NETWORK_IN_NUM] = {
data_in_1
};
#else
ai_i8* data_ins[AI_NETWORK_IN_NUM] = {
NULL
};
#endif
#if !defined(AI_NETWORK_OUTPUTS_IN_ACTIVATIONS)
AI_ALIGNED(4) ai_i8 data_out_1[AI_NETWORK_OUT_1_SIZE_BYTES];
AI_ALIGNED(4) ai_i8 data_out_2[AI_NETWORK_OUT_2_SIZE_BYTES];
AI_ALIGNED(4) ai_i8 data_out_3[AI_NETWORK_OUT_3_SIZE_BYTES];
ai_i8* data_outs[AI_NETWORK_OUT_NUM] = {
data_out_1,
data_out_2,
data_out_3
};
#else
ai_i8* data_outs[AI_NETWORK_OUT_NUM] = {
NULL,
NULL,
NULL
};
#endif
/* Activations buffers -------------------------------------------------------*/
AI_ALIGNED(32)
static uint8_t pool0[AI_NETWORK_DATA_ACTIVATION_1_SIZE];
ai_handle data_activations0[] = {pool0};
/* AI objects ----------------------------------------------------------------*/
static ai_handle network = AI_HANDLE_NULL;
static ai_buffer* ai_input;
static ai_buffer* ai_output;
static void ai_log_err(const ai_error err, const char *fct)
{
/* USER CODE BEGIN log */
if (fct)
printf("TEMPLATE - Error (%s) - type=0x%02x code=0x%02x\r\n", fct,
err.type, err.code);
else
printf("TEMPLATE - Error - type=0x%02x code=0x%02x\r\n", err.type, err.code);
do {} while (1);
/* USER CODE END log */
}
static int ai_boostrap(ai_handle *act_addr)
{
ai_error err;
/* Create and initialize an instance of the model */
err = ai_network_create_and_init(&network, act_addr, NULL);
if (err.type != AI_ERROR_NONE) {
ai_log_err(err, "ai_network_create_and_init");
return -1;
}
ai_input = ai_network_inputs_get(network, NULL);
ai_output = ai_network_outputs_get(network, NULL);
#if defined(AI_NETWORK_INPUTS_IN_ACTIVATIONS)
/* In the case where "--allocate-inputs" option is used, memory buffer can be
* used from the activations buffer. This is not mandatory.
*/
for (int idx=0; idx < AI_NETWORK_IN_NUM; idx++) {
data_ins[idx] = ai_input[idx].data;
}
#else
for (int idx=0; idx < AI_NETWORK_IN_NUM; idx++) {
ai_input[idx].data = data_ins[idx];
}
#endif
#if defined(AI_NETWORK_OUTPUTS_IN_ACTIVATIONS)
/* In the case where "--allocate-outputs" option is used, memory buffer can be
* used from the activations buffer. This is no mandatory.
*/
for (int idx=0; idx < AI_NETWORK_OUT_NUM; idx++) {
data_outs[idx] = ai_output[idx].data;
}
#else
for (int idx=0; idx < AI_NETWORK_OUT_NUM; idx++) {
ai_output[idx].data = data_outs[idx];
}
#endif
return 0;
}
static int ai_run(void)
{
ai_i32 batch;
batch = ai_network_run(network, ai_input, ai_output);
if (batch != 1) {
ai_log_err(ai_network_get_error(network),
"ai_network_run");
return -1;
}
return 0;
}
/* USER CODE BEGIN 2 */
extern ai_float in_data1[AI_NETWORK_IN_1_SIZE];
extern ai_float out_data1[AI_NETWORK_OUT_1_SIZE];
extern ai_float out_data2[AI_NETWORK_OUT_2_SIZE];
extern ai_float out_data3[AI_NETWORK_OUT_3_SIZE];
int acquire_and_process_data(ai_i8* data[])
{
/* process the predictions
for (int idx=0; idx < AI_NETWORK_OUT_NUM; idx++ )
{
data[idx] = ....
}
*/
// Cast data_ins[0] to a pointer of type ai_float*
memcpy(data[0], in_data1, AI_NETWORK_IN_1_SIZE * sizeof(ai_float));
return 0;
}
int post_process(ai_i8* data[])
{
/* process the predictions
for (int idx=0; idx < AI_NETWORK_OUT_NUM; idx++ )
{
data[idx] = ....
}
*/
memcpy(out_data1, data[0], AI_NETWORK_OUT_1_SIZE * sizeof(ai_float));
memcpy(out_data2, data[1], AI_NETWORK_OUT_2_SIZE * sizeof(ai_float));
memcpy(out_data3, data[2], AI_NETWORK_OUT_3_SIZE * sizeof(ai_float));
return 0;
}
/* USER CODE END 2 */
/* Entry points --------------------------------------------------------------*/
void MX_X_CUBE_AI_Init(void)
{
/* USER CODE BEGIN 5 */
printf("\r\nTEMPLATE - initialization\r\n");
ai_boostrap(data_activations0);
/* USER CODE END 5 */
}
void MX_X_CUBE_AI_Process(void)
{
/* USER CODE BEGIN 6 */
int res = -1;
printf("TEMPLATE - run - main loop\r\n");
if (network) {
// do {
/* 1 - acquire and pre-process input data */
res = acquire_and_process_data(data_ins);
/* 2 - process the data - call inference engine */
if (res == 0)
res = ai_run();
/* 3- post-process the predictions */
if (res == 0)
res = post_process(data_outs);
// } while (res==0);
}
if (res) {
ai_error err = {AI_ERROR_INVALID_STATE, AI_ERROR_CODE_NETWORK};
ai_log_err(err, "Process has FAILED");
}
/* USER CODE END 6 */
}
#ifdef __cplusplus
}
#endif
| 6,548 | C | 24.582031 | 92 | 0.583842 |
Tbarkin121/GuardDog/stm32/AnymalNet/X-CUBE-AI/App/network.h | /**
******************************************************************************
* @file network.h
* @author AST Embedded Analytics Research Platform
* @date Sat Jan 6 20:35:01 2024
* @brief AI Tool Automatic Code Generator for Embedded NN computing
******************************************************************************
* @attention
*
* Copyright (c) 2024 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
#ifndef AI_NETWORK_H
#define AI_NETWORK_H
#pragma once
#include "network_config.h"
#include "ai_platform.h"
/******************************************************************************/
#define AI_NETWORK_MODEL_NAME "network"
#define AI_NETWORK_ORIGIN_MODEL_NAME "anymal"
/******************************************************************************/
#define AI_NETWORK_ACTIVATIONS_ALIGNMENT (4)
#define AI_NETWORK_INPUTS_IN_ACTIVATIONS (4)
#define AI_NETWORK_OUTPUTS_IN_ACTIVATIONS (4)
/******************************************************************************/
#define AI_NETWORK_IN_NUM (1)
AI_DEPRECATED
#define AI_NETWORK_IN \
ai_network_inputs_get(AI_HANDLE_NULL, NULL)
#define AI_NETWORK_IN_SIZE { \
AI_NETWORK_IN_1_SIZE, \
}
#define AI_NETWORK_IN_SIZE_BYTES { \
AI_NETWORK_IN_1_SIZE_BYTES, \
}
#define AI_NETWORK_IN_1_FORMAT AI_BUFFER_FORMAT_FLOAT
#define AI_NETWORK_IN_1_CHANNEL (48)
#define AI_NETWORK_IN_1_SIZE (48)
#define AI_NETWORK_IN_1_SIZE_BYTES (192)
/******************************************************************************/
#define AI_NETWORK_OUT_NUM (3)
AI_DEPRECATED
#define AI_NETWORK_OUT \
ai_network_outputs_get(AI_HANDLE_NULL, NULL)
#define AI_NETWORK_OUT_SIZE { \
AI_NETWORK_OUT_1_SIZE, \
AI_NETWORK_OUT_2_SIZE, \
AI_NETWORK_OUT_3_SIZE, \
}
#define AI_NETWORK_OUT_SIZE_BYTES { \
AI_NETWORK_OUT_1_SIZE_BYTES, \
AI_NETWORK_OUT_2_SIZE_BYTES, \
AI_NETWORK_OUT_3_SIZE_BYTES, \
}
#define AI_NETWORK_OUT_1_FORMAT AI_BUFFER_FORMAT_FLOAT
#define AI_NETWORK_OUT_1_CHANNEL (12)
#define AI_NETWORK_OUT_1_SIZE (12)
#define AI_NETWORK_OUT_1_SIZE_BYTES (48)
#define AI_NETWORK_OUT_2_FORMAT AI_BUFFER_FORMAT_FLOAT
#define AI_NETWORK_OUT_2_CHANNEL (12)
#define AI_NETWORK_OUT_2_SIZE (12)
#define AI_NETWORK_OUT_2_SIZE_BYTES (48)
#define AI_NETWORK_OUT_3_FORMAT AI_BUFFER_FORMAT_FLOAT
#define AI_NETWORK_OUT_3_CHANNEL (1)
#define AI_NETWORK_OUT_3_SIZE (1)
#define AI_NETWORK_OUT_3_SIZE_BYTES (4)
/******************************************************************************/
#define AI_NETWORK_N_NODES (13)
AI_API_DECLARE_BEGIN
/*!
* @defgroup network
* @brief Public neural network APIs
* @details This is the header for the network public APIs declarations
* for interfacing a generated network model.
* @details The public neural network APIs hide the structure of the network
* and offer a set of interfaces to create, initialize, query, configure,
* run and destroy a network instance.
* To handle this, an opaque handler to the network context is provided
* on creation.
* The APIs are meant as stadard interfaces for the calling code; depending on
* the supported platforms and the models, different implementations could be
* available.
*/
/******************************************************************************/
/*! Public API Functions Declarations */
/*!
* @brief Get network library info as a datastruct.
* @ingroup network
* @param[in] network: the handler to the network context
* @param[out] report a pointer to the report struct where to
* store network info. See @ref ai_network_report struct for details
* @return a boolean reporting the exit status of the API
*/
AI_DEPRECATED
AI_API_ENTRY
ai_bool ai_network_get_info(
ai_handle network, ai_network_report* report);
/*!
* @brief Get network library report as a datastruct.
* @ingroup network
* @param[in] network: the handler to the network context
* @param[out] report a pointer to the report struct where to
* store network info. See @ref ai_network_report struct for details
* @return a boolean reporting the exit status of the API
*/
AI_API_ENTRY
ai_bool ai_network_get_report(
ai_handle network, ai_network_report* report);
/*!
* @brief Get first network error code.
* @ingroup network
* @details Get an error code related to the 1st error generated during
* network processing. The error code is structure containing an
* error type indicating the type of error with an associated error code
* Note: after this call the error code is internally reset to AI_ERROR_NONE
* @param network an opaque handle to the network context
* @return an error type/code pair indicating both the error type and code
* see @ref ai_error for struct definition
*/
AI_API_ENTRY
ai_error ai_network_get_error(ai_handle network);
/*!
* @brief Create a neural network.
* @ingroup network
* @details Instantiate a network and returns an object to handle it;
* @param network an opaque handle to the network context
* @param network_config a pointer to the network configuration info coded as a
* buffer
* @return an error code reporting the status of the API on exit
*/
AI_API_ENTRY
ai_error ai_network_create(
ai_handle* network, const ai_buffer* network_config);
/*!
* @brief Destroy a neural network and frees the allocated memory.
* @ingroup network
* @details Destroys the network and frees its memory. The network handle is returned;
* if the handle is not NULL, the unloading has not been successful.
* @param network an opaque handle to the network context
* @return an object handle : AI_HANDLE_NULL if network was destroyed
* correctly. The same input network handle if destroy failed.
*/
AI_API_ENTRY
ai_handle ai_network_destroy(ai_handle network);
/*!
* @brief Initialize the data structures of the network.
* @ingroup network
* @details This API initialized the network after a successfull
* @ref ai_network_create. Both the activations memory buffer
* and params (i.e. weights) need to be provided by caller application
*
* @param network an opaque handle to the network context
* @param params the parameters of the network (required).
* see @ref ai_network_params struct for details
* @return true if the network was correctly initialized, false otherwise
* in case of error the error type could be queried by
* using @ref ai_network_get_error
*/
AI_API_ENTRY
ai_bool ai_network_init(
ai_handle network, const ai_network_params* params);
/*!
* @brief Create and initialize a neural network (helper function)
* @ingroup network
* @details Helper function to instantiate and to initialize a network. It returns an object to handle it;
* @param network an opaque handle to the network context
* @param activations array of addresses of the activations buffers
* @param weights array of addresses of the weights buffers
* @return an error code reporting the status of the API on exit
*/
AI_API_ENTRY
ai_error ai_network_create_and_init(
ai_handle* network, const ai_handle activations[], const ai_handle weights[]);
/*!
* @brief Get network inputs array pointer as a ai_buffer array pointer.
* @ingroup network
* @param network an opaque handle to the network context
* @param n_buffer optional parameter to return the number of outputs
* @return a ai_buffer pointer to the inputs arrays
*/
AI_API_ENTRY
ai_buffer* ai_network_inputs_get(
ai_handle network, ai_u16 *n_buffer);
/*!
* @brief Get network outputs array pointer as a ai_buffer array pointer.
* @ingroup network
* @param network an opaque handle to the network context
* @param n_buffer optional parameter to return the number of outputs
* @return a ai_buffer pointer to the outputs arrays
*/
AI_API_ENTRY
ai_buffer* ai_network_outputs_get(
ai_handle network, ai_u16 *n_buffer);
/*!
* @brief Run the network and return the output
* @ingroup network
*
* @details Runs the network on the inputs and returns the corresponding output.
* The size of the input and output buffers is stored in this
* header generated by the code generation tool. See AI_NETWORK_*
* defines into file @ref network.h for all network sizes defines
*
* @param network an opaque handle to the network context
* @param[in] input buffer with the input data
* @param[out] output buffer with the output data
* @return the number of input batches processed (default 1) or <= 0 if it fails
* in case of error the error type could be queried by
* using @ref ai_network_get_error
*/
AI_API_ENTRY
ai_i32 ai_network_run(
ai_handle network, const ai_buffer* input, ai_buffer* output);
/*!
* @brief Runs the network on the inputs.
* @ingroup network
*
* @details Differently from @ref ai_network_run, no output is returned, e.g. for
* temporal models with a fixed step size.
*
* @param network the network to be run
* @param[in] input buffer with the input data
* @return the number of input batches processed (usually 1) or <= 0 if it fails
* in case of error the error type could be queried by
* using @ref ai_network_get_error
*/
AI_API_ENTRY
ai_i32 ai_network_forward(
ai_handle network, const ai_buffer* input);
AI_API_DECLARE_END
#endif /* AI_NETWORK_H */
| 9,500 | C | 34.85283 | 106 | 0.671895 |
Tbarkin121/GuardDog/stm32/AnymalNet/X-CUBE-AI/App/network_data_params.c | /**
******************************************************************************
* @file network_data_params.c
* @author AST Embedded Analytics Research Platform
* @date Sat Jan 6 20:35:01 2024
* @brief AI Tool Automatic Code Generator for Embedded NN computing
******************************************************************************
* Copyright (c) 2024 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
#include "network_data_params.h"
/** Activations Section ****************************************************/
ai_handle g_network_activations_table[1 + 2] = {
AI_HANDLE_PTR(AI_MAGIC_MARKER),
AI_HANDLE_PTR(NULL),
AI_HANDLE_PTR(AI_MAGIC_MARKER),
};
/** Weights Section ********************************************************/
AI_ALIGNED(32)
const ai_u64 s_network_weights_array_u64[7747] = {
0x400d32ae00000000U, 0x3fc2d3e33f8dd3b5U, 0x3de75e2b3ea6b58eU, 0x3d6c0f3a3e0e3d67U,
0x3c3d36473d6e727eU, 0x3f9051ac4011ef61U, 0x3e55bc613e11d6dfU, 0x3e6c8c063e892695U,
0x3e8473e03e56eb46U, 0x3e5237f13e57a328U, 0x3e689abb3e815d41U, 0x3e9a4ac63e3e3beaU,
0x3df26afe3e71e574U, 0x3e87209c3e45ee69U, 0x3e312a373df7b8a9U, 0x3df20c3d3e8750caU,
0x3e85ad1f3e2fef75U, 0x3e3b2cdd3deba259U, 0x3f09df8c3e89279aU, 0x3f30e1693f1aa0f1U,
0x3f0e93b43f06323cU, 0x3f008fa13f202020U, 0x3f2100413f018674U, 0x3f18ff0e3efb6c14U,
0xbd1771a63f2fec1aU, 0x3e261e543d14179eU, 0x39a79a95bb02081bU, 0x3996888a38ea2927U,
0xbf7f1ed9ba7649f9U, 0xbbe9326f3c90c0aeU, 0xbc44ec103b08bc08U, 0xbebf7ea83e9a8aedU,
0xbec04e2ebd8e44efU, 0x3d9262d03eb67008U, 0xbecacdfc3ea686aaU, 0xbe9a23eb3d279b40U,
0xb9d411de3ea3a7c7U, 0x3c3f22f7bb2e4817U, 0x3a9e4241bb06d475U, 0x3a9f527bb9d96947U,
0x3b734fc0bb0d905aU, 0x3b3051273aafacc9U, 0xbe053045bc203bcfU, 0xbe95705d3edc6117U,
0xbf087060be8b757bU, 0x3e6a06893e987e2dU, 0xbea9de1d3f02a164U, 0xbeda8b173e83026fU,
0xbef306043e1bef47U, 0xbeef5b5fbef130b2U, 0xbeebb0bbbeed860dU, 0xbee80616bee9db69U,
0xbee45b72bee630c4U, 0xbee0b0cdbee2861fU, 0xbedc4541bededb7bU, 0xbed8f711bedb30d6U,
0xbed5b0dfbed78632U, 0xbed2063bbed3db8dU, 0xbece5b96bed0b04fU, 0xbecab0f2becc8644U,
0xbec6ec15bec8dba0U, 0xbec35ba9bec530fbU, 0xbebfb104bec21144U, 0xbebc428ebebddbb2U,
0xbeb8cb00beba310dU, 0xbeb4b116beb66d19U, 0xbeb10672beb2e8ccU, 0xbead46fcbeaf3120U,
0xbea9b129beab3f0eU, 0xbea5cb2ebea79d11U, 0xbea31dffbea3afc5U, 0xbe9e97e8bea0745eU,
0xbe9bb871be9cdbe9U, 0xbe9737b2be99aa08U, 0xbe92e4f0be9542bcU, 0xbe9028a6be914171U,
0xbe8d1fb5be8ee7dcU, 0xbe88ce8ebe8a5560U, 0xbe848f83be86c419U, 0xbe819282be82c62aU,
0xbe7b52edbe7f848bU, 0xbe73266bbe7768a4U, 0xbe6cc16cbe7092a0U, 0xbe653c4bbe6930a9U,
0xbe5e57abbe624836U, 0xbe562aafbe5a5940U, 0xbe4f36c5be51ab88U, 0xbe47d9febe4bcb0dU,
0xbe407eb6be43c8acU, 0xbe396661be3d25d8U, 0xbe32013ebe35df02U, 0xbe2afb38be2ec78eU,
0xbe23852bbe273b80U, 0xbe1c540abe20575aU, 0xbe1498d1be18895cU, 0xbe0d4002be10ac5cU,
0xbe057219be0953daU, 0xbdfb8edebe0180f0U, 0xbdee29d6bdf4ab27U, 0xbddf8575bde6435bU,
0xbdd1c9b6bdd914e8U, 0xbdc43186bdca91e8U, 0xbdb4f172bdbcb6fcU, 0xbda5f843bdadf7f3U,
0xbd96bd27bd9e106bU, 0xbd885844bd8f81baU, 0xbd72f49fbd81229dU, 0xbd55f12ebd641f73U,
0xbd39a745bd47ae4eU, 0xbd1b438dbd2af319U, 0xbcfacd54bd0c9b70U, 0xbcc03443bcdd37a6U,
0xbc8661eabca23392U, 0xbc18d034bc534f89U, 0xbb09ae31bbbfecd4U, 0x3baaec6f3ad971e4U,
0x3c48e0983c0d6403U, 0x3ca0787c3c82139aU, 0x3cdbdb3e3cbeeb09U, 0x3d0aafe73cf71e3eU,
0x3d29a2993d1a700dU, 0x3d4870da3d38ac4dU, 0x3d635c463d54e347U, 0x3d7f7ec63d70d239U,
0x3d8e54843d872a24U, 0x3d9c15d43d94fe31U, 0x3dacb7243da4a8c3U, 0x3dbaafd93db3d4aaU,
0x3dc7c8c33dc0f581U, 0x3dd75fd13dcf90c3U, 0x3de584353dddef2aU, 0x3df4df683dedbeb6U,
0x3e012cab3dfc1d39U, 0x3e08d0613e050afeU, 0x3e103d163e0c9b28U, 0x3e16ec2c3e13642fU,
0x3e1ecdc43e1b3ef7U, 0x3e27055e3e23440eU, 0x3e2e10393e2a9842U, 0x3e3583023e31a88eU,
0x3e3d1aad3e3a42b6U, 0x3e43c5ed3e40bbe4U, 0x3e4b40d43e47441eU, 0x3e520de33e4f4f1cU,
0x3e5955a73e558c5dU, 0x3e617c033e5dbcd9U, 0x3e6a5e4b3e64b0c6U, 0x3e70695b3e6d384dU,
0x3e7657c33e7339daU, 0x3e7e844e3e79a19fU, 0x3e82a5fd3e81014cU, 0x3e8685eb3e84bc9aU,
0x3e8a3ce63e887784U, 0x3e8db7c13e8c3e90U, 0x3e91a2203e8ee7deU, 0x3e954cc43e93b290U,
0x3e998dcf3e976cfdU, 0x3e9c8dc23e9a8a08U, 0x3ea010bc3e9dabe4U, 0x3ea3d3d43ea1b544U,
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0x3db193ff3c21bc70U, 0xbc535158bda88547U, 0x3ce4eeed3da12517U, 0xbc89fa893c5c850fU,
0xbd56be793e1d8d5dU, 0x3d7dd6263d981bfdU, 0xbddd4d793c85e977U, 0xbe079ed0bd9c98a1U,
0x3e447a3dbc864b59U, 0xbc935f2fbdd4bbefU, 0xbcd97119bd227328U, 0x3b3050df3d553100U,
0xbda506153e309309U, 0x3dbbf02fbe0b501dU, 0x3b265f993d82e7aeU, 0x3dd94505bd85cdb2U,
0xbdd7f6c23cedd5a9U, 0x3d4f561d3e423db6U, 0xbdb08243bca451b4U, 0xbc9f263dbe2466e5U,
0x3dd8b1313dafe37dU, 0xbc83d3513e1ef6a1U, 0x3e169c613c0287eaU, 0x3c559d48bd93b96aU,
0xbb48d1dd3d14c045U, 0xbdbf1395bdfee254U, 0xbd93be9cbd91f04dU, 0x3dc7e6b8be5c21dcU,
0xbd32db2f3cf9b083U, 0xba220048bcd30ab0U, 0x3e164977bdb8750fU, 0xbdc1b3bbbdf4d1a6U,
0xbd57eef2bd944f61U, 0x3d1be8f13d8c4ce1U, 0x3d22387bbe3d0f9fU, 0xbd6b178a3cb86e7eU,
0xbbc11555bd4f860cU, 0x3e0dec133d864b1fU, 0xbcb6281bbd5a2463U, 0x3d912d87bcc028f9U,
0x3d74f130bc2b6561U, 0x3c0550583e07ed05U, 0xbe0f04bfbd40788fU, 0x3db086f8bda31e9fU,
0xbb277b2c3da4eb73U, 0x3ca2dcc6bde15b43U, 0xbde8ee38be17b34eU, 0x3de3d0273d72f074U,
0xbe0516c8bdc349bbU, 0x3d24b830bc91c031U, 0x3e1b6ac1be3107dcU, 0x3d3fb6343dad79bbU,
0xbdf92f02be317a04U, 0x3e296028bcef7844U, 0x3e055b323d395df8U, 0x3dd5abaa3dfaec28U,
0xbde171d93a7b1e1eU, 0xbce238aabe5277b4U, 0xbd8424243d76fadcU, 0xbd80ac283ebd0600U,
0xbdab3fd53e1a35baU, 0x3dd3cfc03d6c55bcU, 0xbe0021d03e26cd0bU, 0xbe3084f53e127193U,
0xbc0bdb053e49e952U, 0xbd064e3d3dbfeafdU, 0x3d049966be0fe8a6U, 0x3c291300bd526f1fU,
0xbe481407bc4d97f2U, 0xbd5ffe27bddeab43U, 0xbdbcc2bcbd99acb6U, 0xbd853e9c3a747be1U,
0xbe352d7d3ba027fcU, 0x3d4971903da89ab3U, 0x3dcd0f3d3dce6bc0U, 0x3d7d333abd23adf8U,
0xbcd82705bad2e43fU, 0xbdba3b17bd160332U, 0xbe0bf9e23e0f0dc2U, 0x3dda0af4bd93d925U,
0x3e0d29a4bd5bf7f2U, 0xbd840c03be03af94U, 0xbde3c09b3dd2732fU, 0xbe08be273c9fe457U,
0x3d1a01923e2e9023U, 0xbe12fb863e521705U, 0xbd068af83de407ffU, 0xbe2248f2be22f677U,
0xbcc319aabc8cd285U, 0xbc42f37dbdef7cd5U, 0xbde499743e584cf6U, 0x3d0857163d4a62b4U,
0xbe14b2ae3d042729U, 0xbcf12063bd9609b6U, 0xbd613333bd68265fU, 0x3d27e8393c90c703U,
0xbdc1aa6dbda44ce0U, 0x3dd0b0f2be2ce99eU, 0x3d044d4b3a773f7cU, 0x3dfa0ffbbd585506U,
0x3d9578d5bdd2ca0eU, 0x3dfd2cd7be0662e1U, 0x3d4b048e3dbb827dU, 0x3c41d0713dc08819U,
0xbe255f663c430af5U, 0x3ba9ee403c1644b1U, 0xbdefd260bd85587aU, 0x3da71eb7be0f95a8U,
0x3d72c29abd33a00cU, 0xbd8c9e61bd588572U, 0x3e049c6b3d34dda4U, 0xbd8b9c7f3d5ddbb8U,
0xbb85f1b9bdc6f27dU, 0xbd172b023e09a9e7U, 0xbded3e2fbd59f3dcU, 0xbe1a1f973c76f2baU,
0xbbabcc3bbd99eb86U, 0x3dedf000be02addcU, 0x3e1cd29abe71d6e2U, 0xbc023c1cbe16a064U,
0xbdbd7d1cbd7ca548U, 0x3cd1cfd8be1f755eU, 0xbe36c115bd8b4f6fU, 0x3dbe9b263db29a76U,
0x3d42dada3d0e3f63U, 0xbdb829b8be3b738fU, 0x3cced0a4bb12ca3eU, 0xbc9cd31a3cb228f6U,
0x3c60ac82be0b8d19U, 0xbd7938a83ca2cf64U, 0xbbc5db80399836adU, 0x3c8c023bbde312cdU,
0xba8b6ed33d9c26dfU, 0xbd1fc0863e115d05U, 0xbe164071bdf1f4ebU, 0x3e021d53bdc36d24U,
0xbdfd92c6bcedda4fU, 0xbd6cb2a63e332898U, 0x3e23c6d1bd868944U, 0x3dd6d0223d0d61efU,
0xbd948984ba68aa42U, 0x3d2d39713e40dcb0U, 0xbc6155c2be35585eU, 0xbd06aab13dba41b8U,
0xbe02b57fbdb7ab31U, 0x3da878eebd957e8aU, 0xbe784872bdf58371U, 0x3da43c6b3df13eafU,
0xbdb2ccd7bbc9198eU, 0xbd388f3e3df5a2caU, 0xbcaa3e8abdef33b8U, 0xbdb6f961bdea0fd7U,
0xbe15ea8abe49a047U, 0xbda2a0cebdef959cU, 0xbcd3978cbe3aa658U, 0x3d8a0683bd16771bU,
0x3e150786be19cd87U, 0xbc60fab53e408a01U, 0xbe05a7ca3db796bdU, 0x3df11d05bd4fdfe7U,
0xbd9b32d3be85bc49U, 0x3dc211e93deaf7ebU, 0x3d56b0dbbdfadd72U, 0x3c61d85d3e53540bU,
0x3e63ddd93e5c0b12U, 0x3cef46dbbcfff9f2U, 0x3d8f2d2f3dbd4e7fU, 0x3d76bdd93d6071ceU,
0xbe02793fbe03ded5U, 0xbde25897bdc877a9U, 0xbd0e738d3c8c9815U, 0x3d8ac2bbbe3adff4U,
0x3d7829403e22dc77U, 0x3dfdcac1bd8ac750U, 0xbd3a9f343dcb7b6dU, 0x3cf07c8fbddb8a49U,
0x3da813debd9c4416U, 0xbd646ceabd2affbcU, 0x3ba082b73ca5c584U, 0xbca11ac2bdb369ccU,
0xbde6f31bbd96d2b3U, 0xbd6738b9bdbb4397U, 0x3e19866c3d6cc685U, 0xbda70e1a3e5e1f29U,
0x3d8e956b3e1ca6d4U, 0x3d82e2a3bd93ca77U, 0x3ce8804a3d864a4bU, 0xbda0a704bd818b4aU,
0x3c8e70893daa00b7U, 0x3ce3bacdbc8fe4c1U, 0xbd879da83ccdf1dcU, 0x3f8000003f800000U,
0x3f8000003f800000U, 0x3f8000003f800000U, 0x3f8000003f800000U, 0x3f8000003f800000U,
0x3f8000003f800000U, 0xc00064dfc00e7d86U, 0xc00e5050bffdc125U, 0xbfede25fbfed838dU,
0xbffb408bc00e64b1U, 0xc0138a24bff4cfceU, 0xbffd1a44bffe0755U,
};
ai_handle g_network_weights_table[1 + 2] = {
AI_HANDLE_PTR(AI_MAGIC_MARKER),
AI_HANDLE_PTR(s_network_weights_array_u64),
AI_HANDLE_PTR(AI_MAGIC_MARKER),
};
| 167,866 | C | 83.824154 | 85 | 0.880768 |
Tbarkin121/GuardDog/stm32/AnymalNet/X-CUBE-AI/App/network_config.h |
/**
******************************************************************************
* @file network_config.h
* @author AST Embedded Analytics Research Platform
* @date Sat Jan 6 20:35:01 2024
* @brief AI Tool Automatic Code Generator for Custom Layers Implementation
******************************************************************************
* @attention
*
* Copyright (c) 2024 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
#ifndef AI_NETWORK_CONFIG_H
#define AI_NETWORK_CONFIG_H
#pragma once
#undef AI_TOOLS_VERSION_MAJOR
#undef AI_TOOLS_VERSION_MINOR
#undef AI_TOOLS_VERSION_MICRO
#define AI_TOOLS_VERSION_MAJOR 8
#define AI_TOOLS_VERSION_MINOR 1
#define AI_TOOLS_VERSION_MICRO 0
#define AI_TOOLS_VERSION_EXTRA "19520"
#undef AI_PLATFORM_API_MAJOR
#undef AI_PLATFORM_API_MINOR
#undef AI_PLATFORM_API_MICRO
#define AI_PLATFORM_API_MAJOR (1)
#define AI_PLATFORM_API_MINOR (1)
#define AI_PLATFORM_API_MICRO (0)
#undef AI_TOOLS_API_VERSION_MAJOR
#undef AI_TOOLS_API_VERSION_MINOR
#undef AI_TOOLS_API_VERSION_MICRO
#define AI_TOOLS_API_VERSION_MAJOR (1)
#define AI_TOOLS_API_VERSION_MINOR (5)
#define AI_TOOLS_API_VERSION_MICRO (0)
#endif /*AI_NETWORK_CONFIG_H*/
| 1,510 | C | 30.479166 | 80 | 0.611258 |
Tbarkin121/GuardDog/stm32/AnymalNet/X-CUBE-AI/App/network.c | /**
******************************************************************************
* @file network.c
* @author AST Embedded Analytics Research Platform
* @date Sat Jan 6 20:35:01 2024
* @brief AI Tool Automatic Code Generator for Embedded NN computing
******************************************************************************
* @attention
*
* Copyright (c) 2024 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
#include "network.h"
#include "network_data.h"
#include "ai_platform.h"
#include "ai_platform_interface.h"
#include "ai_math_helpers.h"
#include "core_common.h"
#include "core_convert.h"
#include "layers.h"
#undef AI_NET_OBJ_INSTANCE
#define AI_NET_OBJ_INSTANCE g_network
#undef AI_NETWORK_MODEL_SIGNATURE
#define AI_NETWORK_MODEL_SIGNATURE "ea19e02ca028c0f0f356ef6bad3672ec"
#ifndef AI_TOOLS_REVISION_ID
#define AI_TOOLS_REVISION_ID ""
#endif
#undef AI_TOOLS_DATE_TIME
#define AI_TOOLS_DATE_TIME "Sat Jan 6 20:35:01 2024"
#undef AI_TOOLS_COMPILE_TIME
#define AI_TOOLS_COMPILE_TIME __DATE__ " " __TIME__
#undef AI_NETWORK_N_BATCHES
#define AI_NETWORK_N_BATCHES (1)
static ai_ptr g_network_activations_map[1] = AI_C_ARRAY_INIT;
static ai_ptr g_network_weights_map[1] = AI_C_ARRAY_INIT;
/** Array declarations section **********************************************/
/* Array#0 */
AI_ARRAY_OBJ_DECLARE(
obs_output_array, AI_ARRAY_FORMAT_FLOAT|AI_FMT_FLAG_IS_IO,
NULL, NULL, 48, AI_STATIC)
/* Array#1 */
AI_ARRAY_OBJ_DECLARE(
_model_running_mean_std_Sub_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 48, AI_STATIC)
/* Array#2 */
AI_ARRAY_OBJ_DECLARE(
_model_running_mean_std_Div_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 48, AI_STATIC)
/* Array#3 */
AI_ARRAY_OBJ_DECLARE(
_model_running_mean_std_Clip_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 48, AI_STATIC)
/* Array#4 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 256, AI_STATIC)
/* Array#5 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_1_Elu_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 256, AI_STATIC)
/* Array#6 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 128, AI_STATIC)
/* Array#7 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_3_Elu_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 128, AI_STATIC)
/* Array#8 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 64, AI_STATIC)
/* Array#9 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_5_Elu_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 64, AI_STATIC)
/* Array#10 */
AI_ARRAY_OBJ_DECLARE(
value_output_array, AI_ARRAY_FORMAT_FLOAT|AI_FMT_FLAG_IS_IO,
NULL, NULL, 1, AI_STATIC)
/* Array#11 */
AI_ARRAY_OBJ_DECLARE(
mu_output_array, AI_ARRAY_FORMAT_FLOAT|AI_FMT_FLAG_IS_IO,
NULL, NULL, 12, AI_STATIC)
/* Array#12 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_Mul_output_0_output_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 12, AI_STATIC)
/* Array#13 */
AI_ARRAY_OBJ_DECLARE(
log_std_output_array, AI_ARRAY_FORMAT_FLOAT|AI_FMT_FLAG_IS_IO,
NULL, NULL, 12, AI_STATIC)
/* Array#14 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_Constant_output_0_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 1, AI_STATIC)
/* Array#15 */
AI_ARRAY_OBJ_DECLARE(
onnxDiv_41_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 48, AI_STATIC)
/* Array#16 */
AI_ARRAY_OBJ_DECLARE(
onnxSub_38_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 48, AI_STATIC)
/* Array#17 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_weights_array, AI_ARRAY_FORMAT_LUT8_FLOAT,
NULL, NULL, 12288, AI_STATIC)
/* Array#18 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_bias_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 256, AI_STATIC)
/* Array#19 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_weights_array, AI_ARRAY_FORMAT_LUT8_FLOAT,
NULL, NULL, 32768, AI_STATIC)
/* Array#20 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_bias_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 128, AI_STATIC)
/* Array#21 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_weights_array, AI_ARRAY_FORMAT_LUT8_FLOAT,
NULL, NULL, 8192, AI_STATIC)
/* Array#22 */
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_bias_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 64, AI_STATIC)
/* Array#23 */
AI_ARRAY_OBJ_DECLARE(
value_weights_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 64, AI_STATIC)
/* Array#24 */
AI_ARRAY_OBJ_DECLARE(
value_bias_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 1, AI_STATIC)
/* Array#25 */
AI_ARRAY_OBJ_DECLARE(
mu_weights_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 768, AI_STATIC)
/* Array#26 */
AI_ARRAY_OBJ_DECLARE(
mu_bias_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 12, AI_STATIC)
/* Array#27 */
AI_ARRAY_OBJ_DECLARE(
log_std_scale_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 12, AI_STATIC)
/* Array#28 */
AI_ARRAY_OBJ_DECLARE(
log_std_bias_array, AI_ARRAY_FORMAT_FLOAT,
NULL, NULL, 12, AI_STATIC)
/** Tensor declarations section *********************************************/
/* Tensor #0 */
AI_TENSOR_OBJ_DECLARE(
obs_output, AI_STATIC,
0, 0x0,
AI_SHAPE_INIT(4, 1, 48, 1, 1), AI_STRIDE_INIT(4, 4, 4, 192, 192),
1, &obs_output_array, NULL)
/* Tensor #1 */
AI_TENSOR_OBJ_DECLARE(
_model_running_mean_std_Sub_output_0_output, AI_STATIC,
1, 0x0,
AI_SHAPE_INIT(4, 1, 48, 1, 1), AI_STRIDE_INIT(4, 4, 4, 192, 192),
1, &_model_running_mean_std_Sub_output_0_output_array, NULL)
/* Tensor #2 */
AI_TENSOR_OBJ_DECLARE(
_model_running_mean_std_Div_output_0_output, AI_STATIC,
2, 0x0,
AI_SHAPE_INIT(4, 1, 48, 1, 1), AI_STRIDE_INIT(4, 4, 4, 192, 192),
1, &_model_running_mean_std_Div_output_0_output_array, NULL)
/* Tensor #3 */
AI_TENSOR_OBJ_DECLARE(
_model_running_mean_std_Clip_output_0_output, AI_STATIC,
3, 0x0,
AI_SHAPE_INIT(4, 1, 48, 1, 1), AI_STRIDE_INIT(4, 4, 4, 192, 192),
1, &_model_running_mean_std_Clip_output_0_output_array, NULL)
/* Tensor #4 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_output, AI_STATIC,
4, 0x0,
AI_SHAPE_INIT(4, 1, 256, 1, 1), AI_STRIDE_INIT(4, 4, 4, 1024, 1024),
1, &_model_a2c_network_actor_mlp_0_Gemm_output_0_output_array, NULL)
/* Tensor #5 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_1_Elu_output_0_output, AI_STATIC,
5, 0x0,
AI_SHAPE_INIT(4, 1, 256, 1, 1), AI_STRIDE_INIT(4, 4, 4, 1024, 1024),
1, &_model_a2c_network_actor_mlp_1_Elu_output_0_output_array, NULL)
/* Tensor #6 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_output, AI_STATIC,
6, 0x0,
AI_SHAPE_INIT(4, 1, 128, 1, 1), AI_STRIDE_INIT(4, 4, 4, 512, 512),
1, &_model_a2c_network_actor_mlp_2_Gemm_output_0_output_array, NULL)
/* Tensor #7 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_3_Elu_output_0_output, AI_STATIC,
7, 0x0,
AI_SHAPE_INIT(4, 1, 128, 1, 1), AI_STRIDE_INIT(4, 4, 4, 512, 512),
1, &_model_a2c_network_actor_mlp_3_Elu_output_0_output_array, NULL)
/* Tensor #8 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_output, AI_STATIC,
8, 0x0,
AI_SHAPE_INIT(4, 1, 64, 1, 1), AI_STRIDE_INIT(4, 4, 4, 256, 256),
1, &_model_a2c_network_actor_mlp_4_Gemm_output_0_output_array, NULL)
/* Tensor #9 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_5_Elu_output_0_output, AI_STATIC,
9, 0x0,
AI_SHAPE_INIT(4, 1, 64, 1, 1), AI_STRIDE_INIT(4, 4, 4, 256, 256),
1, &_model_a2c_network_actor_mlp_5_Elu_output_0_output_array, NULL)
/* Tensor #10 */
AI_TENSOR_OBJ_DECLARE(
value_output, AI_STATIC,
10, 0x0,
AI_SHAPE_INIT(4, 1, 1, 1, 1), AI_STRIDE_INIT(4, 4, 4, 4, 4),
1, &value_output_array, NULL)
/* Tensor #11 */
AI_TENSOR_OBJ_DECLARE(
mu_output, AI_STATIC,
11, 0x0,
AI_SHAPE_INIT(4, 1, 12, 1, 1), AI_STRIDE_INIT(4, 4, 4, 48, 48),
1, &mu_output_array, NULL)
/* Tensor #12 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_Mul_output_0_output, AI_STATIC,
12, 0x0,
AI_SHAPE_INIT(4, 1, 12, 1, 1), AI_STRIDE_INIT(4, 4, 4, 48, 48),
1, &_model_a2c_network_Mul_output_0_output_array, NULL)
/* Tensor #13 */
AI_TENSOR_OBJ_DECLARE(
log_std_output, AI_STATIC,
13, 0x0,
AI_SHAPE_INIT(4, 1, 12, 1, 1), AI_STRIDE_INIT(4, 4, 4, 48, 48),
1, &log_std_output_array, NULL)
/* Tensor #14 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_Constant_output_0, AI_STATIC,
14, 0x0,
AI_SHAPE_INIT(4, 1, 1, 1, 1), AI_STRIDE_INIT(4, 4, 4, 4, 4),
1, &_model_a2c_network_Constant_output_0_array, NULL)
/* Tensor #15 */
AI_TENSOR_OBJ_DECLARE(
onnxDiv_41, AI_STATIC,
15, 0x0,
AI_SHAPE_INIT(4, 1, 48, 1, 1), AI_STRIDE_INIT(4, 4, 4, 192, 192),
1, &onnxDiv_41_array, NULL)
/* Tensor #16 */
AI_TENSOR_OBJ_DECLARE(
onnxSub_38, AI_STATIC,
16, 0x0,
AI_SHAPE_INIT(4, 1, 48, 1, 1), AI_STRIDE_INIT(4, 4, 4, 192, 192),
1, &onnxSub_38_array, NULL)
/* Tensor #17 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_weights, AI_STATIC,
17, 0x0,
AI_SHAPE_INIT(4, 48, 256, 1, 1), AI_STRIDE_INIT(4, 1, 48, 12288, 12288),
1, &_model_a2c_network_actor_mlp_0_Gemm_output_0_weights_array, NULL)
/* Tensor #18 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_bias, AI_STATIC,
18, 0x0,
AI_SHAPE_INIT(4, 1, 256, 1, 1), AI_STRIDE_INIT(4, 4, 4, 1024, 1024),
1, &_model_a2c_network_actor_mlp_0_Gemm_output_0_bias_array, NULL)
/* Tensor #19 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_weights, AI_STATIC,
19, 0x0,
AI_SHAPE_INIT(4, 256, 128, 1, 1), AI_STRIDE_INIT(4, 1, 256, 32768, 32768),
1, &_model_a2c_network_actor_mlp_2_Gemm_output_0_weights_array, NULL)
/* Tensor #20 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_bias, AI_STATIC,
20, 0x0,
AI_SHAPE_INIT(4, 1, 128, 1, 1), AI_STRIDE_INIT(4, 4, 4, 512, 512),
1, &_model_a2c_network_actor_mlp_2_Gemm_output_0_bias_array, NULL)
/* Tensor #21 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_weights, AI_STATIC,
21, 0x0,
AI_SHAPE_INIT(4, 128, 64, 1, 1), AI_STRIDE_INIT(4, 1, 128, 8192, 8192),
1, &_model_a2c_network_actor_mlp_4_Gemm_output_0_weights_array, NULL)
/* Tensor #22 */
AI_TENSOR_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_bias, AI_STATIC,
22, 0x0,
AI_SHAPE_INIT(4, 1, 64, 1, 1), AI_STRIDE_INIT(4, 4, 4, 256, 256),
1, &_model_a2c_network_actor_mlp_4_Gemm_output_0_bias_array, NULL)
/* Tensor #23 */
AI_TENSOR_OBJ_DECLARE(
value_weights, AI_STATIC,
23, 0x0,
AI_SHAPE_INIT(4, 64, 1, 1, 1), AI_STRIDE_INIT(4, 4, 256, 256, 256),
1, &value_weights_array, NULL)
/* Tensor #24 */
AI_TENSOR_OBJ_DECLARE(
value_bias, AI_STATIC,
24, 0x0,
AI_SHAPE_INIT(4, 1, 1, 1, 1), AI_STRIDE_INIT(4, 4, 4, 4, 4),
1, &value_bias_array, NULL)
/* Tensor #25 */
AI_TENSOR_OBJ_DECLARE(
mu_weights, AI_STATIC,
25, 0x0,
AI_SHAPE_INIT(4, 64, 12, 1, 1), AI_STRIDE_INIT(4, 4, 256, 3072, 3072),
1, &mu_weights_array, NULL)
/* Tensor #26 */
AI_TENSOR_OBJ_DECLARE(
mu_bias, AI_STATIC,
26, 0x0,
AI_SHAPE_INIT(4, 1, 12, 1, 1), AI_STRIDE_INIT(4, 4, 4, 48, 48),
1, &mu_bias_array, NULL)
/* Tensor #27 */
AI_TENSOR_OBJ_DECLARE(
log_std_scale, AI_STATIC,
27, 0x0,
AI_SHAPE_INIT(4, 1, 12, 1, 1), AI_STRIDE_INIT(4, 4, 4, 48, 48),
1, &log_std_scale_array, NULL)
/* Tensor #28 */
AI_TENSOR_OBJ_DECLARE(
log_std_bias, AI_STATIC,
28, 0x0,
AI_SHAPE_INIT(4, 1, 12, 1, 1), AI_STRIDE_INIT(4, 4, 4, 48, 48),
1, &log_std_bias_array, NULL)
/** Layer declarations section **********************************************/
AI_TENSOR_CHAIN_OBJ_DECLARE(
log_std_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_Mul_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &log_std_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &log_std_scale, &log_std_bias),
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
log_std_layer, 17,
BN_TYPE, 0x0, NULL,
bn, forward_bn,
&log_std_chain,
NULL, &log_std_layer, AI_STATIC,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_a2c_network_Mul_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &mu_output, &_model_a2c_network_Constant_output_0),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_Mul_output_0_output),
AI_TENSOR_LIST_OBJ_EMPTY,
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_a2c_network_Mul_output_0_layer, 16,
ELTWISE_TYPE, 0x0, NULL,
eltwise, forward_eltwise,
&_model_a2c_network_Mul_output_0_chain,
NULL, &log_std_layer, AI_STATIC,
.operation = ai_mul_f32,
.buffer_operation = ai_mul_buffer_f32,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
mu_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_5_Elu_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &mu_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &mu_weights, &mu_bias),
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
mu_layer, 14,
DENSE_TYPE, 0x0, NULL,
dense, forward_dense,
&mu_chain,
NULL, &_model_a2c_network_Mul_output_0_layer, AI_STATIC,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
value_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_5_Elu_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &value_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &value_weights, &value_bias),
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
value_layer, 13,
DENSE_TYPE, 0x0, NULL,
dense, forward_dense,
&value_chain,
NULL, &mu_layer, AI_STATIC,
)
AI_STATIC_CONST ai_float _model_a2c_network_actor_mlp_5_Elu_output_0_nl_params_data[] = { 1.0 };
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_5_Elu_output_0_nl_params, AI_ARRAY_FORMAT_FLOAT,
_model_a2c_network_actor_mlp_5_Elu_output_0_nl_params_data, _model_a2c_network_actor_mlp_5_Elu_output_0_nl_params_data, 1, AI_STATIC_CONST)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_a2c_network_actor_mlp_5_Elu_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_4_Gemm_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_5_Elu_output_0_output),
AI_TENSOR_LIST_OBJ_EMPTY,
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_a2c_network_actor_mlp_5_Elu_output_0_layer, 12,
NL_TYPE, 0x0, NULL,
nl, forward_elu,
&_model_a2c_network_actor_mlp_5_Elu_output_0_chain,
NULL, &value_layer, AI_STATIC,
.nl_params = &_model_a2c_network_actor_mlp_5_Elu_output_0_nl_params,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_3_Elu_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_4_Gemm_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &_model_a2c_network_actor_mlp_4_Gemm_output_0_weights, &_model_a2c_network_actor_mlp_4_Gemm_output_0_bias),
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_a2c_network_actor_mlp_4_Gemm_output_0_layer, 11,
DENSE_TYPE, 0x0, NULL,
dense, forward_dense,
&_model_a2c_network_actor_mlp_4_Gemm_output_0_chain,
NULL, &_model_a2c_network_actor_mlp_5_Elu_output_0_layer, AI_STATIC,
)
AI_STATIC_CONST ai_float _model_a2c_network_actor_mlp_3_Elu_output_0_nl_params_data[] = { 1.0 };
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_3_Elu_output_0_nl_params, AI_ARRAY_FORMAT_FLOAT,
_model_a2c_network_actor_mlp_3_Elu_output_0_nl_params_data, _model_a2c_network_actor_mlp_3_Elu_output_0_nl_params_data, 1, AI_STATIC_CONST)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_a2c_network_actor_mlp_3_Elu_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_2_Gemm_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_3_Elu_output_0_output),
AI_TENSOR_LIST_OBJ_EMPTY,
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_a2c_network_actor_mlp_3_Elu_output_0_layer, 10,
NL_TYPE, 0x0, NULL,
nl, forward_elu,
&_model_a2c_network_actor_mlp_3_Elu_output_0_chain,
NULL, &_model_a2c_network_actor_mlp_4_Gemm_output_0_layer, AI_STATIC,
.nl_params = &_model_a2c_network_actor_mlp_3_Elu_output_0_nl_params,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_1_Elu_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_2_Gemm_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &_model_a2c_network_actor_mlp_2_Gemm_output_0_weights, &_model_a2c_network_actor_mlp_2_Gemm_output_0_bias),
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_a2c_network_actor_mlp_2_Gemm_output_0_layer, 9,
DENSE_TYPE, 0x0, NULL,
dense, forward_dense,
&_model_a2c_network_actor_mlp_2_Gemm_output_0_chain,
NULL, &_model_a2c_network_actor_mlp_3_Elu_output_0_layer, AI_STATIC,
)
AI_STATIC_CONST ai_float _model_a2c_network_actor_mlp_1_Elu_output_0_nl_params_data[] = { 1.0 };
AI_ARRAY_OBJ_DECLARE(
_model_a2c_network_actor_mlp_1_Elu_output_0_nl_params, AI_ARRAY_FORMAT_FLOAT,
_model_a2c_network_actor_mlp_1_Elu_output_0_nl_params_data, _model_a2c_network_actor_mlp_1_Elu_output_0_nl_params_data, 1, AI_STATIC_CONST)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_a2c_network_actor_mlp_1_Elu_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_0_Gemm_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_1_Elu_output_0_output),
AI_TENSOR_LIST_OBJ_EMPTY,
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_a2c_network_actor_mlp_1_Elu_output_0_layer, 8,
NL_TYPE, 0x0, NULL,
nl, forward_elu,
&_model_a2c_network_actor_mlp_1_Elu_output_0_chain,
NULL, &_model_a2c_network_actor_mlp_2_Gemm_output_0_layer, AI_STATIC,
.nl_params = &_model_a2c_network_actor_mlp_1_Elu_output_0_nl_params,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_running_mean_std_Clip_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_a2c_network_actor_mlp_0_Gemm_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &_model_a2c_network_actor_mlp_0_Gemm_output_0_weights, &_model_a2c_network_actor_mlp_0_Gemm_output_0_bias),
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_a2c_network_actor_mlp_0_Gemm_output_0_layer, 7,
DENSE_TYPE, 0x0, NULL,
dense, forward_dense,
&_model_a2c_network_actor_mlp_0_Gemm_output_0_chain,
NULL, &_model_a2c_network_actor_mlp_1_Elu_output_0_layer, AI_STATIC,
)
AI_STATIC_CONST ai_float _model_running_mean_std_Clip_output_0_nl_params_data[] = { -5.0, 5.0 };
AI_ARRAY_OBJ_DECLARE(
_model_running_mean_std_Clip_output_0_nl_params, AI_ARRAY_FORMAT_FLOAT,
_model_running_mean_std_Clip_output_0_nl_params_data, _model_running_mean_std_Clip_output_0_nl_params_data, 2, AI_STATIC_CONST)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_running_mean_std_Clip_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_running_mean_std_Div_output_0_output),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_running_mean_std_Clip_output_0_output),
AI_TENSOR_LIST_OBJ_EMPTY,
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_running_mean_std_Clip_output_0_layer, 5,
NL_TYPE, 0x0, NULL,
nl, forward_clip,
&_model_running_mean_std_Clip_output_0_chain,
NULL, &_model_a2c_network_actor_mlp_0_Gemm_output_0_layer, AI_STATIC,
.nl_params = &_model_running_mean_std_Clip_output_0_nl_params,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_running_mean_std_Div_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &_model_running_mean_std_Sub_output_0_output, &onnxDiv_41),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_running_mean_std_Div_output_0_output),
AI_TENSOR_LIST_OBJ_EMPTY,
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_running_mean_std_Div_output_0_layer, 2,
ELTWISE_TYPE, 0x0, NULL,
eltwise, forward_eltwise,
&_model_running_mean_std_Div_output_0_chain,
NULL, &_model_running_mean_std_Clip_output_0_layer, AI_STATIC,
.operation = ai_div_f32,
.buffer_operation = ai_div_buffer_f32,
)
AI_TENSOR_CHAIN_OBJ_DECLARE(
_model_running_mean_std_Sub_output_0_chain, AI_STATIC_CONST, 4,
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 2, &obs_output, &onnxSub_38),
AI_TENSOR_LIST_OBJ_INIT(AI_FLAG_NONE, 1, &_model_running_mean_std_Sub_output_0_output),
AI_TENSOR_LIST_OBJ_EMPTY,
AI_TENSOR_LIST_OBJ_EMPTY
)
AI_LAYER_OBJ_DECLARE(
_model_running_mean_std_Sub_output_0_layer, 1,
ELTWISE_TYPE, 0x0, NULL,
eltwise, forward_eltwise,
&_model_running_mean_std_Sub_output_0_chain,
NULL, &_model_running_mean_std_Div_output_0_layer, AI_STATIC,
.operation = ai_sub_f32,
.buffer_operation = ai_sub_buffer_f32,
)
#if (AI_TOOLS_API_VERSION < AI_TOOLS_API_VERSION_1_5)
AI_NETWORK_OBJ_DECLARE(
AI_NET_OBJ_INSTANCE, AI_STATIC,
AI_BUFFER_INIT(AI_FLAG_NONE, AI_BUFFER_FORMAT_U8,
AI_BUFFER_SHAPE_INIT(AI_SHAPE_BCWH, 4, 1, 61976, 1, 1),
61976, NULL, NULL),
AI_BUFFER_INIT(AI_FLAG_NONE, AI_BUFFER_FORMAT_U8,
AI_BUFFER_SHAPE_INIT(AI_SHAPE_BCWH, 4, 1, 1536, 1, 1),
1536, NULL, NULL),
AI_TENSOR_LIST_IO_OBJ_INIT(AI_FLAG_NONE, AI_NETWORK_IN_NUM, &obs_output),
AI_TENSOR_LIST_IO_OBJ_INIT(AI_FLAG_NONE, AI_NETWORK_OUT_NUM, &mu_output, &log_std_output, &value_output),
&_model_running_mean_std_Sub_output_0_layer, 0, NULL)
#else
AI_NETWORK_OBJ_DECLARE(
AI_NET_OBJ_INSTANCE, AI_STATIC,
AI_BUFFER_ARRAY_OBJ_INIT_STATIC(
AI_FLAG_NONE, 1,
AI_BUFFER_INIT(AI_FLAG_NONE, AI_BUFFER_FORMAT_U8,
AI_BUFFER_SHAPE_INIT(AI_SHAPE_BCWH, 4, 1, 61976, 1, 1),
61976, NULL, NULL)
),
AI_BUFFER_ARRAY_OBJ_INIT_STATIC(
AI_FLAG_NONE, 1,
AI_BUFFER_INIT(AI_FLAG_NONE, AI_BUFFER_FORMAT_U8,
AI_BUFFER_SHAPE_INIT(AI_SHAPE_BCWH, 4, 1, 1536, 1, 1),
1536, NULL, NULL)
),
AI_TENSOR_LIST_IO_OBJ_INIT(AI_FLAG_NONE, AI_NETWORK_IN_NUM, &obs_output),
AI_TENSOR_LIST_IO_OBJ_INIT(AI_FLAG_NONE, AI_NETWORK_OUT_NUM, &mu_output, &log_std_output, &value_output),
&_model_running_mean_std_Sub_output_0_layer, 0, NULL)
#endif /*(AI_TOOLS_API_VERSION < AI_TOOLS_API_VERSION_1_5)*/
/******************************************************************************/
AI_DECLARE_STATIC
ai_bool network_configure_activations(
ai_network* net_ctx, const ai_network_params* params)
{
AI_ASSERT(net_ctx)
if (ai_platform_get_activations_map(g_network_activations_map, 1, params)) {
/* Updating activations (byte) offsets */
obs_output_array.data = AI_PTR(g_network_activations_map[0] + 320);
obs_output_array.data_start = AI_PTR(g_network_activations_map[0] + 320);
_model_running_mean_std_Sub_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 320);
_model_running_mean_std_Sub_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 320);
_model_running_mean_std_Div_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 320);
_model_running_mean_std_Div_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 320);
_model_running_mean_std_Clip_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 320);
_model_running_mean_std_Clip_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 320);
_model_a2c_network_actor_mlp_0_Gemm_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 512);
_model_a2c_network_actor_mlp_0_Gemm_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 512);
_model_a2c_network_actor_mlp_1_Elu_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 512);
_model_a2c_network_actor_mlp_1_Elu_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 512);
_model_a2c_network_actor_mlp_2_Gemm_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 0);
_model_a2c_network_actor_mlp_2_Gemm_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 0);
_model_a2c_network_actor_mlp_3_Elu_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 512);
_model_a2c_network_actor_mlp_3_Elu_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 512);
_model_a2c_network_actor_mlp_4_Gemm_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 0);
_model_a2c_network_actor_mlp_4_Gemm_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 0);
_model_a2c_network_actor_mlp_5_Elu_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 256);
_model_a2c_network_actor_mlp_5_Elu_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 256);
value_output_array.data = AI_PTR(g_network_activations_map[0] + 0);
value_output_array.data_start = AI_PTR(g_network_activations_map[0] + 0);
mu_output_array.data = AI_PTR(g_network_activations_map[0] + 4);
mu_output_array.data_start = AI_PTR(g_network_activations_map[0] + 4);
_model_a2c_network_Mul_output_0_output_array.data = AI_PTR(g_network_activations_map[0] + 52);
_model_a2c_network_Mul_output_0_output_array.data_start = AI_PTR(g_network_activations_map[0] + 52);
log_std_output_array.data = AI_PTR(g_network_activations_map[0] + 100);
log_std_output_array.data_start = AI_PTR(g_network_activations_map[0] + 100);
return true;
}
AI_ERROR_TRAP(net_ctx, INIT_FAILED, NETWORK_ACTIVATIONS);
return false;
}
/******************************************************************************/
AI_DECLARE_STATIC
ai_bool network_configure_weights(
ai_network* net_ctx, const ai_network_params* params)
{
AI_ASSERT(net_ctx)
if (ai_platform_get_weights_map(g_network_weights_map, 1, params)) {
/* Updating weights (byte) offsets */
_model_a2c_network_Constant_output_0_array.format |= AI_FMT_FLAG_CONST;
_model_a2c_network_Constant_output_0_array.data = AI_PTR(g_network_weights_map[0] + 0);
_model_a2c_network_Constant_output_0_array.data_start = AI_PTR(g_network_weights_map[0] + 0);
onnxDiv_41_array.format |= AI_FMT_FLAG_CONST;
onnxDiv_41_array.data = AI_PTR(g_network_weights_map[0] + 4);
onnxDiv_41_array.data_start = AI_PTR(g_network_weights_map[0] + 4);
onnxSub_38_array.format |= AI_FMT_FLAG_CONST;
onnxSub_38_array.data = AI_PTR(g_network_weights_map[0] + 196);
onnxSub_38_array.data_start = AI_PTR(g_network_weights_map[0] + 196);
_model_a2c_network_actor_mlp_0_Gemm_output_0_weights_array.format |= AI_FMT_FLAG_CONST;
_model_a2c_network_actor_mlp_0_Gemm_output_0_weights_array.data = AI_PTR(g_network_weights_map[0] + 1412);
_model_a2c_network_actor_mlp_0_Gemm_output_0_weights_array.data_start = AI_PTR(g_network_weights_map[0] + 388);
_model_a2c_network_actor_mlp_0_Gemm_output_0_bias_array.format |= AI_FMT_FLAG_CONST;
_model_a2c_network_actor_mlp_0_Gemm_output_0_bias_array.data = AI_PTR(g_network_weights_map[0] + 13700);
_model_a2c_network_actor_mlp_0_Gemm_output_0_bias_array.data_start = AI_PTR(g_network_weights_map[0] + 13700);
_model_a2c_network_actor_mlp_2_Gemm_output_0_weights_array.format |= AI_FMT_FLAG_CONST;
_model_a2c_network_actor_mlp_2_Gemm_output_0_weights_array.data = AI_PTR(g_network_weights_map[0] + 15748);
_model_a2c_network_actor_mlp_2_Gemm_output_0_weights_array.data_start = AI_PTR(g_network_weights_map[0] + 14724);
_model_a2c_network_actor_mlp_2_Gemm_output_0_bias_array.format |= AI_FMT_FLAG_CONST;
_model_a2c_network_actor_mlp_2_Gemm_output_0_bias_array.data = AI_PTR(g_network_weights_map[0] + 48516);
_model_a2c_network_actor_mlp_2_Gemm_output_0_bias_array.data_start = AI_PTR(g_network_weights_map[0] + 48516);
_model_a2c_network_actor_mlp_4_Gemm_output_0_weights_array.format |= AI_FMT_FLAG_CONST;
_model_a2c_network_actor_mlp_4_Gemm_output_0_weights_array.data = AI_PTR(g_network_weights_map[0] + 50052);
_model_a2c_network_actor_mlp_4_Gemm_output_0_weights_array.data_start = AI_PTR(g_network_weights_map[0] + 49028);
_model_a2c_network_actor_mlp_4_Gemm_output_0_bias_array.format |= AI_FMT_FLAG_CONST;
_model_a2c_network_actor_mlp_4_Gemm_output_0_bias_array.data = AI_PTR(g_network_weights_map[0] + 58244);
_model_a2c_network_actor_mlp_4_Gemm_output_0_bias_array.data_start = AI_PTR(g_network_weights_map[0] + 58244);
value_weights_array.format |= AI_FMT_FLAG_CONST;
value_weights_array.data = AI_PTR(g_network_weights_map[0] + 58500);
value_weights_array.data_start = AI_PTR(g_network_weights_map[0] + 58500);
value_bias_array.format |= AI_FMT_FLAG_CONST;
value_bias_array.data = AI_PTR(g_network_weights_map[0] + 58756);
value_bias_array.data_start = AI_PTR(g_network_weights_map[0] + 58756);
mu_weights_array.format |= AI_FMT_FLAG_CONST;
mu_weights_array.data = AI_PTR(g_network_weights_map[0] + 58760);
mu_weights_array.data_start = AI_PTR(g_network_weights_map[0] + 58760);
mu_bias_array.format |= AI_FMT_FLAG_CONST;
mu_bias_array.data = AI_PTR(g_network_weights_map[0] + 61832);
mu_bias_array.data_start = AI_PTR(g_network_weights_map[0] + 61832);
log_std_scale_array.format |= AI_FMT_FLAG_CONST;
log_std_scale_array.data = AI_PTR(g_network_weights_map[0] + 61880);
log_std_scale_array.data_start = AI_PTR(g_network_weights_map[0] + 61880);
log_std_bias_array.format |= AI_FMT_FLAG_CONST;
log_std_bias_array.data = AI_PTR(g_network_weights_map[0] + 61928);
log_std_bias_array.data_start = AI_PTR(g_network_weights_map[0] + 61928);
return true;
}
AI_ERROR_TRAP(net_ctx, INIT_FAILED, NETWORK_WEIGHTS);
return false;
}
/** PUBLIC APIs SECTION *****************************************************/
AI_DEPRECATED
AI_API_ENTRY
ai_bool ai_network_get_info(
ai_handle network, ai_network_report* report)
{
ai_network* net_ctx = AI_NETWORK_ACQUIRE_CTX(network);
if (report && net_ctx)
{
ai_network_report r = {
.model_name = AI_NETWORK_MODEL_NAME,
.model_signature = AI_NETWORK_MODEL_SIGNATURE,
.model_datetime = AI_TOOLS_DATE_TIME,
.compile_datetime = AI_TOOLS_COMPILE_TIME,
.runtime_revision = ai_platform_runtime_get_revision(),
.runtime_version = ai_platform_runtime_get_version(),
.tool_revision = AI_TOOLS_REVISION_ID,
.tool_version = {AI_TOOLS_VERSION_MAJOR, AI_TOOLS_VERSION_MINOR,
AI_TOOLS_VERSION_MICRO, 0x0},
.tool_api_version = AI_STRUCT_INIT,
.api_version = ai_platform_api_get_version(),
.interface_api_version = ai_platform_interface_api_get_version(),
.n_macc = 59889,
.n_inputs = 0,
.inputs = NULL,
.n_outputs = 0,
.outputs = NULL,
.params = AI_STRUCT_INIT,
.activations = AI_STRUCT_INIT,
.n_nodes = 0,
.signature = 0x0,
};
if (!ai_platform_api_get_network_report(network, &r)) return false;
*report = r;
return true;
}
return false;
}
AI_API_ENTRY
ai_bool ai_network_get_report(
ai_handle network, ai_network_report* report)
{
ai_network* net_ctx = AI_NETWORK_ACQUIRE_CTX(network);
if (report && net_ctx)
{
ai_network_report r = {
.model_name = AI_NETWORK_MODEL_NAME,
.model_signature = AI_NETWORK_MODEL_SIGNATURE,
.model_datetime = AI_TOOLS_DATE_TIME,
.compile_datetime = AI_TOOLS_COMPILE_TIME,
.runtime_revision = ai_platform_runtime_get_revision(),
.runtime_version = ai_platform_runtime_get_version(),
.tool_revision = AI_TOOLS_REVISION_ID,
.tool_version = {AI_TOOLS_VERSION_MAJOR, AI_TOOLS_VERSION_MINOR,
AI_TOOLS_VERSION_MICRO, 0x0},
.tool_api_version = AI_STRUCT_INIT,
.api_version = ai_platform_api_get_version(),
.interface_api_version = ai_platform_interface_api_get_version(),
.n_macc = 59889,
.n_inputs = 0,
.inputs = NULL,
.n_outputs = 0,
.outputs = NULL,
.map_signature = AI_MAGIC_SIGNATURE,
.map_weights = AI_STRUCT_INIT,
.map_activations = AI_STRUCT_INIT,
.n_nodes = 0,
.signature = 0x0,
};
if (!ai_platform_api_get_network_report(network, &r)) return false;
*report = r;
return true;
}
return false;
}
AI_API_ENTRY
ai_error ai_network_get_error(ai_handle network)
{
return ai_platform_network_get_error(network);
}
AI_API_ENTRY
ai_error ai_network_create(
ai_handle* network, const ai_buffer* network_config)
{
return ai_platform_network_create(
network, network_config,
&AI_NET_OBJ_INSTANCE,
AI_TOOLS_API_VERSION_MAJOR, AI_TOOLS_API_VERSION_MINOR, AI_TOOLS_API_VERSION_MICRO);
}
AI_API_ENTRY
ai_error ai_network_create_and_init(
ai_handle* network, const ai_handle activations[], const ai_handle weights[])
{
ai_error err;
ai_network_params params;
err = ai_network_create(network, AI_NETWORK_DATA_CONFIG);
if (err.type != AI_ERROR_NONE)
return err;
if (ai_network_data_params_get(¶ms) != true) {
err = ai_network_get_error(*network);
return err;
}
#if defined(AI_NETWORK_DATA_ACTIVATIONS_COUNT)
if (activations) {
/* set the addresses of the activations buffers */
for (int idx=0;idx<params.map_activations.size;idx++)
AI_BUFFER_ARRAY_ITEM_SET_ADDRESS(¶ms.map_activations, idx, activations[idx]);
}
#endif
#if defined(AI_NETWORK_DATA_WEIGHTS_COUNT)
if (weights) {
/* set the addresses of the weight buffers */
for (int idx=0;idx<params.map_weights.size;idx++)
AI_BUFFER_ARRAY_ITEM_SET_ADDRESS(¶ms.map_weights, idx, weights[idx]);
}
#endif
if (ai_network_init(*network, ¶ms) != true) {
err = ai_network_get_error(*network);
}
return err;
}
AI_API_ENTRY
ai_buffer* ai_network_inputs_get(ai_handle network, ai_u16 *n_buffer)
{
if (network == AI_HANDLE_NULL) {
network = (ai_handle)&AI_NET_OBJ_INSTANCE;
((ai_network *)network)->magic = AI_MAGIC_CONTEXT_TOKEN;
}
return ai_platform_inputs_get(network, n_buffer);
}
AI_API_ENTRY
ai_buffer* ai_network_outputs_get(ai_handle network, ai_u16 *n_buffer)
{
if (network == AI_HANDLE_NULL) {
network = (ai_handle)&AI_NET_OBJ_INSTANCE;
((ai_network *)network)->magic = AI_MAGIC_CONTEXT_TOKEN;
}
return ai_platform_outputs_get(network, n_buffer);
}
AI_API_ENTRY
ai_handle ai_network_destroy(ai_handle network)
{
return ai_platform_network_destroy(network);
}
AI_API_ENTRY
ai_bool ai_network_init(
ai_handle network, const ai_network_params* params)
{
ai_network* net_ctx = ai_platform_network_init(network, params);
if (!net_ctx) return false;
ai_bool ok = true;
ok &= network_configure_weights(net_ctx, params);
ok &= network_configure_activations(net_ctx, params);
ok &= ai_platform_network_post_init(network);
return ok;
}
AI_API_ENTRY
ai_i32 ai_network_run(
ai_handle network, const ai_buffer* input, ai_buffer* output)
{
return ai_platform_network_process(network, input, output);
}
AI_API_ENTRY
ai_i32 ai_network_forward(ai_handle network, const ai_buffer* input)
{
return ai_platform_network_process(network, input, NULL);
}
#undef AI_NETWORK_MODEL_SIGNATURE
#undef AI_NET_OBJ_INSTANCE
#undef AI_TOOLS_DATE_TIME
#undef AI_TOOLS_COMPILE_TIME
| 36,457 | C | 35.240557 | 150 | 0.663384 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_pwr.c | /**
******************************************************************************
* @file stm32g4xx_hal_pwr.c
* @author MCD Application Team
* @brief PWR HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Power Controller (PWR) peripheral:
* + Initialization/de-initialization functions
* + Peripheral Control functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup PWR PWR
* @brief PWR HAL module driver
* @{
*/
#ifdef HAL_PWR_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup PWR_Private_Defines PWR Private Defines
* @{
*/
/** @defgroup PWR_PVD_Mode_Mask PWR PVD Mode Mask
* @{
*/
#define PVD_MODE_IT ((uint32_t)0x00010000) /*!< Mask for interruption yielded by PVD threshold crossing */
#define PVD_MODE_EVT ((uint32_t)0x00020000) /*!< Mask for event yielded by PVD threshold crossing */
#define PVD_RISING_EDGE ((uint32_t)0x00000001) /*!< Mask for rising edge set as PVD trigger */
#define PVD_FALLING_EDGE ((uint32_t)0x00000002) /*!< Mask for falling edge set as PVD trigger */
/**
* @}
*/
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup PWR_Exported_Functions PWR Exported Functions
* @{
*/
/** @defgroup PWR_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and de-initialization functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..]
@endverbatim
* @{
*/
/**
* @brief Deinitialize the HAL PWR peripheral registers to their default reset values.
* @retval None
*/
void HAL_PWR_DeInit(void)
{
__HAL_RCC_PWR_FORCE_RESET();
__HAL_RCC_PWR_RELEASE_RESET();
}
/**
* @brief Enable access to the backup domain
* (RTC registers, RTC backup data registers).
* @note After reset, the backup domain is protected against
* possible unwanted write accesses.
* @note RTCSEL that sets the RTC clock source selection is in the RTC back-up domain.
* In order to set or modify the RTC clock, the backup domain access must be
* disabled.
* @note LSEON bit that switches on and off the LSE crystal belongs as well to the
* back-up domain.
* @retval None
*/
void HAL_PWR_EnableBkUpAccess(void)
{
SET_BIT(PWR->CR1, PWR_CR1_DBP);
}
/**
* @brief Disable access to the backup domain
* (RTC registers, RTC backup data registers).
* @retval None
*/
void HAL_PWR_DisableBkUpAccess(void)
{
CLEAR_BIT(PWR->CR1, PWR_CR1_DBP);
}
/**
* @}
*/
/** @defgroup PWR_Exported_Functions_Group2 Peripheral Control functions
* @brief Low Power modes configuration functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..]
*** PVD configuration ***
=========================
[..]
(+) The PVD is used to monitor the VDD power supply by comparing it to a
threshold selected by the PVD Level (PLS[2:0] bits in PWR_CR2 register).
(+) PVDO flag is available to indicate if VDD/VDDA is higher or lower
than the PVD threshold. This event is internally connected to the EXTI
line16 and can generate an interrupt if enabled. This is done through
__HAL_PVD_EXTI_ENABLE_IT() macro.
(+) The PVD is stopped in Standby mode.
*** WakeUp pin configuration ***
================================
[..]
(+) WakeUp pins are used to wakeup the system from Standby mode or Shutdown mode.
The polarity of these pins can be set to configure event detection on high
level (rising edge) or low level (falling edge).
*** Low Power modes configuration ***
=====================================
[..]
The devices feature 8 low-power modes:
(+) Low-power Run mode: core and peripherals are running, main regulator off, low power regulator on.
(+) Sleep mode: Cortex-M4 core stopped, peripherals kept running, main and low power regulators on.
(+) Low-power Sleep mode: Cortex-M4 core stopped, peripherals kept running, main regulator off, low power regulator on.
(+) Stop 0 mode: all clocks are stopped except LSI and LSE, main and low power regulators on.
(+) Stop 1 mode: all clocks are stopped except LSI and LSE, main regulator off, low power regulator on.
(+) Standby mode with SRAM2: all clocks are stopped except LSI and LSE, SRAM2 content preserved, main regulator off, low power regulator on.
(+) Standby mode without SRAM2: all clocks are stopped except LSI and LSE, main and low power regulators off.
(+) Shutdown mode: all clocks are stopped except LSE, main and low power regulators off.
*** Low-power run mode ***
==========================
[..]
(+) Entry: (from main run mode)
(++) set LPR bit with HAL_PWREx_EnableLowPowerRunMode() API after having decreased the system clock below 2 MHz.
(+) Exit:
(++) clear LPR bit then wait for REGLP bit to be reset with HAL_PWREx_DisableLowPowerRunMode() API. Only
then can the system clock frequency be increased above 2 MHz.
*** Sleep mode / Low-power sleep mode ***
=========================================
[..]
(+) Entry:
The Sleep mode / Low-power Sleep mode is entered through HAL_PWR_EnterSLEEPMode() API
in specifying whether or not the regulator is forced to low-power mode and if exit is interrupt or event-triggered.
(++) PWR_MAINREGULATOR_ON: Sleep mode (regulator in main mode).
(++) PWR_LOWPOWERREGULATOR_ON: Low-power sleep (regulator in low power mode).
In the latter case, the system clock frequency must have been decreased below 2 MHz beforehand.
(++) PWR_SLEEPENTRY_WFI: enter SLEEP mode with WFI instruction
(++) PWR_SLEEPENTRY_WFE: enter SLEEP mode with WFE instruction
(+) WFI Exit:
(++) Any peripheral interrupt acknowledged by the nested vectored interrupt
controller (NVIC) or any wake-up event.
(+) WFE Exit:
(++) Any wake-up event such as an EXTI line configured in event mode.
[..] When exiting the Low-power sleep mode by issuing an interrupt or a wakeup event,
the MCU is in Low-power Run mode.
*** Stop 0, Stop 1 modes ***
===============================
[..]
(+) Entry:
The Stop 0, Stop 1 modes are entered through the following API's:
(++) HAL_PWREx_EnterSTOP0Mode() for mode 0 or HAL_PWREx_EnterSTOP1Mode() for mode 1 or for porting reasons HAL_PWR_EnterSTOPMode().
(+) Regulator setting (applicable to HAL_PWR_EnterSTOPMode() only):
(++) PWR_MAINREGULATOR_ON
(++) PWR_LOWPOWERREGULATOR_ON
(+) Exit (interrupt or event-triggered, specified when entering STOP mode):
(++) PWR_STOPENTRY_WFI: enter Stop mode with WFI instruction
(++) PWR_STOPENTRY_WFE: enter Stop mode with WFE instruction
(+) WFI Exit:
(++) Any EXTI Line (Internal or External) configured in Interrupt mode.
(++) Some specific communication peripherals (USART, LPUART, I2C) interrupts
when programmed in wakeup mode.
(+) WFE Exit:
(++) Any EXTI Line (Internal or External) configured in Event mode.
[..]
When exiting Stop 0 and Stop 1 modes, the MCU is either in Run mode or in Low-power Run mode
depending on the LPR bit setting.
*** Standby mode ***
====================
[..]
The Standby mode offers two options:
(+) option a) all clocks off except LSI and LSE, RRS bit set (keeps voltage regulator in low power mode).
SRAM and registers contents are lost except for the SRAM2 content, the RTC registers, RTC backup registers
and Standby circuitry.
(+) option b) all clocks off except LSI and LSE, RRS bit cleared (voltage regulator then disabled).
SRAM and register contents are lost except for the RTC registers, RTC backup registers
and Standby circuitry.
(++) Entry:
(+++) The Standby mode is entered through HAL_PWR_EnterSTANDBYMode() API.
SRAM1 and register contents are lost except for registers in the Backup domain and
Standby circuitry. SRAM2 content can be preserved if the bit RRS is set in PWR_CR3 register.
To enable this feature, the user can resort to HAL_PWREx_EnableSRAM2ContentRetention() API
to set RRS bit.
(++) Exit:
(+++) WKUP pin rising edge, RTC alarm or wakeup, tamper event, time-stamp event,
external reset in NRST pin, IWDG reset.
[..] After waking up from Standby mode, program execution restarts in the same way as after a Reset.
*** Shutdown mode ***
======================
[..]
In Shutdown mode,
voltage regulator is disabled, all clocks are off except LSE, RRS bit is cleared.
SRAM and registers contents are lost except for backup domain registers.
(+) Entry:
The Shutdown mode is entered through HAL_PWREx_EnterSHUTDOWNMode() API.
(+) Exit:
(++) WKUP pin rising edge, RTC alarm or wakeup, tamper event, time-stamp event,
external reset in NRST pin.
[..] After waking up from Shutdown mode, program execution restarts in the same way as after a Reset.
*** Auto-wakeup (AWU) from low-power mode ***
=============================================
[..]
The MCU can be woken up from low-power mode by an RTC Alarm event, an RTC
Wakeup event, a tamper event or a time-stamp event, without depending on
an external interrupt (Auto-wakeup mode).
(+) RTC auto-wakeup (AWU) from the Stop, Standby and Shutdown modes
(++) To wake up from the Stop mode with an RTC alarm event, it is necessary to
configure the RTC to generate the RTC alarm using the HAL_RTC_SetAlarm_IT() function.
(++) To wake up from the Stop mode with an RTC Tamper or time stamp event, it
is necessary to configure the RTC to detect the tamper or time stamp event using the
HAL_RTCEx_SetTimeStamp_IT() or HAL_RTCEx_SetTamper_IT() functions.
(++) To wake up from the Stop mode with an RTC WakeUp event, it is necessary to
configure the RTC to generate the RTC WakeUp event using the HAL_RTCEx_SetWakeUpTimer_IT() function.
@endverbatim
* @{
*/
/**
* @brief Configure the voltage threshold detected by the Power Voltage Detector (PVD).
* @param sConfigPVD: pointer to a PWR_PVDTypeDef structure that contains the PVD
* configuration information.
* @note Refer to the electrical characteristics of your device datasheet for
* more details about the voltage thresholds corresponding to each
* detection level.
* @retval None
*/
HAL_StatusTypeDef HAL_PWR_ConfigPVD(PWR_PVDTypeDef *sConfigPVD)
{
/* Check the parameters */
assert_param(IS_PWR_PVD_LEVEL(sConfigPVD->PVDLevel));
assert_param(IS_PWR_PVD_MODE(sConfigPVD->Mode));
/* Set PLS bits according to PVDLevel value */
MODIFY_REG(PWR->CR2, PWR_CR2_PLS, sConfigPVD->PVDLevel);
/* Clear any previous config. Keep it clear if no event or IT mode is selected */
__HAL_PWR_PVD_EXTI_DISABLE_EVENT();
__HAL_PWR_PVD_EXTI_DISABLE_IT();
__HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE();
__HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE();
/* Configure interrupt mode */
if((sConfigPVD->Mode & PVD_MODE_IT) == PVD_MODE_IT)
{
__HAL_PWR_PVD_EXTI_ENABLE_IT();
}
/* Configure event mode */
if((sConfigPVD->Mode & PVD_MODE_EVT) == PVD_MODE_EVT)
{
__HAL_PWR_PVD_EXTI_ENABLE_EVENT();
}
/* Configure the edge */
if((sConfigPVD->Mode & PVD_RISING_EDGE) == PVD_RISING_EDGE)
{
__HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE();
}
if((sConfigPVD->Mode & PVD_FALLING_EDGE) == PVD_FALLING_EDGE)
{
__HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE();
}
return HAL_OK;
}
/**
* @brief Enable the Power Voltage Detector (PVD).
* @retval None
*/
void HAL_PWR_EnablePVD(void)
{
SET_BIT(PWR->CR2, PWR_CR2_PVDE);
}
/**
* @brief Disable the Power Voltage Detector (PVD).
* @retval None
*/
void HAL_PWR_DisablePVD(void)
{
CLEAR_BIT(PWR->CR2, PWR_CR2_PVDE);
}
/**
* @brief Enable the WakeUp PINx functionality.
* @param WakeUpPinPolarity: Specifies which Wake-Up pin to enable.
* This parameter can be one of the following legacy values which set the default polarity
* i.e. detection on high level (rising edge):
* @arg @ref PWR_WAKEUP_PIN1, PWR_WAKEUP_PIN2, PWR_WAKEUP_PIN3, PWR_WAKEUP_PIN4, PWR_WAKEUP_PIN5
*
* or one of the following value where the user can explicitly specify the enabled pin and
* the chosen polarity:
* @arg @ref PWR_WAKEUP_PIN1_HIGH or PWR_WAKEUP_PIN1_LOW
* @arg @ref PWR_WAKEUP_PIN2_HIGH or PWR_WAKEUP_PIN2_LOW
* @arg @ref PWR_WAKEUP_PIN3_HIGH or PWR_WAKEUP_PIN3_LOW
* @arg @ref PWR_WAKEUP_PIN4_HIGH or PWR_WAKEUP_PIN4_LOW
* @arg @ref PWR_WAKEUP_PIN5_HIGH or PWR_WAKEUP_PIN5_LOW
* @note PWR_WAKEUP_PINx and PWR_WAKEUP_PINx_HIGH are equivalent.
* @retval None
*/
void HAL_PWR_EnableWakeUpPin(uint32_t WakeUpPinPolarity)
{
assert_param(IS_PWR_WAKEUP_PIN(WakeUpPinPolarity));
/* Specifies the Wake-Up pin polarity for the event detection
(rising or falling edge) */
MODIFY_REG(PWR->CR4, (PWR_CR3_EWUP & WakeUpPinPolarity), (WakeUpPinPolarity >> PWR_WUP_POLARITY_SHIFT));
/* Enable wake-up pin */
SET_BIT(PWR->CR3, (PWR_CR3_EWUP & WakeUpPinPolarity));
}
/**
* @brief Disable the WakeUp PINx functionality.
* @param WakeUpPinx: Specifies the Power Wake-Up pin to disable.
* This parameter can be one of the following values:
* @arg @ref PWR_WAKEUP_PIN1, PWR_WAKEUP_PIN2, PWR_WAKEUP_PIN3, PWR_WAKEUP_PIN4, PWR_WAKEUP_PIN5
* @retval None
*/
void HAL_PWR_DisableWakeUpPin(uint32_t WakeUpPinx)
{
assert_param(IS_PWR_WAKEUP_PIN(WakeUpPinx));
CLEAR_BIT(PWR->CR3, (PWR_CR3_EWUP & WakeUpPinx));
}
/**
* @brief Enter Sleep or Low-power Sleep mode.
* @note In Sleep/Low-power Sleep mode, all I/O pins keep the same state as in Run mode.
* @param Regulator: Specifies the regulator state in Sleep/Low-power Sleep mode.
* This parameter can be one of the following values:
* @arg @ref PWR_MAINREGULATOR_ON Sleep mode (regulator in main mode)
* @arg @ref PWR_LOWPOWERREGULATOR_ON Low-power Sleep mode (regulator in low-power mode)
* @note Low-power Sleep mode is entered from Low-power Run mode. Therefore, if not yet
* in Low-power Run mode before calling HAL_PWR_EnterSLEEPMode() with Regulator set
* to PWR_LOWPOWERREGULATOR_ON, the user can optionally configure the
* Flash in power-down monde in setting the SLEEP_PD bit in FLASH_ACR register.
* Additionally, the clock frequency must be reduced below 2 MHz.
* Setting SLEEP_PD in FLASH_ACR then appropriately reducing the clock frequency must
* be done before calling HAL_PWR_EnterSLEEPMode() API.
* @note When exiting Low-power Sleep mode, the MCU is in Low-power Run mode. To move in
* Run mode, the user must resort to HAL_PWREx_DisableLowPowerRunMode() API.
* @param SLEEPEntry: Specifies if Sleep mode is entered with WFI or WFE instruction.
* This parameter can be one of the following values:
* @arg @ref PWR_SLEEPENTRY_WFI enter Sleep or Low-power Sleep mode with WFI instruction
* @arg @ref PWR_SLEEPENTRY_WFE enter Sleep or Low-power Sleep mode with WFE instruction
* @note When WFI entry is used, tick interrupt have to be disabled if not desired as
* the interrupt wake up source.
* @retval None
*/
void HAL_PWR_EnterSLEEPMode(uint32_t Regulator, uint8_t SLEEPEntry)
{
/* Check the parameters */
assert_param(IS_PWR_REGULATOR(Regulator));
assert_param(IS_PWR_SLEEP_ENTRY(SLEEPEntry));
/* Set Regulator parameter */
if (Regulator == PWR_MAINREGULATOR_ON)
{
/* If in low-power run mode at this point, exit it */
if (HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_REGLPF))
{
(void)HAL_PWREx_DisableLowPowerRunMode();
}
/* Regulator now in main mode. */
}
else
{
/* If in run mode, first move to low-power run mode.
The system clock frequency must be below 2 MHz at this point. */
if (HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_REGLPF) == 0U)
{
HAL_PWREx_EnableLowPowerRunMode();
}
}
/* Clear SLEEPDEEP bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* Select SLEEP mode entry -------------------------------------------------*/
if(SLEEPEntry == PWR_SLEEPENTRY_WFI)
{
/* Request Wait For Interrupt */
__WFI();
}
else
{
/* Request Wait For Event */
__SEV();
__WFE();
__WFE();
}
}
/**
* @brief Enter Stop mode
* @note This API is named HAL_PWR_EnterSTOPMode to ensure compatibility with legacy code running
* on devices where only "Stop mode" is mentioned with main or low power regulator ON.
* @note In Stop mode, all I/O pins keep the same state as in Run mode.
* @note All clocks in the VCORE domain are stopped; the PLL,
* the HSI and the HSE oscillators are disabled. Some peripherals with the wakeup capability
* (I2Cx, USARTx and LPUART) can switch on the HSI to receive a frame, and switch off the HSI
* after receiving the frame if it is not a wakeup frame. In this case, the HSI clock is propagated
* only to the peripheral requesting it.
* SRAM1, SRAM2 and register contents are preserved.
* The BOR is available.
* The voltage regulator can be configured either in normal (Stop 0) or low-power mode (Stop 1).
* @note When exiting Stop 0 or Stop 1 mode by issuing an interrupt or a wakeup event,
* the HSI RC oscillator is selected as system clock.
* @note When the voltage regulator operates in low power mode (Stop 1), an additional
* startup delay is incurred when waking up.
* By keeping the internal regulator ON during Stop mode (Stop 0), the consumption
* is higher although the startup time is reduced.
* @param Regulator: Specifies the regulator state in Stop mode.
* This parameter can be one of the following values:
* @arg @ref PWR_MAINREGULATOR_ON Stop 0 mode (main regulator ON)
* @arg @ref PWR_LOWPOWERREGULATOR_ON Stop 1 mode (low power regulator ON)
* @param STOPEntry: Specifies Stop 0 or Stop 1 mode is entered with WFI or WFE instruction.
* This parameter can be one of the following values:
* @arg @ref PWR_STOPENTRY_WFI Enter Stop 0 or Stop 1 mode with WFI instruction.
* @arg @ref PWR_STOPENTRY_WFE Enter Stop 0 or Stop 1 mode with WFE instruction.
* @retval None
*/
void HAL_PWR_EnterSTOPMode(uint32_t Regulator, uint8_t STOPEntry)
{
/* Check the parameters */
assert_param(IS_PWR_REGULATOR(Regulator));
if(Regulator == PWR_LOWPOWERREGULATOR_ON)
{
HAL_PWREx_EnterSTOP1Mode(STOPEntry);
}
else
{
HAL_PWREx_EnterSTOP0Mode(STOPEntry);
}
}
/**
* @brief Enter Standby mode.
* @note In Standby mode, the PLL, the HSI and the HSE oscillators are switched
* off. The voltage regulator is disabled, except when SRAM2 content is preserved
* in which case the regulator is in low-power mode.
* SRAM1 and register contents are lost except for registers in the Backup domain and
* Standby circuitry. SRAM2 content can be preserved if the bit RRS is set in PWR_CR3 register.
* To enable this feature, the user can resort to HAL_PWREx_EnableSRAM2ContentRetention() API
* to set RRS bit.
* The BOR is available.
* @note The I/Os can be configured either with a pull-up or pull-down or can be kept in analog state.
* HAL_PWREx_EnableGPIOPullUp() and HAL_PWREx_EnableGPIOPullDown() respectively enable Pull Up and
* Pull Down state, HAL_PWREx_DisableGPIOPullUp() and HAL_PWREx_DisableGPIOPullDown() disable the
* same.
* These states are effective in Standby mode only if APC bit is set through
* HAL_PWREx_EnablePullUpPullDownConfig() API.
* @retval None
*/
void HAL_PWR_EnterSTANDBYMode(void)
{
/* Set Stand-by mode */
MODIFY_REG(PWR->CR1, PWR_CR1_LPMS, PWR_CR1_LPMS_STANDBY);
/* Set SLEEPDEEP bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* This option is used to ensure that store operations are completed */
#if defined ( __CC_ARM)
__force_stores();
#endif
/* Request Wait For Interrupt */
__WFI();
}
/**
* @brief Indicate Sleep-On-Exit when returning from Handler mode to Thread mode.
* @note Set SLEEPONEXIT bit of SCR register. When this bit is set, the processor
* re-enters SLEEP mode when an interruption handling is over.
* Setting this bit is useful when the processor is expected to run only on
* interruptions handling.
* @retval None
*/
void HAL_PWR_EnableSleepOnExit(void)
{
/* Set SLEEPONEXIT bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPONEXIT_Msk));
}
/**
* @brief Disable Sleep-On-Exit feature when returning from Handler mode to Thread mode.
* @note Clear SLEEPONEXIT bit of SCR register. When this bit is set, the processor
* re-enters SLEEP mode when an interruption handling is over.
* @retval None
*/
void HAL_PWR_DisableSleepOnExit(void)
{
/* Clear SLEEPONEXIT bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPONEXIT_Msk));
}
/**
* @brief Enable CORTEX M4 SEVONPEND bit.
* @note Set SEVONPEND bit of SCR register. When this bit is set, this causes
* WFE to wake up when an interrupt moves from inactive to pended.
* @retval None
*/
void HAL_PWR_EnableSEVOnPend(void)
{
/* Set SEVONPEND bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SEVONPEND_Msk));
}
/**
* @brief Disable CORTEX M4 SEVONPEND bit.
* @note Clear SEVONPEND bit of SCR register. When this bit is set, this causes
* WFE to wake up when an interrupt moves from inactive to pended.
* @retval None
*/
void HAL_PWR_DisableSEVOnPend(void)
{
/* Clear SEVONPEND bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SEVONPEND_Msk));
}
/**
* @brief PWR PVD interrupt callback
* @retval None
*/
__weak void HAL_PWR_PVDCallback(void)
{
/* NOTE : This function should not be modified; when the callback is needed,
the HAL_PWR_PVDCallback can be implemented in the user file
*/
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_PWR_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 24,463 | C | 36.464012 | 146 | 0.625107 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_uart_ex.c | /**
******************************************************************************
* @file stm32g4xx_hal_uart_ex.c
* @author MCD Application Team
* @brief Extended UART HAL module driver.
* This file provides firmware functions to manage the following extended
* functionalities of the Universal Asynchronous Receiver Transmitter Peripheral (UART).
* + Initialization and de-initialization functions
* + Peripheral Control functions
*
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### UART peripheral extended features #####
==============================================================================
(#) Declare a UART_HandleTypeDef handle structure.
(#) For the UART RS485 Driver Enable mode, initialize the UART registers
by calling the HAL_RS485Ex_Init() API.
(#) FIFO mode enabling/disabling and RX/TX FIFO threshold programming.
-@- When UART operates in FIFO mode, FIFO mode must be enabled prior
starting RX/TX transfers. Also RX/TX FIFO thresholds must be
configured prior starting RX/TX transfers.
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup UARTEx UARTEx
* @brief UART Extended HAL module driver
* @{
*/
#ifdef HAL_UART_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup UARTEX_Private_Constants UARTEx Private Constants
* @{
*/
/* UART RX FIFO depth */
#define RX_FIFO_DEPTH 8U
/* UART TX FIFO depth */
#define TX_FIFO_DEPTH 8U
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup UARTEx_Private_Functions UARTEx Private Functions
* @{
*/
static void UARTEx_Wakeup_AddressConfig(UART_HandleTypeDef *huart, UART_WakeUpTypeDef WakeUpSelection);
static void UARTEx_SetNbDataToProcess(UART_HandleTypeDef *huart);
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup UARTEx_Exported_Functions UARTEx Exported Functions
* @{
*/
/** @defgroup UARTEx_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Extended Initialization and Configuration Functions
*
@verbatim
===============================================================================
##### Initialization and Configuration functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to initialize the USARTx or the UARTy
in asynchronous mode.
(+) For the asynchronous mode the parameters below can be configured:
(++) Baud Rate
(++) Word Length
(++) Stop Bit
(++) Parity: If the parity is enabled, then the MSB bit of the data written
in the data register is transmitted but is changed by the parity bit.
(++) Hardware flow control
(++) Receiver/transmitter modes
(++) Over Sampling Method
(++) One-Bit Sampling Method
(+) For the asynchronous mode, the following advanced features can be configured as well:
(++) TX and/or RX pin level inversion
(++) data logical level inversion
(++) RX and TX pins swap
(++) RX overrun detection disabling
(++) DMA disabling on RX error
(++) MSB first on communication line
(++) auto Baud rate detection
[..]
The HAL_RS485Ex_Init() API follows the UART RS485 mode configuration
procedures (details for the procedures are available in reference manual).
@endverbatim
Depending on the frame length defined by the M1 and M0 bits (7-bit,
8-bit or 9-bit), the possible UART formats are listed in the
following table.
Table 1. UART frame format.
+-----------------------------------------------------------------------+
| M1 bit | M0 bit | PCE bit | UART frame |
|---------|---------|-----------|---------------------------------------|
| 0 | 0 | 0 | | SB | 8 bit data | STB | |
|---------|---------|-----------|---------------------------------------|
| 0 | 0 | 1 | | SB | 7 bit data | PB | STB | |
|---------|---------|-----------|---------------------------------------|
| 0 | 1 | 0 | | SB | 9 bit data | STB | |
|---------|---------|-----------|---------------------------------------|
| 0 | 1 | 1 | | SB | 8 bit data | PB | STB | |
|---------|---------|-----------|---------------------------------------|
| 1 | 0 | 0 | | SB | 7 bit data | STB | |
|---------|---------|-----------|---------------------------------------|
| 1 | 0 | 1 | | SB | 6 bit data | PB | STB | |
+-----------------------------------------------------------------------+
* @{
*/
/**
* @brief Initialize the RS485 Driver enable feature according to the specified
* parameters in the UART_InitTypeDef and creates the associated handle.
* @param huart UART handle.
* @param Polarity Select the driver enable polarity.
* This parameter can be one of the following values:
* @arg @ref UART_DE_POLARITY_HIGH DE signal is active high
* @arg @ref UART_DE_POLARITY_LOW DE signal is active low
* @param AssertionTime Driver Enable assertion time:
* 5-bit value defining the time between the activation of the DE (Driver Enable)
* signal and the beginning of the start bit. It is expressed in sample time
* units (1/8 or 1/16 bit time, depending on the oversampling rate)
* @param DeassertionTime Driver Enable deassertion time:
* 5-bit value defining the time between the end of the last stop bit, in a
* transmitted message, and the de-activation of the DE (Driver Enable) signal.
* It is expressed in sample time units (1/8 or 1/16 bit time, depending on the
* oversampling rate).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RS485Ex_Init(UART_HandleTypeDef *huart, uint32_t Polarity, uint32_t AssertionTime,
uint32_t DeassertionTime)
{
uint32_t temp;
/* Check the UART handle allocation */
if (huart == NULL)
{
return HAL_ERROR;
}
/* Check the Driver Enable UART instance */
assert_param(IS_UART_DRIVER_ENABLE_INSTANCE(huart->Instance));
/* Check the Driver Enable polarity */
assert_param(IS_UART_DE_POLARITY(Polarity));
/* Check the Driver Enable assertion time */
assert_param(IS_UART_ASSERTIONTIME(AssertionTime));
/* Check the Driver Enable deassertion time */
assert_param(IS_UART_DEASSERTIONTIME(DeassertionTime));
if (huart->gState == HAL_UART_STATE_RESET)
{
/* Allocate lock resource and initialize it */
huart->Lock = HAL_UNLOCKED;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
UART_InitCallbacksToDefault(huart);
if (huart->MspInitCallback == NULL)
{
huart->MspInitCallback = HAL_UART_MspInit;
}
/* Init the low level hardware */
huart->MspInitCallback(huart);
#else
/* Init the low level hardware : GPIO, CLOCK, CORTEX */
HAL_UART_MspInit(huart);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
huart->gState = HAL_UART_STATE_BUSY;
/* Disable the Peripheral */
__HAL_UART_DISABLE(huart);
/* Perform advanced settings configuration */
/* For some items, configuration requires to be done prior TE and RE bits are set */
if (huart->AdvancedInit.AdvFeatureInit != UART_ADVFEATURE_NO_INIT)
{
UART_AdvFeatureConfig(huart);
}
/* Set the UART Communication parameters */
if (UART_SetConfig(huart) == HAL_ERROR)
{
return HAL_ERROR;
}
/* Enable the Driver Enable mode by setting the DEM bit in the CR3 register */
SET_BIT(huart->Instance->CR3, USART_CR3_DEM);
/* Set the Driver Enable polarity */
MODIFY_REG(huart->Instance->CR3, USART_CR3_DEP, Polarity);
/* Set the Driver Enable assertion and deassertion times */
temp = (AssertionTime << UART_CR1_DEAT_ADDRESS_LSB_POS);
temp |= (DeassertionTime << UART_CR1_DEDT_ADDRESS_LSB_POS);
MODIFY_REG(huart->Instance->CR1, (USART_CR1_DEDT | USART_CR1_DEAT), temp);
/* Enable the Peripheral */
__HAL_UART_ENABLE(huart);
/* TEACK and/or REACK to check before moving huart->gState and huart->RxState to Ready */
return (UART_CheckIdleState(huart));
}
/**
* @}
*/
/** @defgroup UARTEx_Exported_Functions_Group2 IO operation functions
* @brief Extended functions
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
This subsection provides a set of Wakeup and FIFO mode related callback functions.
(#) Wakeup from Stop mode Callback:
(+) HAL_UARTEx_WakeupCallback()
(#) TX/RX Fifos Callbacks:
(+) HAL_UARTEx_RxFifoFullCallback()
(+) HAL_UARTEx_TxFifoEmptyCallback()
@endverbatim
* @{
*/
/**
* @brief UART wakeup from Stop mode callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UARTEx_WakeupCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UARTEx_WakeupCallback can be implemented in the user file.
*/
}
/**
* @brief UART RX Fifo full callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UARTEx_RxFifoFullCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UARTEx_RxFifoFullCallback can be implemented in the user file.
*/
}
/**
* @brief UART TX Fifo empty callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UARTEx_TxFifoEmptyCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UARTEx_TxFifoEmptyCallback can be implemented in the user file.
*/
}
/**
* @}
*/
/** @defgroup UARTEx_Exported_Functions_Group3 Peripheral Control functions
* @brief Extended Peripheral Control functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..] This section provides the following functions:
(+) HAL_MultiProcessorEx_AddressLength_Set() API optionally sets the UART node address
detection length to more than 4 bits for multiprocessor address mark wake up.
(+) HAL_UARTEx_StopModeWakeUpSourceConfig() API defines the wake-up from stop mode
trigger: address match, Start Bit detection or RXNE bit status.
(+) HAL_UARTEx_EnableStopMode() API enables the UART to wake up the MCU from stop mode
(+) HAL_UARTEx_DisableStopMode() API disables the above functionality
(+) HAL_UARTEx_EnableFifoMode() API enables the FIFO mode
(+) HAL_UARTEx_DisableFifoMode() API disables the FIFO mode
(+) HAL_UARTEx_SetTxFifoThreshold() API sets the TX FIFO threshold
(+) HAL_UARTEx_SetRxFifoThreshold() API sets the RX FIFO threshold
[..] This subsection also provides a set of additional functions providing enhanced reception
services to user. (For example, these functions allow application to handle use cases
where number of data to be received is unknown).
(#) Compared to standard reception services which only consider number of received
data elements as reception completion criteria, these functions also consider additional events
as triggers for updating reception status to caller :
(+) Detection of inactivity period (RX line has not been active for a given period).
(++) RX inactivity detected by IDLE event, i.e. RX line has been in idle state (normally high state)
for 1 frame time, after last received byte.
(++) RX inactivity detected by RTO, i.e. line has been in idle state
for a programmable time, after last received byte.
(+) Detection that a specific character has been received.
(#) There are two mode of transfer:
(+) Blocking mode: The reception is performed in polling mode, until either expected number of data is received,
or till IDLE event occurs. Reception is handled only during function execution.
When function exits, no data reception could occur. HAL status and number of actually received data elements,
are returned by function after finishing transfer.
(+) Non-Blocking mode: The reception is performed using Interrupts or DMA.
These API's return the HAL status.
The end of the data processing will be indicated through the
dedicated UART IRQ when using Interrupt mode or the DMA IRQ when using DMA mode.
The HAL_UARTEx_RxEventCallback() user callback will be executed during Receive process
The HAL_UART_ErrorCallback()user callback will be executed when a reception error is detected.
(#) Blocking mode API:
(+) HAL_UARTEx_ReceiveToIdle()
(#) Non-Blocking mode API with Interrupt:
(+) HAL_UARTEx_ReceiveToIdle_IT()
(#) Non-Blocking mode API with DMA:
(+) HAL_UARTEx_ReceiveToIdle_DMA()
@endverbatim
* @{
*/
/**
* @brief By default in multiprocessor mode, when the wake up method is set
* to address mark, the UART handles only 4-bit long addresses detection;
* this API allows to enable longer addresses detection (6-, 7- or 8-bit
* long).
* @note Addresses detection lengths are: 6-bit address detection in 7-bit data mode,
* 7-bit address detection in 8-bit data mode, 8-bit address detection in 9-bit data mode.
* @param huart UART handle.
* @param AddressLength This parameter can be one of the following values:
* @arg @ref UART_ADDRESS_DETECT_4B 4-bit long address
* @arg @ref UART_ADDRESS_DETECT_7B 6-, 7- or 8-bit long address
* @retval HAL status
*/
HAL_StatusTypeDef HAL_MultiProcessorEx_AddressLength_Set(UART_HandleTypeDef *huart, uint32_t AddressLength)
{
/* Check the UART handle allocation */
if (huart == NULL)
{
return HAL_ERROR;
}
/* Check the address length parameter */
assert_param(IS_UART_ADDRESSLENGTH_DETECT(AddressLength));
huart->gState = HAL_UART_STATE_BUSY;
/* Disable the Peripheral */
__HAL_UART_DISABLE(huart);
/* Set the address length */
MODIFY_REG(huart->Instance->CR2, USART_CR2_ADDM7, AddressLength);
/* Enable the Peripheral */
__HAL_UART_ENABLE(huart);
/* TEACK and/or REACK to check before moving huart->gState to Ready */
return (UART_CheckIdleState(huart));
}
/**
* @brief Set Wakeup from Stop mode interrupt flag selection.
* @note It is the application responsibility to enable the interrupt used as
* usart_wkup interrupt source before entering low-power mode.
* @param huart UART handle.
* @param WakeUpSelection Address match, Start Bit detection or RXNE/RXFNE bit status.
* This parameter can be one of the following values:
* @arg @ref UART_WAKEUP_ON_ADDRESS
* @arg @ref UART_WAKEUP_ON_STARTBIT
* @arg @ref UART_WAKEUP_ON_READDATA_NONEMPTY
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_StopModeWakeUpSourceConfig(UART_HandleTypeDef *huart, UART_WakeUpTypeDef WakeUpSelection)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tickstart;
/* check the wake-up from stop mode UART instance */
assert_param(IS_UART_WAKEUP_FROMSTOP_INSTANCE(huart->Instance));
/* check the wake-up selection parameter */
assert_param(IS_UART_WAKEUP_SELECTION(WakeUpSelection.WakeUpEvent));
/* Process Locked */
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Disable the Peripheral */
__HAL_UART_DISABLE(huart);
/* Set the wake-up selection scheme */
MODIFY_REG(huart->Instance->CR3, USART_CR3_WUS, WakeUpSelection.WakeUpEvent);
if (WakeUpSelection.WakeUpEvent == UART_WAKEUP_ON_ADDRESS)
{
UARTEx_Wakeup_AddressConfig(huart, WakeUpSelection);
}
/* Enable the Peripheral */
__HAL_UART_ENABLE(huart);
/* Init tickstart for timeout management */
tickstart = HAL_GetTick();
/* Wait until REACK flag is set */
if (UART_WaitOnFlagUntilTimeout(huart, USART_ISR_REACK, RESET, tickstart, HAL_UART_TIMEOUT_VALUE) != HAL_OK)
{
status = HAL_TIMEOUT;
}
else
{
/* Initialize the UART State */
huart->gState = HAL_UART_STATE_READY;
}
/* Process Unlocked */
__HAL_UNLOCK(huart);
return status;
}
/**
* @brief Enable UART Stop Mode.
* @note The UART is able to wake up the MCU from Stop 1 mode as long as UART clock is HSI or LSE.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_EnableStopMode(UART_HandleTypeDef *huart)
{
/* Process Locked */
__HAL_LOCK(huart);
/* Set UESM bit */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_UESM);
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Disable UART Stop Mode.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_DisableStopMode(UART_HandleTypeDef *huart)
{
/* Process Locked */
__HAL_LOCK(huart);
/* Clear UESM bit */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_UESM);
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Enable the FIFO mode.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_EnableFifoMode(UART_HandleTypeDef *huart)
{
uint32_t tmpcr1;
/* Check parameters */
assert_param(IS_UART_FIFO_INSTANCE(huart->Instance));
/* Process Locked */
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Save actual UART configuration */
tmpcr1 = READ_REG(huart->Instance->CR1);
/* Disable UART */
__HAL_UART_DISABLE(huart);
/* Enable FIFO mode */
SET_BIT(tmpcr1, USART_CR1_FIFOEN);
huart->FifoMode = UART_FIFOMODE_ENABLE;
/* Restore UART configuration */
WRITE_REG(huart->Instance->CR1, tmpcr1);
/* Determine the number of data to process during RX/TX ISR execution */
UARTEx_SetNbDataToProcess(huart);
huart->gState = HAL_UART_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Disable the FIFO mode.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_DisableFifoMode(UART_HandleTypeDef *huart)
{
uint32_t tmpcr1;
/* Check parameters */
assert_param(IS_UART_FIFO_INSTANCE(huart->Instance));
/* Process Locked */
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Save actual UART configuration */
tmpcr1 = READ_REG(huart->Instance->CR1);
/* Disable UART */
__HAL_UART_DISABLE(huart);
/* Enable FIFO mode */
CLEAR_BIT(tmpcr1, USART_CR1_FIFOEN);
huart->FifoMode = UART_FIFOMODE_DISABLE;
/* Restore UART configuration */
WRITE_REG(huart->Instance->CR1, tmpcr1);
huart->gState = HAL_UART_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Set the TXFIFO threshold.
* @param huart UART handle.
* @param Threshold TX FIFO threshold value
* This parameter can be one of the following values:
* @arg @ref UART_TXFIFO_THRESHOLD_1_8
* @arg @ref UART_TXFIFO_THRESHOLD_1_4
* @arg @ref UART_TXFIFO_THRESHOLD_1_2
* @arg @ref UART_TXFIFO_THRESHOLD_3_4
* @arg @ref UART_TXFIFO_THRESHOLD_7_8
* @arg @ref UART_TXFIFO_THRESHOLD_8_8
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_SetTxFifoThreshold(UART_HandleTypeDef *huart, uint32_t Threshold)
{
uint32_t tmpcr1;
/* Check parameters */
assert_param(IS_UART_FIFO_INSTANCE(huart->Instance));
assert_param(IS_UART_TXFIFO_THRESHOLD(Threshold));
/* Process Locked */
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Save actual UART configuration */
tmpcr1 = READ_REG(huart->Instance->CR1);
/* Disable UART */
__HAL_UART_DISABLE(huart);
/* Update TX threshold configuration */
MODIFY_REG(huart->Instance->CR3, USART_CR3_TXFTCFG, Threshold);
/* Determine the number of data to process during RX/TX ISR execution */
UARTEx_SetNbDataToProcess(huart);
/* Restore UART configuration */
WRITE_REG(huart->Instance->CR1, tmpcr1);
huart->gState = HAL_UART_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Set the RXFIFO threshold.
* @param huart UART handle.
* @param Threshold RX FIFO threshold value
* This parameter can be one of the following values:
* @arg @ref UART_RXFIFO_THRESHOLD_1_8
* @arg @ref UART_RXFIFO_THRESHOLD_1_4
* @arg @ref UART_RXFIFO_THRESHOLD_1_2
* @arg @ref UART_RXFIFO_THRESHOLD_3_4
* @arg @ref UART_RXFIFO_THRESHOLD_7_8
* @arg @ref UART_RXFIFO_THRESHOLD_8_8
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_SetRxFifoThreshold(UART_HandleTypeDef *huart, uint32_t Threshold)
{
uint32_t tmpcr1;
/* Check the parameters */
assert_param(IS_UART_FIFO_INSTANCE(huart->Instance));
assert_param(IS_UART_RXFIFO_THRESHOLD(Threshold));
/* Process Locked */
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Save actual UART configuration */
tmpcr1 = READ_REG(huart->Instance->CR1);
/* Disable UART */
__HAL_UART_DISABLE(huart);
/* Update RX threshold configuration */
MODIFY_REG(huart->Instance->CR3, USART_CR3_RXFTCFG, Threshold);
/* Determine the number of data to process during RX/TX ISR execution */
UARTEx_SetNbDataToProcess(huart);
/* Restore UART configuration */
WRITE_REG(huart->Instance->CR1, tmpcr1);
huart->gState = HAL_UART_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Receive an amount of data in blocking mode till either the expected number of data
* is received or an IDLE event occurs.
* @note HAL_OK is returned if reception is completed (expected number of data has been received)
* or if reception is stopped after IDLE event (less than the expected number of data has been received)
* In this case, RxLen output parameter indicates number of data available in reception buffer.
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the received data is handled as a set of uint16_t. In this case, Size must indicate the number
* of uint16_t available through pData.
* @note When FIFO mode is enabled, the RXFNE flag is set as long as the RXFIFO
* is not empty. Read operations from the RDR register are performed when
* RXFNE flag is set. From hardware perspective, RXFNE flag and
* RXNE are mapped on the same bit-field.
* @param huart UART handle.
* @param pData Pointer to data buffer (uint8_t or uint16_t data elements).
* @param Size Amount of data elements (uint8_t or uint16_t) to be received.
* @param RxLen Number of data elements finally received
* (could be lower than Size, in case reception ends on IDLE event)
* @param Timeout Timeout duration expressed in ms (covers the whole reception sequence).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_ReceiveToIdle(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size, uint16_t *RxLen,
uint32_t Timeout)
{
uint8_t *pdata8bits;
uint16_t *pdata16bits;
uint16_t uhMask;
uint32_t tickstart;
/* Check that a Rx process is not already ongoing */
if (huart->RxState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->RxState = HAL_UART_STATE_BUSY_RX;
huart->ReceptionType = HAL_UART_RECEPTION_TOIDLE;
huart->RxEventType = HAL_UART_RXEVENT_TC;
/* Init tickstart for timeout management */
tickstart = HAL_GetTick();
huart->RxXferSize = Size;
huart->RxXferCount = Size;
/* Computation of UART mask to apply to RDR register */
UART_MASK_COMPUTATION(huart);
uhMask = huart->Mask;
/* In case of 9bits/No Parity transfer, pRxData needs to be handled as a uint16_t pointer */
if ((huart->Init.WordLength == UART_WORDLENGTH_9B) && (huart->Init.Parity == UART_PARITY_NONE))
{
pdata8bits = NULL;
pdata16bits = (uint16_t *) pData;
}
else
{
pdata8bits = pData;
pdata16bits = NULL;
}
/* Initialize output number of received elements */
*RxLen = 0U;
/* as long as data have to be received */
while (huart->RxXferCount > 0U)
{
/* Check if IDLE flag is set */
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_IDLE))
{
/* Clear IDLE flag in ISR */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
/* If Set, but no data ever received, clear flag without exiting loop */
/* If Set, and data has already been received, this means Idle Event is valid : End reception */
if (*RxLen > 0U)
{
huart->RxEventType = HAL_UART_RXEVENT_IDLE;
huart->RxState = HAL_UART_STATE_READY;
return HAL_OK;
}
}
/* Check if RXNE flag is set */
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_RXNE))
{
if (pdata8bits == NULL)
{
*pdata16bits = (uint16_t)(huart->Instance->RDR & uhMask);
pdata16bits++;
}
else
{
*pdata8bits = (uint8_t)(huart->Instance->RDR & (uint8_t)uhMask);
pdata8bits++;
}
/* Increment number of received elements */
*RxLen += 1U;
huart->RxXferCount--;
}
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
huart->RxState = HAL_UART_STATE_READY;
return HAL_TIMEOUT;
}
}
}
/* Set number of received elements in output parameter : RxLen */
*RxLen = huart->RxXferSize - huart->RxXferCount;
/* At end of Rx process, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
return HAL_OK;
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Receive an amount of data in interrupt mode till either the expected number of data
* is received or an IDLE event occurs.
* @note Reception is initiated by this function call. Further progress of reception is achieved thanks
* to UART interrupts raised by RXNE and IDLE events. Callback is called at end of reception indicating
* number of received data elements.
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the received data is handled as a set of uint16_t. In this case, Size must indicate the number
* of uint16_t available through pData.
* @param huart UART handle.
* @param pData Pointer to data buffer (uint8_t or uint16_t data elements).
* @param Size Amount of data elements (uint8_t or uint16_t) to be received.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_ReceiveToIdle_IT(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check that a Rx process is not already ongoing */
if (huart->RxState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
/* Set Reception type to reception till IDLE Event*/
huart->ReceptionType = HAL_UART_RECEPTION_TOIDLE;
huart->RxEventType = HAL_UART_RXEVENT_TC;
(void)UART_Start_Receive_IT(huart, pData, Size);
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
}
else
{
/* In case of errors already pending when reception is started,
Interrupts may have already been raised and lead to reception abortion.
(Overrun error for instance).
In such case Reception Type has been reset to HAL_UART_RECEPTION_STANDARD. */
status = HAL_ERROR;
}
return status;
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Receive an amount of data in DMA mode till either the expected number
* of data is received or an IDLE event occurs.
* @note Reception is initiated by this function call. Further progress of reception is achieved thanks
* to DMA services, transferring automatically received data elements in user reception buffer and
* calling registered callbacks at half/end of reception. UART IDLE events are also used to consider
* reception phase as ended. In all cases, callback execution will indicate number of received data elements.
* @note When the UART parity is enabled (PCE = 1), the received data contain
* the parity bit (MSB position).
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the received data is handled as a set of uint16_t. In this case, Size must indicate the number
* of uint16_t available through pData.
* @param huart UART handle.
* @param pData Pointer to data buffer (uint8_t or uint16_t data elements).
* @param Size Amount of data elements (uint8_t or uint16_t) to be received.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UARTEx_ReceiveToIdle_DMA(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size)
{
HAL_StatusTypeDef status;
/* Check that a Rx process is not already ongoing */
if (huart->RxState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
/* Set Reception type to reception till IDLE Event*/
huart->ReceptionType = HAL_UART_RECEPTION_TOIDLE;
huart->RxEventType = HAL_UART_RXEVENT_TC;
status = UART_Start_Receive_DMA(huart, pData, Size);
/* Check Rx process has been successfully started */
if (status == HAL_OK)
{
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
}
else
{
/* In case of errors already pending when reception is started,
Interrupts may have already been raised and lead to reception abortion.
(Overrun error for instance).
In such case Reception Type has been reset to HAL_UART_RECEPTION_STANDARD. */
status = HAL_ERROR;
}
}
return status;
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Provide Rx Event type that has lead to RxEvent callback execution.
* @note When HAL_UARTEx_ReceiveToIdle_IT() or HAL_UARTEx_ReceiveToIdle_DMA() API are called, progress
* of reception process is provided to application through calls of Rx Event callback (either default one
* HAL_UARTEx_RxEventCallback() or user registered one). As several types of events could occur (IDLE event,
* Half Transfer, or Transfer Complete), this function allows to retrieve the Rx Event type that has lead
* to Rx Event callback execution.
* @note This function is expected to be called within the user implementation of Rx Event Callback,
* in order to provide the accurate value :
* In Interrupt Mode :
* - HAL_UART_RXEVENT_TC : when Reception has been completed (expected nb of data has been received)
* - HAL_UART_RXEVENT_IDLE : when Idle event occurred prior reception has been completed (nb of
* received data is lower than expected one)
* In DMA Mode :
* - HAL_UART_RXEVENT_TC : when Reception has been completed (expected nb of data has been received)
* - HAL_UART_RXEVENT_HT : when half of expected nb of data has been received
* - HAL_UART_RXEVENT_IDLE : when Idle event occurred prior reception has been completed (nb of
* received data is lower than expected one).
* In DMA mode, RxEvent callback could be called several times;
* When DMA is configured in Normal Mode, HT event does not stop Reception process;
* When DMA is configured in Circular Mode, HT, TC or IDLE events don't stop Reception process;
* @param huart UART handle.
* @retval Rx Event Type (return vale will be a value of @ref UART_RxEvent_Type_Values)
*/
HAL_UART_RxEventTypeTypeDef HAL_UARTEx_GetRxEventType(const UART_HandleTypeDef *huart)
{
/* Return Rx Event type value, as stored in UART handle */
return (huart->RxEventType);
}
/**
* @}
*/
/**
* @}
*/
/** @addtogroup UARTEx_Private_Functions
* @{
*/
/**
* @brief Initialize the UART wake-up from stop mode parameters when triggered by address detection.
* @param huart UART handle.
* @param WakeUpSelection UART wake up from stop mode parameters.
* @retval None
*/
static void UARTEx_Wakeup_AddressConfig(UART_HandleTypeDef *huart, UART_WakeUpTypeDef WakeUpSelection)
{
assert_param(IS_UART_ADDRESSLENGTH_DETECT(WakeUpSelection.AddressLength));
/* Set the USART address length */
MODIFY_REG(huart->Instance->CR2, USART_CR2_ADDM7, WakeUpSelection.AddressLength);
/* Set the USART address node */
MODIFY_REG(huart->Instance->CR2, USART_CR2_ADD, ((uint32_t)WakeUpSelection.Address << UART_CR2_ADDRESS_LSB_POS));
}
/**
* @brief Calculate the number of data to process in RX/TX ISR.
* @note The RX FIFO depth and the TX FIFO depth is extracted from
* the UART configuration registers.
* @param huart UART handle.
* @retval None
*/
static void UARTEx_SetNbDataToProcess(UART_HandleTypeDef *huart)
{
uint8_t rx_fifo_depth;
uint8_t tx_fifo_depth;
uint8_t rx_fifo_threshold;
uint8_t tx_fifo_threshold;
static const uint8_t numerator[] = {1U, 1U, 1U, 3U, 7U, 1U, 0U, 0U};
static const uint8_t denominator[] = {8U, 4U, 2U, 4U, 8U, 1U, 1U, 1U};
if (huart->FifoMode == UART_FIFOMODE_DISABLE)
{
huart->NbTxDataToProcess = 1U;
huart->NbRxDataToProcess = 1U;
}
else
{
rx_fifo_depth = RX_FIFO_DEPTH;
tx_fifo_depth = TX_FIFO_DEPTH;
rx_fifo_threshold = (uint8_t)(READ_BIT(huart->Instance->CR3, USART_CR3_RXFTCFG) >> USART_CR3_RXFTCFG_Pos);
tx_fifo_threshold = (uint8_t)(READ_BIT(huart->Instance->CR3, USART_CR3_TXFTCFG) >> USART_CR3_TXFTCFG_Pos);
huart->NbTxDataToProcess = ((uint16_t)tx_fifo_depth * numerator[tx_fifo_threshold]) /
(uint16_t)denominator[tx_fifo_threshold];
huart->NbRxDataToProcess = ((uint16_t)rx_fifo_depth * numerator[rx_fifo_threshold]) /
(uint16_t)denominator[rx_fifo_threshold];
}
}
/**
* @}
*/
#endif /* HAL_UART_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 36,532 | C | 34.026846 | 120 | 0.621455 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_flash_ramfunc.c | /**
******************************************************************************
* @file stm32g4xx_hal_flash_ramfunc.c
* @author MCD Application Team
* @brief FLASH RAMFUNC driver.
* This file provides a Flash firmware functions which should be
* executed from internal SRAM
* + FLASH Power Down in Run mode
* + FLASH DBANK User Option Byte
*
*
@verbatim
==============================================================================
##### Flash RAM functions #####
==============================================================================
*** ARM Compiler ***
--------------------
[..] RAM functions are defined using the toolchain options.
Functions that are executed in RAM should reside in a separate
source module. Using the 'Options for File' dialog you can simply change
the 'Code / Const' area of a module to a memory space in physical RAM.
Available memory areas are declared in the 'Target' tab of the
Options for Target' dialog.
*** ICCARM Compiler ***
-----------------------
[..] RAM functions are defined using a specific toolchain keyword "__ramfunc".
*** GNU Compiler ***
--------------------
[..] RAM functions are defined using a specific toolchain attribute
"__attribute__((section(".RamFunc")))".
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup FLASH_RAMFUNC FLASH_RAMFUNC
* @brief FLASH functions executed from RAM
* @{
*/
#ifdef HAL_FLASH_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions -------------------------------------------------------*/
/** @defgroup FLASH_RAMFUNC_Exported_Functions FLASH_RAMFUNC Exported Functions
* @{
*/
/** @defgroup FLASH_RAMFUNC_Exported_Functions_Group1 Peripheral features functions
* @brief Data transfers functions
*
@verbatim
===============================================================================
##### ramfunc functions #####
===============================================================================
[..]
This subsection provides a set of functions that should be executed from RAM.
@endverbatim
* @{
*/
/**
* @brief Enable the Power down in Run Mode
* @note This function should be called and executed from SRAM memory.
* @retval None
*/
__RAM_FUNC HAL_StatusTypeDef HAL_FLASHEx_EnableRunPowerDown(void)
{
/* Enable the Power Down in Run mode*/
__HAL_FLASH_POWER_DOWN_ENABLE();
return HAL_OK;
}
/**
* @brief Disable the Power down in Run Mode
* @note This function should be called and executed from SRAM memory.
* @retval None
*/
__RAM_FUNC HAL_StatusTypeDef HAL_FLASHEx_DisableRunPowerDown(void)
{
/* Disable the Power Down in Run mode*/
__HAL_FLASH_POWER_DOWN_DISABLE();
return HAL_OK;
}
#if defined (FLASH_OPTR_DBANK)
/**
* @brief Program the FLASH DBANK User Option Byte.
*
* @note To configure the user option bytes, the option lock bit OPTLOCK must
* be cleared with the call of the HAL_FLASH_OB_Unlock() function.
* @note To modify the DBANK option byte, no PCROP region should be defined.
* To deactivate PCROP, user should perform RDP changing.
*
* @param DBankConfig The FLASH DBANK User Option Byte value.
* This parameter can be one of the following values:
* @arg OB_DBANK_128_BITS: Single-bank with 128-bits data
* @arg OB_DBANK_64_BITS: Dual-bank with 64-bits data
*
* @retval HAL_Status
*/
__RAM_FUNC HAL_StatusTypeDef HAL_FLASHEx_OB_DBankConfig(uint32_t DBankConfig)
{
uint32_t count, reg;
HAL_StatusTypeDef status = HAL_ERROR;
/* Process Locked */
__HAL_LOCK(&pFlash);
/* Check if the PCROP is disabled */
reg = FLASH->PCROP1SR;
if (reg > FLASH->PCROP1ER)
{
reg = FLASH->PCROP2SR;
if (reg > FLASH->PCROP2ER)
{
/* Disable Flash prefetch */
__HAL_FLASH_PREFETCH_BUFFER_DISABLE();
if (READ_BIT(FLASH->ACR, FLASH_ACR_ICEN) != 0U)
{
/* Disable Flash instruction cache */
__HAL_FLASH_INSTRUCTION_CACHE_DISABLE();
/* Flush Flash instruction cache */
__HAL_FLASH_INSTRUCTION_CACHE_RESET();
}
if (READ_BIT(FLASH->ACR, FLASH_ACR_DCEN) != 0U)
{
/* Disable Flash data cache */
__HAL_FLASH_DATA_CACHE_DISABLE();
/* Flush Flash data cache */
__HAL_FLASH_DATA_CACHE_RESET();
}
/* Disable WRP zone A of 1st bank if needed */
reg = FLASH->WRP1AR;
if (((reg & FLASH_WRP1AR_WRP1A_STRT) >> FLASH_WRP1AR_WRP1A_STRT_Pos) <=
((reg & FLASH_WRP1AR_WRP1A_END) >> FLASH_WRP1AR_WRP1A_END_Pos))
{
MODIFY_REG(FLASH->WRP1AR, (FLASH_WRP1AR_WRP1A_STRT | FLASH_WRP1AR_WRP1A_END), FLASH_WRP1AR_WRP1A_STRT);
}
/* Disable WRP zone B of 1st bank if needed */
reg = FLASH->WRP1BR;
if (((reg & FLASH_WRP1BR_WRP1B_STRT) >> FLASH_WRP1BR_WRP1B_STRT_Pos) <=
((reg & FLASH_WRP1BR_WRP1B_END) >> FLASH_WRP1BR_WRP1B_END_Pos))
{
MODIFY_REG(FLASH->WRP1BR, (FLASH_WRP1BR_WRP1B_STRT | FLASH_WRP1BR_WRP1B_END), FLASH_WRP1BR_WRP1B_STRT);
}
/* Disable WRP zone A of 2nd bank if needed */
reg = FLASH->WRP2AR;
if (((reg & FLASH_WRP2AR_WRP2A_STRT) >> FLASH_WRP2AR_WRP2A_STRT_Pos) <=
((reg & FLASH_WRP2AR_WRP2A_END) >> FLASH_WRP2AR_WRP2A_END_Pos))
{
MODIFY_REG(FLASH->WRP2AR, (FLASH_WRP2AR_WRP2A_STRT | FLASH_WRP2AR_WRP2A_END), FLASH_WRP2AR_WRP2A_STRT);
}
/* Disable WRP zone B of 2nd bank if needed */
reg = FLASH->WRP2BR;
if (((reg & FLASH_WRP2BR_WRP2B_STRT) >> FLASH_WRP2BR_WRP2B_STRT_Pos) <=
((reg & FLASH_WRP2BR_WRP2B_END) >> FLASH_WRP2BR_WRP2B_END_Pos))
{
MODIFY_REG(FLASH->WRP2BR, (FLASH_WRP2BR_WRP2B_STRT | FLASH_WRP2BR_WRP2B_END), FLASH_WRP2BR_WRP2B_STRT);
}
/* Modify the DBANK user option byte */
MODIFY_REG(FLASH->OPTR, FLASH_OPTR_DBANK, DBankConfig);
/* Set OPTSTRT Bit */
SET_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Wait for last operation to be completed */
/* 8 is the number of required instruction cycles for the below loop statement (timeout expressed in ms) */
count = FLASH_TIMEOUT_VALUE * (SystemCoreClock / 8U / 1000U);
do
{
if (count == 0U)
{
break;
}
count--;
}
while (__HAL_FLASH_GET_FLAG(FLASH_FLAG_BSY) != RESET);
/* If the option byte program operation is completed, disable the OPTSTRT Bit */
CLEAR_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Set the bit to force the option byte reloading */
SET_BIT(FLASH->CR, FLASH_CR_OBL_LAUNCH);
}
}
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
return status;
}
#endif
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_FLASH_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 7,937 | C | 30.251968 | 113 | 0.536979 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_gpio.c | /**
******************************************************************************
* @file stm32g4xx_hal_gpio.c
* @author MCD Application Team
* @brief GPIO HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the General Purpose Input/Output (GPIO) peripheral:
* + Initialization and de-initialization functions
* + IO operation functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### GPIO Peripheral features #####
==============================================================================
[..]
(+) Each port bit of the general-purpose I/O (GPIO) ports can be individually
configured by software in several modes:
(++) Input mode
(++) Analog mode
(++) Output mode
(++) Alternate function mode
(++) External interrupt/event lines
(+) During and just after reset, the alternate functions and external interrupt
lines are not active and the I/O ports are configured in input floating mode.
(+) All GPIO pins have weak internal pull-up and pull-down resistors, which can be
activated or not.
(+) In Output or Alternate mode, each IO can be configured on open-drain or push-pull
type and the IO speed can be selected depending on the VDD value.
(+) The microcontroller IO pins are connected to onboard peripherals/modules through a
multiplexer that allows only one peripheral alternate function (AF) connected
to an IO pin at a time. In this way, there can be no conflict between peripherals
sharing the same IO pin.
(+) All ports have external interrupt/event capability. To use external interrupt
lines, the port must be configured in input mode. All available GPIO pins are
connected to the 16 external interrupt/event lines from EXTI0 to EXTI15.
(+) The external interrupt/event controller consists of up to 44 edge detectors
(16 lines are connected to GPIO) for generating event/interrupt requests (each
input line can be independently configured to select the type (interrupt or event)
and the corresponding trigger event (rising or falling or both). Each line can
also be masked independently.
##### How to use this driver #####
==============================================================================
[..]
(#) Enable the GPIO AHB clock using the following function: __HAL_RCC_GPIOx_CLK_ENABLE().
(#) Configure the GPIO pin(s) using HAL_GPIO_Init().
(++) Configure the IO mode using "Mode" member from GPIO_InitTypeDef structure
(++) Activate Pull-up, Pull-down resistor using "Pull" member from GPIO_InitTypeDef
structure.
(++) In case of Output or alternate function mode selection: the speed is
configured through "Speed" member from GPIO_InitTypeDef structure.
(++) In alternate mode is selection, the alternate function connected to the IO
is configured through "Alternate" member from GPIO_InitTypeDef structure.
(++) Analog mode is required when a pin is to be used as ADC channel
or DAC output.
(++) In case of external interrupt/event selection the "Mode" member from
GPIO_InitTypeDef structure select the type (interrupt or event) and
the corresponding trigger event (rising or falling or both).
(#) In case of external interrupt/event mode selection, configure NVIC IRQ priority
mapped to the EXTI line using HAL_NVIC_SetPriority() and enable it using
HAL_NVIC_EnableIRQ().
(#) To get the level of a pin configured in input mode use HAL_GPIO_ReadPin().
(#) To set/reset the level of a pin configured in output mode use
HAL_GPIO_WritePin()/HAL_GPIO_TogglePin().
(#) To lock pin configuration until next reset use HAL_GPIO_LockPin().
(#) During and just after reset, the alternate functions are not
active and the GPIO pins are configured in input floating mode (except JTAG
pins).
(#) The LSE oscillator pins OSC32_IN and OSC32_OUT can be used as general purpose
(PC14 and PC15, respectively) when the LSE oscillator is off. The LSE has
priority over the GPIO function.
(#) The HSE oscillator pins OSC_IN/OSC_OUT can be used as
general purpose PF0 and PF1, respectively, when the HSE oscillator is off.
The HSE has priority over the GPIO function.
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup GPIO
* @{
*/
/** MISRA C:2012 deviation rule has been granted for following rules:
* Rule-12.2 - Medium: RHS argument is in interval [0,INF] which is out of
* range of the shift operator in following API :
* HAL_GPIO_Init
* HAL_GPIO_DeInit
*/
#ifdef HAL_GPIO_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private defines -----------------------------------------------------------*/
/** @addtogroup GPIO_Private_Constants GPIO Private Constants
* @{
*/
#define GPIO_NUMBER (16U)
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup GPIO_Exported_Functions
* @{
*/
/** @defgroup GPIO_Exported_Functions_Group1 Initialization/de-initialization functions
* @brief Initialization and Configuration functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
@endverbatim
* @{
*/
/**
* @brief Initialize the GPIOx peripheral according to the specified parameters in the GPIO_Init.
* @param GPIOx where x can be (A..G) to select the GPIO peripheral for STM32G4xx family
* @param GPIO_Init pointer to a GPIO_InitTypeDef structure that contains
* the configuration information for the specified GPIO peripheral.
* @retval None
*/
void HAL_GPIO_Init(GPIO_TypeDef *GPIOx, GPIO_InitTypeDef *GPIO_Init)
{
uint32_t position = 0x00U;
uint32_t iocurrent;
uint32_t temp;
/* Check the parameters */
assert_param(IS_GPIO_ALL_INSTANCE(GPIOx));
assert_param(IS_GPIO_PIN(GPIO_Init->Pin));
assert_param(IS_GPIO_MODE(GPIO_Init->Mode));
/* Configure the port pins */
while (((GPIO_Init->Pin) >> position) != 0U)
{
/* Get current io position */
iocurrent = (GPIO_Init->Pin) & (1UL << position);
if (iocurrent != 0x00u)
{
/*--------------------- GPIO Mode Configuration ------------------------*/
/* In case of Output or Alternate function mode selection */
if(((GPIO_Init->Mode & GPIO_MODE) == MODE_OUTPUT) ||
((GPIO_Init->Mode & GPIO_MODE) == MODE_AF))
{
/* Check the Speed parameter */
assert_param(IS_GPIO_SPEED(GPIO_Init->Speed));
/* Configure the IO Speed */
temp = GPIOx->OSPEEDR;
temp &= ~(GPIO_OSPEEDR_OSPEED0 << (position * 2U));
temp |= (GPIO_Init->Speed << (position * 2U));
GPIOx->OSPEEDR = temp;
/* Configure the IO Output Type */
temp = GPIOx->OTYPER;
temp &= ~(GPIO_OTYPER_OT0 << position) ;
temp |= (((GPIO_Init->Mode & OUTPUT_TYPE) >> OUTPUT_TYPE_Pos) << position);
GPIOx->OTYPER = temp;
}
if ((GPIO_Init->Mode & GPIO_MODE) != MODE_ANALOG)
{
/* Check the Pull parameter */
assert_param(IS_GPIO_PULL(GPIO_Init->Pull));
/* Activate the Pull-up or Pull down resistor for the current IO */
temp = GPIOx->PUPDR;
temp &= ~(GPIO_PUPDR_PUPD0 << (position * 2U));
temp |= ((GPIO_Init->Pull) << (position * 2U));
GPIOx->PUPDR = temp;
}
/* In case of Alternate function mode selection */
if ((GPIO_Init->Mode & GPIO_MODE) == MODE_AF)
{
/* Check the Alternate function parameters */
assert_param(IS_GPIO_AF_INSTANCE(GPIOx));
assert_param(IS_GPIO_AF(GPIO_Init->Alternate));
/* Configure Alternate function mapped with the current IO */
temp = GPIOx->AFR[position >> 3U];
temp &= ~(0xFU << ((position & 0x07U) * 4U));
temp |= ((GPIO_Init->Alternate) << ((position & 0x07U) * 4U));
GPIOx->AFR[position >> 3U] = temp;
}
/* Configure IO Direction mode (Input, Output, Alternate or Analog) */
temp = GPIOx->MODER;
temp &= ~(GPIO_MODER_MODE0 << (position * 2U));
temp |= ((GPIO_Init->Mode & GPIO_MODE) << (position * 2U));
GPIOx->MODER = temp;
/*--------------------- EXTI Mode Configuration ------------------------*/
/* Configure the External Interrupt or event for the current IO */
if ((GPIO_Init->Mode & EXTI_MODE) != 0x00u)
{
/* Enable SYSCFG Clock */
__HAL_RCC_SYSCFG_CLK_ENABLE();
temp = SYSCFG->EXTICR[position >> 2U];
temp &= ~(0x0FUL << (4U * (position & 0x03U)));
temp |= (GPIO_GET_INDEX(GPIOx) << (4U * (position & 0x03U)));
SYSCFG->EXTICR[position >> 2U] = temp;
/* Clear Rising Falling edge configuration */
temp = EXTI->RTSR1;
temp &= ~(iocurrent);
if ((GPIO_Init->Mode & TRIGGER_RISING) != 0x00U)
{
temp |= iocurrent;
}
EXTI->RTSR1 = temp;
temp = EXTI->FTSR1;
temp &= ~(iocurrent);
if ((GPIO_Init->Mode & TRIGGER_FALLING) != 0x00U)
{
temp |= iocurrent;
}
EXTI->FTSR1 = temp;
temp = EXTI->EMR1;
temp &= ~(iocurrent);
if ((GPIO_Init->Mode & EXTI_EVT) != 0x00U)
{
temp |= iocurrent;
}
EXTI->EMR1 = temp;
/* Clear EXTI line configuration */
temp = EXTI->IMR1;
temp &= ~(iocurrent);
if ((GPIO_Init->Mode & EXTI_IT) != 0x00U)
{
temp |= iocurrent;
}
EXTI->IMR1 = temp;
}
}
position++;
}
}
/**
* @brief De-initialize the GPIOx peripheral registers to their default reset values.
* @param GPIOx where x can be (A..G) to select the GPIO peripheral for STM32G4xx family
* @param GPIO_Pin specifies the port bit to be written.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15).
* @retval None
*/
void HAL_GPIO_DeInit(GPIO_TypeDef *GPIOx, uint32_t GPIO_Pin)
{
uint32_t position = 0x00U;
uint32_t iocurrent;
uint32_t tmp;
/* Check the parameters */
assert_param(IS_GPIO_ALL_INSTANCE(GPIOx));
assert_param(IS_GPIO_PIN(GPIO_Pin));
/* Configure the port pins */
while ((GPIO_Pin >> position) != 0U)
{
/* Get current io position */
iocurrent = (GPIO_Pin) & (1UL << position);
if (iocurrent != 0x00u)
{
/*------------------------- EXTI Mode Configuration --------------------*/
/* Clear the External Interrupt or Event for the current IO */
tmp = SYSCFG->EXTICR[position >> 2U];
tmp &= (0x0FUL << (4U * (position & 0x03U)));
if (tmp == (GPIO_GET_INDEX(GPIOx) << (4U * (position & 0x03U))))
{
/* Clear EXTI line configuration */
EXTI->IMR1 &= ~(iocurrent);
EXTI->EMR1 &= ~(iocurrent);
/* Clear Rising Falling edge configuration */
EXTI->FTSR1 &= ~(iocurrent);
EXTI->RTSR1 &= ~(iocurrent);
tmp = 0x0FUL << (4U * (position & 0x03U));
SYSCFG->EXTICR[position >> 2U] &= ~tmp;
}
/*------------------------- GPIO Mode Configuration --------------------*/
/* Configure IO in Analog Mode */
GPIOx->MODER |= (GPIO_MODER_MODE0 << (position * 2u));
/* Configure the default Alternate Function in current IO */
GPIOx->AFR[position >> 3u] &= ~(0xFu << ((position & 0x07u) * 4u));
/* Deactivate the Pull-up and Pull-down resistor for the current IO */
GPIOx->PUPDR &= ~(GPIO_PUPDR_PUPD0 << (position * 2u));
/* Configure the default value IO Output Type */
GPIOx->OTYPER &= ~(GPIO_OTYPER_OT0 << position);
/* Configure the default value for IO Speed */
GPIOx->OSPEEDR &= ~(GPIO_OSPEEDR_OSPEED0 << (position * 2u));
}
position++;
}
}
/**
* @}
*/
/** @addtogroup GPIO_Exported_Functions_Group2
* @brief GPIO Read, Write, Toggle, Lock and EXTI management functions.
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
@endverbatim
* @{
*/
/**
* @brief Read the specified input port pin.
* @param GPIOx where x can be (A..G) to select the GPIO peripheral for STM32G4xx family
* @param GPIO_Pin specifies the port bit to read.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15).
* @retval The input port pin value.
*/
GPIO_PinState HAL_GPIO_ReadPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin)
{
GPIO_PinState bitstatus;
/* Check the parameters */
assert_param(IS_GPIO_PIN(GPIO_Pin));
if ((GPIOx->IDR & GPIO_Pin) != 0x00U)
{
bitstatus = GPIO_PIN_SET;
}
else
{
bitstatus = GPIO_PIN_RESET;
}
return bitstatus;
}
/**
* @brief Set or clear the selected data port bit.
*
* @note This function uses GPIOx_BSRR and GPIOx_BRR registers to allow atomic read/modify
* accesses. In this way, there is no risk of an IRQ occurring between
* the read and the modify access.
*
* @param GPIOx where x can be (A..G) to select the GPIO peripheral for STM32G4xx family
* @param GPIO_Pin specifies the port bit to be written.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15).
* @param PinState specifies the value to be written to the selected bit.
* This parameter can be one of the GPIO_PinState enum values:
* @arg GPIO_PIN_RESET: to clear the port pin
* @arg GPIO_PIN_SET: to set the port pin
* @retval None
*/
void HAL_GPIO_WritePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin, GPIO_PinState PinState)
{
/* Check the parameters */
assert_param(IS_GPIO_PIN(GPIO_Pin));
assert_param(IS_GPIO_PIN_ACTION(PinState));
if (PinState != GPIO_PIN_RESET)
{
GPIOx->BSRR = (uint32_t)GPIO_Pin;
}
else
{
GPIOx->BRR = (uint32_t)GPIO_Pin;
}
}
/**
* @brief Toggle the specified GPIO pin.
* @param GPIOx where x can be (A..G) to select the GPIO peripheral for STM32G4xx family
* @param GPIO_Pin specifies the pin to be toggled.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15).
* @retval None
*/
void HAL_GPIO_TogglePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin)
{
uint32_t odr;
/* Check the parameters */
assert_param(IS_GPIO_PIN(GPIO_Pin));
/* get current Output Data Register value */
odr = GPIOx->ODR;
/* Set selected pins that were at low level, and reset ones that were high */
GPIOx->BSRR = ((odr & GPIO_Pin) << GPIO_NUMBER) | (~odr & GPIO_Pin);
}
/**
* @brief Lock GPIO Pins configuration registers.
* @note The locked registers are GPIOx_MODER, GPIOx_OTYPER, GPIOx_OSPEEDR,
* GPIOx_PUPDR, GPIOx_AFRL and GPIOx_AFRH.
* @note The configuration of the locked GPIO pins can no longer be modified
* until the next reset.
* @param GPIOx where x can be (A..G) to select the GPIO peripheral for STM32G4xx family
* @param GPIO_Pin specifies the port bits to be locked.
* This parameter can be any combination of GPIO_Pin_x where x can be (0..15).
* @retval None
*/
HAL_StatusTypeDef HAL_GPIO_LockPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin)
{
__IO uint32_t tmp = GPIO_LCKR_LCKK;
/* Check the parameters */
assert_param(IS_GPIO_LOCK_INSTANCE(GPIOx));
assert_param(IS_GPIO_PIN(GPIO_Pin));
/* Apply lock key write sequence */
tmp |= GPIO_Pin;
/* Set LCKx bit(s): LCKK='1' + LCK[15-0] */
GPIOx->LCKR = tmp;
/* Reset LCKx bit(s): LCKK='0' + LCK[15-0] */
GPIOx->LCKR = GPIO_Pin;
/* Set LCKx bit(s): LCKK='1' + LCK[15-0] */
GPIOx->LCKR = tmp;
/* Read LCKK register. This read is mandatory to complete key lock sequence */
tmp = GPIOx->LCKR;
/* read again in order to confirm lock is active */
if ((GPIOx->LCKR & GPIO_LCKR_LCKK) != 0x00u)
{
return HAL_OK;
}
else
{
return HAL_ERROR;
}
}
/**
* @brief Handle EXTI interrupt request.
* @param GPIO_Pin Specifies the port pin connected to corresponding EXTI line.
* @retval None
*/
void HAL_GPIO_EXTI_IRQHandler(uint16_t GPIO_Pin)
{
/* EXTI line interrupt detected */
if (__HAL_GPIO_EXTI_GET_IT(GPIO_Pin) != 0x00u)
{
__HAL_GPIO_EXTI_CLEAR_IT(GPIO_Pin);
HAL_GPIO_EXTI_Callback(GPIO_Pin);
}
}
/**
* @brief EXTI line detection callback.
* @param GPIO_Pin: Specifies the port pin connected to corresponding EXTI line.
* @retval None
*/
__weak void HAL_GPIO_EXTI_Callback(uint16_t GPIO_Pin)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(GPIO_Pin);
/* NOTE: This function should not be modified, when the callback is needed,
the HAL_GPIO_EXTI_Callback could be implemented in the user file
*/
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_GPIO_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 18,379 | C | 33.484052 | 99 | 0.572556 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_crc_ex.c | /**
******************************************************************************
* @file stm32g4xx_hal_crc_ex.c
* @author MCD Application Team
* @brief Extended CRC HAL module driver.
* This file provides firmware functions to manage the extended
* functionalities of the CRC peripheral.
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
================================================================================
##### How to use this driver #####
================================================================================
[..]
(+) Set user-defined generating polynomial through HAL_CRCEx_Polynomial_Set()
(+) Configure Input or Output data inversion
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup CRCEx CRCEx
* @brief CRC Extended HAL module driver
* @{
*/
#ifdef HAL_CRC_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup CRCEx_Exported_Functions CRC Extended Exported Functions
* @{
*/
/** @defgroup CRCEx_Exported_Functions_Group1 Extended Initialization/de-initialization functions
* @brief Extended Initialization and Configuration functions.
*
@verbatim
===============================================================================
##### Extended configuration functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Configure the generating polynomial
(+) Configure the input data inversion
(+) Configure the output data inversion
@endverbatim
* @{
*/
/**
* @brief Initialize the CRC polynomial if different from default one.
* @param hcrc CRC handle
* @param Pol CRC generating polynomial (7, 8, 16 or 32-bit long).
* This parameter is written in normal representation, e.g.
* @arg for a polynomial of degree 7, X^7 + X^6 + X^5 + X^2 + 1 is written 0x65
* @arg for a polynomial of degree 16, X^16 + X^12 + X^5 + 1 is written 0x1021
* @param PolyLength CRC polynomial length.
* This parameter can be one of the following values:
* @arg @ref CRC_POLYLENGTH_7B 7-bit long CRC (generating polynomial of degree 7)
* @arg @ref CRC_POLYLENGTH_8B 8-bit long CRC (generating polynomial of degree 8)
* @arg @ref CRC_POLYLENGTH_16B 16-bit long CRC (generating polynomial of degree 16)
* @arg @ref CRC_POLYLENGTH_32B 32-bit long CRC (generating polynomial of degree 32)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRCEx_Polynomial_Set(CRC_HandleTypeDef *hcrc, uint32_t Pol, uint32_t PolyLength)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t msb = 31U; /* polynomial degree is 32 at most, so msb is initialized to max value */
/* Check the parameters */
assert_param(IS_CRC_POL_LENGTH(PolyLength));
/* Ensure that the generating polynomial is odd */
if ((Pol & (uint32_t)(0x1U)) == 0U)
{
status = HAL_ERROR;
}
else
{
/* check polynomial definition vs polynomial size:
* polynomial length must be aligned with polynomial
* definition. HAL_ERROR is reported if Pol degree is
* larger than that indicated by PolyLength.
* Look for MSB position: msb will contain the degree of
* the second to the largest polynomial member. E.g., for
* X^7 + X^6 + X^5 + X^2 + 1, msb = 6. */
while ((msb-- > 0U) && ((Pol & ((uint32_t)(0x1U) << (msb & 0x1FU))) == 0U))
{
}
switch (PolyLength)
{
case CRC_POLYLENGTH_7B:
if (msb >= HAL_CRC_LENGTH_7B)
{
status = HAL_ERROR;
}
break;
case CRC_POLYLENGTH_8B:
if (msb >= HAL_CRC_LENGTH_8B)
{
status = HAL_ERROR;
}
break;
case CRC_POLYLENGTH_16B:
if (msb >= HAL_CRC_LENGTH_16B)
{
status = HAL_ERROR;
}
break;
case CRC_POLYLENGTH_32B:
/* no polynomial definition vs. polynomial length issue possible */
break;
default:
status = HAL_ERROR;
break;
}
}
if (status == HAL_OK)
{
/* set generating polynomial */
WRITE_REG(hcrc->Instance->POL, Pol);
/* set generating polynomial size */
MODIFY_REG(hcrc->Instance->CR, CRC_CR_POLYSIZE, PolyLength);
}
/* Return function status */
return status;
}
/**
* @brief Set the Reverse Input data mode.
* @param hcrc CRC handle
* @param InputReverseMode Input Data inversion mode.
* This parameter can be one of the following values:
* @arg @ref CRC_INPUTDATA_INVERSION_NONE no change in bit order (default value)
* @arg @ref CRC_INPUTDATA_INVERSION_BYTE Byte-wise bit reversal
* @arg @ref CRC_INPUTDATA_INVERSION_HALFWORD HalfWord-wise bit reversal
* @arg @ref CRC_INPUTDATA_INVERSION_WORD Word-wise bit reversal
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRCEx_Input_Data_Reverse(CRC_HandleTypeDef *hcrc, uint32_t InputReverseMode)
{
/* Check the parameters */
assert_param(IS_CRC_INPUTDATA_INVERSION_MODE(InputReverseMode));
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_BUSY;
/* set input data inversion mode */
MODIFY_REG(hcrc->Instance->CR, CRC_CR_REV_IN, InputReverseMode);
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief Set the Reverse Output data mode.
* @param hcrc CRC handle
* @param OutputReverseMode Output Data inversion mode.
* This parameter can be one of the following values:
* @arg @ref CRC_OUTPUTDATA_INVERSION_DISABLE no CRC inversion (default value)
* @arg @ref CRC_OUTPUTDATA_INVERSION_ENABLE bit-level inversion (e.g. for a 8-bit CRC: 0xB5 becomes 0xAD)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRCEx_Output_Data_Reverse(CRC_HandleTypeDef *hcrc, uint32_t OutputReverseMode)
{
/* Check the parameters */
assert_param(IS_CRC_OUTPUTDATA_INVERSION_MODE(OutputReverseMode));
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_BUSY;
/* set output data inversion mode */
MODIFY_REG(hcrc->Instance->CR, CRC_CR_REV_OUT, OutputReverseMode);
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_CRC_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 7,603 | C | 31.635193 | 117 | 0.548862 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_dma.c | /**
******************************************************************************
* @file stm32g4xx_hal_dma.c
* @author MCD Application Team
* @brief DMA HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Direct Memory Access (DMA) peripheral:
* + Initialization and de-initialization functions
* + IO operation functions
* + Peripheral State and errors functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
(#) Enable and configure the peripheral to be connected to the DMA Channel
(except for internal SRAM / FLASH memories: no initialization is
necessary). Please refer to the Reference manual for connection between peripherals
and DMA requests.
(#) For a given Channel, program the required configuration through the following parameters:
Channel request, Transfer Direction, Source and Destination data formats,
Circular or Normal mode, Channel Priority level, Source and Destination Increment mode
using HAL_DMA_Init() function.
Prior to HAL_DMA_Init the peripheral clock shall be enabled for both DMA & DMAMUX
thanks to:
(##) DMA1 or DMA2: __HAL_RCC_DMA1_CLK_ENABLE() or __HAL_RCC_DMA2_CLK_ENABLE() ;
(##) DMAMUX1: __HAL_RCC_DMAMUX1_CLK_ENABLE();
(#) Use HAL_DMA_GetState() function to return the DMA state and HAL_DMA_GetError() in case of error
detection.
(#) Use HAL_DMA_Abort() function to abort the current transfer
-@- In Memory-to-Memory transfer mode, Circular mode is not allowed.
*** Polling mode IO operation ***
=================================
[..]
(+) Use HAL_DMA_Start() to start DMA transfer after the configuration of Source
address and destination address and the Length of data to be transferred
(+) Use HAL_DMA_PollForTransfer() to poll for the end of current transfer, in this
case a fixed Timeout can be configured by User depending from his application.
*** Interrupt mode IO operation ***
===================================
[..]
(+) Configure the DMA interrupt priority using HAL_NVIC_SetPriority()
(+) Enable the DMA IRQ handler using HAL_NVIC_EnableIRQ()
(+) Use HAL_DMA_Start_IT() to start DMA transfer after the configuration of
Source address and destination address and the Length of data to be transferred.
In this case the DMA interrupt is configured
(+) Use HAL_DMA_IRQHandler() called under DMA_IRQHandler() Interrupt subroutine
(+) At the end of data transfer HAL_DMA_IRQHandler() function is executed and user can
add his own function to register callbacks with HAL_DMA_RegisterCallback().
*** DMA HAL driver macros list ***
=============================================
[..]
Below the list of macros in DMA HAL driver.
(+) __HAL_DMA_ENABLE: Enable the specified DMA Channel.
(+) __HAL_DMA_DISABLE: Disable the specified DMA Channel.
(+) __HAL_DMA_GET_FLAG: Get the DMA Channel pending flags.
(+) __HAL_DMA_CLEAR_FLAG: Clear the DMA Channel pending flags.
(+) __HAL_DMA_ENABLE_IT: Enable the specified DMA Channel interrupts.
(+) __HAL_DMA_DISABLE_IT: Disable the specified DMA Channel interrupts.
(+) __HAL_DMA_GET_IT_SOURCE: Check whether the specified DMA Channel interrupt has occurred or not.
[..]
(@) You can refer to the DMA HAL driver header file for more useful macros
@endverbatim
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup DMA DMA
* @brief DMA HAL module driver
* @{
*/
#ifdef HAL_DMA_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup DMA_Private_Functions DMA Private Functions
* @{
*/
static void DMA_SetConfig(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength);
static void DMA_CalcDMAMUXChannelBaseAndMask(DMA_HandleTypeDef *hdma);
static void DMA_CalcDMAMUXRequestGenBaseAndMask(DMA_HandleTypeDef *hdma);
/**
* @}
*/
/* Exported functions ---------------------------------------------------------*/
/** @defgroup DMA_Exported_Functions DMA Exported Functions
* @{
*/
/** @defgroup DMA_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and de-initialization functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..]
This section provides functions allowing to initialize the DMA Channel source
and destination addresses, incrementation and data sizes, transfer direction,
circular/normal mode selection, memory-to-memory mode selection and Channel priority value.
[..]
The HAL_DMA_Init() function follows the DMA configuration procedures as described in
reference manual.
@endverbatim
* @{
*/
/**
* @brief Initialize the DMA according to the specified
* parameters in the DMA_InitTypeDef and initialize the associated handle.
* @param hdma Pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Init(DMA_HandleTypeDef *hdma)
{
uint32_t tmp;
/* Check the DMA handle allocation */
if (hdma == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
assert_param(IS_DMA_DIRECTION(hdma->Init.Direction));
assert_param(IS_DMA_PERIPHERAL_INC_STATE(hdma->Init.PeriphInc));
assert_param(IS_DMA_MEMORY_INC_STATE(hdma->Init.MemInc));
assert_param(IS_DMA_PERIPHERAL_DATA_SIZE(hdma->Init.PeriphDataAlignment));
assert_param(IS_DMA_MEMORY_DATA_SIZE(hdma->Init.MemDataAlignment));
assert_param(IS_DMA_MODE(hdma->Init.Mode));
assert_param(IS_DMA_PRIORITY(hdma->Init.Priority));
assert_param(IS_DMA_ALL_REQUEST(hdma->Init.Request));
/* Compute the channel index */
if ((uint32_t)(hdma->Instance) < (uint32_t)(DMA2_Channel1))
{
/* DMA1 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA1_Channel1) / ((uint32_t)DMA1_Channel2 - (uint32_t)DMA1_Channel1)) << 2;
hdma->DmaBaseAddress = DMA1;
}
else
{
/* DMA2 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA2_Channel1) / ((uint32_t)DMA2_Channel2 - (uint32_t)DMA2_Channel1)) << 2;
hdma->DmaBaseAddress = DMA2;
}
/* Change DMA peripheral state */
hdma->State = HAL_DMA_STATE_BUSY;
/* Get the CR register value */
tmp = hdma->Instance->CCR;
/* Clear PL, MSIZE, PSIZE, MINC, PINC, CIRC, DIR and MEM2MEM bits */
tmp &= ((uint32_t)~(DMA_CCR_PL | DMA_CCR_MSIZE | DMA_CCR_PSIZE |
DMA_CCR_MINC | DMA_CCR_PINC | DMA_CCR_CIRC |
DMA_CCR_DIR | DMA_CCR_MEM2MEM));
/* Prepare the DMA Channel configuration */
tmp |= hdma->Init.Direction |
hdma->Init.PeriphInc | hdma->Init.MemInc |
hdma->Init.PeriphDataAlignment | hdma->Init.MemDataAlignment |
hdma->Init.Mode | hdma->Init.Priority;
/* Write to DMA Channel CR register */
hdma->Instance->CCR = tmp;
/* Initialize parameters for DMAMUX channel :
DMAmuxChannel, DMAmuxChannelStatus and DMAmuxChannelStatusMask
*/
DMA_CalcDMAMUXChannelBaseAndMask(hdma);
if (hdma->Init.Direction == DMA_MEMORY_TO_MEMORY)
{
/* if memory to memory force the request to 0*/
hdma->Init.Request = DMA_REQUEST_MEM2MEM;
}
/* Set peripheral request to DMAMUX channel */
hdma->DMAmuxChannel->CCR = (hdma->Init.Request & DMAMUX_CxCR_DMAREQ_ID);
/* Clear the DMAMUX synchro overrun flag */
hdma->DMAmuxChannelStatus->CFR = hdma->DMAmuxChannelStatusMask;
if (((hdma->Init.Request > 0U) && (hdma->Init.Request <= DMA_REQUEST_GENERATOR3)))
{
/* Initialize parameters for DMAMUX request generator :
DMAmuxRequestGen, DMAmuxRequestGenStatus and DMAmuxRequestGenStatusMask
*/
DMA_CalcDMAMUXRequestGenBaseAndMask(hdma);
/* Reset the DMAMUX request generator register*/
hdma->DMAmuxRequestGen->RGCR = 0U;
/* Clear the DMAMUX request generator overrun flag */
hdma->DMAmuxRequestGenStatus->RGCFR = hdma->DMAmuxRequestGenStatusMask;
}
else
{
hdma->DMAmuxRequestGen = 0U;
hdma->DMAmuxRequestGenStatus = 0U;
hdma->DMAmuxRequestGenStatusMask = 0U;
}
/* Initialize the error code */
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Initialize the DMA state*/
hdma->State = HAL_DMA_STATE_READY;
/* Allocate lock resource and initialize it */
hdma->Lock = HAL_UNLOCKED;
return HAL_OK;
}
/**
* @brief DeInitialize the DMA peripheral.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_DeInit(DMA_HandleTypeDef *hdma)
{
/* Check the DMA handle allocation */
if (NULL == hdma)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
/* Disable the selected DMA Channelx */
__HAL_DMA_DISABLE(hdma);
/* Compute the channel index */
if ((uint32_t)(hdma->Instance) < (uint32_t)(DMA2_Channel1))
{
/* DMA1 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA1_Channel1) / ((uint32_t)DMA1_Channel2 - (uint32_t)DMA1_Channel1)) << 2;
hdma->DmaBaseAddress = DMA1;
}
else
{
/* DMA2 */
hdma->ChannelIndex = (((uint32_t)hdma->Instance - (uint32_t)DMA2_Channel1) / ((uint32_t)DMA2_Channel2 - (uint32_t)DMA2_Channel1)) << 2;
hdma->DmaBaseAddress = DMA2;
}
/* Reset DMA Channel control register */
hdma->Instance->CCR = 0;
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << (hdma->ChannelIndex & 0x1FU));
/* Initialize parameters for DMAMUX channel :
DMAmuxChannel, DMAmuxChannelStatus and DMAmuxChannelStatusMask */
DMA_CalcDMAMUXChannelBaseAndMask(hdma);
/* Reset the DMAMUX channel that corresponds to the DMA channel */
hdma->DMAmuxChannel->CCR = 0;
/* Clear the DMAMUX synchro overrun flag */
hdma->DMAmuxChannelStatus->CFR = hdma->DMAmuxChannelStatusMask;
/* Reset Request generator parameters if any */
if (((hdma->Init.Request > 0U) && (hdma->Init.Request <= DMA_REQUEST_GENERATOR3)))
{
/* Initialize parameters for DMAMUX request generator :
DMAmuxRequestGen, DMAmuxRequestGenStatus and DMAmuxRequestGenStatusMask
*/
DMA_CalcDMAMUXRequestGenBaseAndMask(hdma);
/* Reset the DMAMUX request generator register*/
hdma->DMAmuxRequestGen->RGCR = 0U;
/* Clear the DMAMUX request generator overrun flag */
hdma->DMAmuxRequestGenStatus->RGCFR = hdma->DMAmuxRequestGenStatusMask;
}
hdma->DMAmuxRequestGen = 0U;
hdma->DMAmuxRequestGenStatus = 0U;
hdma->DMAmuxRequestGenStatusMask = 0U;
/* Clean callbacks */
hdma->XferCpltCallback = NULL;
hdma->XferHalfCpltCallback = NULL;
hdma->XferErrorCallback = NULL;
hdma->XferAbortCallback = NULL;
/* Initialize the error code */
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Initialize the DMA state */
hdma->State = HAL_DMA_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(hdma);
return HAL_OK;
}
/**
* @}
*/
/** @defgroup DMA_Exported_Functions_Group2 Input and Output operation functions
* @brief Input and Output operation functions
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Configure the source, destination address and data length and Start DMA transfer
(+) Configure the source, destination address and data length and
Start DMA transfer with interrupt
(+) Abort DMA transfer
(+) Poll for transfer complete
(+) Handle DMA interrupt request
@endverbatim
* @{
*/
/**
* @brief Start the DMA Transfer.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param SrcAddress The source memory Buffer address
* @param DstAddress The destination memory Buffer address
* @param DataLength The length of data to be transferred from source to destination (up to 256Kbytes-1)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Start(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_DMA_BUFFER_SIZE(DataLength));
/* Process locked */
__HAL_LOCK(hdma);
if (HAL_DMA_STATE_READY == hdma->State)
{
/* Change DMA peripheral state */
hdma->State = HAL_DMA_STATE_BUSY;
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Disable the peripheral */
__HAL_DMA_DISABLE(hdma);
/* Configure the source, destination address and the data length & clear flags*/
DMA_SetConfig(hdma, SrcAddress, DstAddress, DataLength);
/* Enable the Peripheral */
__HAL_DMA_ENABLE(hdma);
}
else
{
/* Process Unlocked */
__HAL_UNLOCK(hdma);
status = HAL_BUSY;
}
return status;
}
/**
* @brief Start the DMA Transfer with interrupt enabled.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param SrcAddress The source memory Buffer address
* @param DstAddress The destination memory Buffer address
* @param DataLength The length of data to be transferred from source to destination (up to 256Kbytes-1)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Start_IT(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress,
uint32_t DataLength)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_DMA_BUFFER_SIZE(DataLength));
/* Process locked */
__HAL_LOCK(hdma);
if (HAL_DMA_STATE_READY == hdma->State)
{
/* Change DMA peripheral state */
hdma->State = HAL_DMA_STATE_BUSY;
hdma->ErrorCode = HAL_DMA_ERROR_NONE;
/* Disable the peripheral */
__HAL_DMA_DISABLE(hdma);
/* Configure the source, destination address and the data length & clear flags*/
DMA_SetConfig(hdma, SrcAddress, DstAddress, DataLength);
/* Enable the transfer complete interrupt */
/* Enable the transfer Error interrupt */
if (NULL != hdma->XferHalfCpltCallback)
{
/* Enable the Half transfer complete interrupt as well */
__HAL_DMA_ENABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
}
else
{
__HAL_DMA_DISABLE_IT(hdma, DMA_IT_HT);
__HAL_DMA_ENABLE_IT(hdma, (DMA_IT_TC | DMA_IT_TE));
}
/* Check if DMAMUX Synchronization is enabled*/
if ((hdma->DMAmuxChannel->CCR & DMAMUX_CxCR_SE) != 0U)
{
/* Enable DMAMUX sync overrun IT*/
hdma->DMAmuxChannel->CCR |= DMAMUX_CxCR_SOIE;
}
if (hdma->DMAmuxRequestGen != 0U)
{
/* if using DMAMUX request generator, enable the DMAMUX request generator overrun IT*/
/* enable the request gen overrun IT*/
hdma->DMAmuxRequestGen->RGCR |= DMAMUX_RGxCR_OIE;
}
/* Enable the Peripheral */
__HAL_DMA_ENABLE(hdma);
}
else
{
/* Process Unlocked */
__HAL_UNLOCK(hdma);
/* Remain BUSY */
status = HAL_BUSY;
}
return status;
}
/**
* @brief Abort the DMA Transfer.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Abort(DMA_HandleTypeDef *hdma)
{
HAL_StatusTypeDef status = HAL_OK;
if(hdma->State != HAL_DMA_STATE_BUSY)
{
/* no transfer ongoing */
hdma->ErrorCode = HAL_DMA_ERROR_NO_XFER;
status = HAL_ERROR;
}
else
{
/* Disable DMA IT */
__HAL_DMA_DISABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
/* disable the DMAMUX sync overrun IT*/
hdma->DMAmuxChannel->CCR &= ~DMAMUX_CxCR_SOIE;
/* Disable the channel */
__HAL_DMA_DISABLE(hdma);
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << (hdma->ChannelIndex & 0x1FU));
/* Clear the DMAMUX synchro overrun flag */
hdma->DMAmuxChannelStatus->CFR = hdma->DMAmuxChannelStatusMask;
if (hdma->DMAmuxRequestGen != 0U)
{
/* if using DMAMUX request generator, disable the DMAMUX request generator overrun IT*/
/* disable the request gen overrun IT*/
hdma->DMAmuxRequestGen->RGCR &= ~DMAMUX_RGxCR_OIE;
/* Clear the DMAMUX request generator overrun flag */
hdma->DMAmuxRequestGenStatus->RGCFR = hdma->DMAmuxRequestGenStatusMask;
}
}
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
return status;
}
/**
* @brief Aborts the DMA Transfer in Interrupt mode.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_Abort_IT(DMA_HandleTypeDef *hdma)
{
HAL_StatusTypeDef status = HAL_OK;
if (HAL_DMA_STATE_BUSY != hdma->State)
{
/* no transfer ongoing */
hdma->ErrorCode = HAL_DMA_ERROR_NO_XFER;
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
status = HAL_ERROR;
}
else
{
/* Disable DMA IT */
__HAL_DMA_DISABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
/* Disable the channel */
__HAL_DMA_DISABLE(hdma);
/* disable the DMAMUX sync overrun IT*/
hdma->DMAmuxChannel->CCR &= ~DMAMUX_CxCR_SOIE;
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << (hdma->ChannelIndex & 0x1FU));
/* Clear the DMAMUX synchro overrun flag */
hdma->DMAmuxChannelStatus->CFR = hdma->DMAmuxChannelStatusMask;
if (hdma->DMAmuxRequestGen != 0U)
{
/* if using DMAMUX request generator, disable the DMAMUX request generator overrun IT*/
/* disable the request gen overrun IT*/
hdma->DMAmuxRequestGen->RGCR &= ~DMAMUX_RGxCR_OIE;
/* Clear the DMAMUX request generator overrun flag */
hdma->DMAmuxRequestGenStatus->RGCFR = hdma->DMAmuxRequestGenStatusMask;
}
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
/* Call User Abort callback */
if (hdma->XferAbortCallback != NULL)
{
hdma->XferAbortCallback(hdma);
}
}
return status;
}
/**
* @brief Polling for transfer complete.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param CompleteLevel Specifies the DMA level complete.
* @param Timeout Timeout duration.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_PollForTransfer(DMA_HandleTypeDef *hdma, HAL_DMA_LevelCompleteTypeDef CompleteLevel,
uint32_t Timeout)
{
uint32_t temp;
uint32_t tickstart;
if (HAL_DMA_STATE_BUSY != hdma->State)
{
/* no transfer ongoing */
hdma->ErrorCode = HAL_DMA_ERROR_NO_XFER;
__HAL_UNLOCK(hdma);
return HAL_ERROR;
}
/* Polling mode not supported in circular mode */
if (0U != (hdma->Instance->CCR & DMA_CCR_CIRC))
{
hdma->ErrorCode = HAL_DMA_ERROR_NOT_SUPPORTED;
return HAL_ERROR;
}
/* Get the level transfer complete flag */
if (HAL_DMA_FULL_TRANSFER == CompleteLevel)
{
/* Transfer Complete flag */
temp = (uint32_t)DMA_FLAG_TC1 << (hdma->ChannelIndex & 0x1FU);
}
else
{
/* Half Transfer Complete flag */
temp = (uint32_t)DMA_FLAG_HT1 << (hdma->ChannelIndex & 0x1FU);
}
/* Get tick */
tickstart = HAL_GetTick();
while (0U == (hdma->DmaBaseAddress->ISR & temp))
{
if ((0U != (hdma->DmaBaseAddress->ISR & ((uint32_t)DMA_FLAG_TE1 << (hdma->ChannelIndex & 0x1FU)))))
{
/* When a DMA transfer error occurs */
/* A hardware clear of its EN bits is performed */
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = ((uint32_t)DMA_ISR_GIF1 << (hdma->ChannelIndex & 0x1FU));
/* Update error code */
hdma->ErrorCode = HAL_DMA_ERROR_TE;
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
return HAL_ERROR;
}
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
/* Update error code */
hdma->ErrorCode = HAL_DMA_ERROR_TIMEOUT;
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
return HAL_ERROR;
}
}
}
/*Check for DMAMUX Request generator (if used) overrun status */
if (hdma->DMAmuxRequestGen != 0U)
{
/* if using DMAMUX request generator Check for DMAMUX request generator overrun */
if ((hdma->DMAmuxRequestGenStatus->RGSR & hdma->DMAmuxRequestGenStatusMask) != 0U)
{
/* Disable the request gen overrun interrupt */
hdma->DMAmuxRequestGen->RGCR |= DMAMUX_RGxCR_OIE;
/* Clear the DMAMUX request generator overrun flag */
hdma->DMAmuxRequestGenStatus->RGCFR = hdma->DMAmuxRequestGenStatusMask;
/* Update error code */
hdma->ErrorCode |= HAL_DMA_ERROR_REQGEN;
}
}
/* Check for DMAMUX Synchronization overrun */
if ((hdma->DMAmuxChannelStatus->CSR & hdma->DMAmuxChannelStatusMask) != 0U)
{
/* Clear the DMAMUX synchro overrun flag */
hdma->DMAmuxChannelStatus->CFR = hdma->DMAmuxChannelStatusMask;
/* Update error code */
hdma->ErrorCode |= HAL_DMA_ERROR_SYNC;
}
if (HAL_DMA_FULL_TRANSFER == CompleteLevel)
{
/* Clear the transfer complete flag */
hdma->DmaBaseAddress->IFCR = ((uint32_t)DMA_FLAG_TC1 << (hdma->ChannelIndex & 0x1FU));
/* The selected Channelx EN bit is cleared (DMA is disabled and
all transfers are complete) */
hdma->State = HAL_DMA_STATE_READY;
}
else
{
/* Clear the half transfer complete flag */
hdma->DmaBaseAddress->IFCR = ((uint32_t)DMA_FLAG_HT1 << (hdma->ChannelIndex & 0x1FU));
}
/* Process unlocked */
__HAL_UNLOCK(hdma);
return HAL_OK;
}
/**
* @brief Handle DMA interrupt request.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval None
*/
void HAL_DMA_IRQHandler(DMA_HandleTypeDef *hdma)
{
uint32_t flag_it = hdma->DmaBaseAddress->ISR;
uint32_t source_it = hdma->Instance->CCR;
/* Half Transfer Complete Interrupt management ******************************/
if ((0U != (flag_it & ((uint32_t)DMA_FLAG_HT1 << (hdma->ChannelIndex & 0x1FU)))) && (0U != (source_it & DMA_IT_HT)))
{
/* Disable the half transfer interrupt if the DMA mode is not CIRCULAR */
if ((hdma->Instance->CCR & DMA_CCR_CIRC) == 0U)
{
/* Disable the half transfer interrupt */
__HAL_DMA_DISABLE_IT(hdma, DMA_IT_HT);
}
/* Clear the half transfer complete flag */
hdma->DmaBaseAddress->IFCR = ((uint32_t)DMA_ISR_HTIF1 << (hdma->ChannelIndex & 0x1FU));
/* DMA peripheral state is not updated in Half Transfer */
/* but in Transfer Complete case */
if (hdma->XferHalfCpltCallback != NULL)
{
/* Half transfer callback */
hdma->XferHalfCpltCallback(hdma);
}
}
/* Transfer Complete Interrupt management ***********************************/
else if ((0U != (flag_it & ((uint32_t)DMA_FLAG_TC1 << (hdma->ChannelIndex & 0x1FU))))
&& (0U != (source_it & DMA_IT_TC)))
{
if ((hdma->Instance->CCR & DMA_CCR_CIRC) == 0U)
{
/* Disable the transfer complete and error interrupt */
__HAL_DMA_DISABLE_IT(hdma, DMA_IT_TE | DMA_IT_TC);
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
}
/* Clear the transfer complete flag */
hdma->DmaBaseAddress->IFCR = ((uint32_t)DMA_ISR_TCIF1 << (hdma->ChannelIndex & 0x1FU));
/* Process Unlocked */
__HAL_UNLOCK(hdma);
if (hdma->XferCpltCallback != NULL)
{
/* Transfer complete callback */
hdma->XferCpltCallback(hdma);
}
}
/* Transfer Error Interrupt management **************************************/
else if ((0U != (flag_it & ((uint32_t)DMA_FLAG_TE1 << (hdma->ChannelIndex & 0x1FU))))
&& (0U != (source_it & DMA_IT_TE)))
{
/* When a DMA transfer error occurs */
/* A hardware clear of its EN bits is performed */
/* Disable ALL DMA IT */
__HAL_DMA_DISABLE_IT(hdma, (DMA_IT_TC | DMA_IT_HT | DMA_IT_TE));
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = ((uint32_t)DMA_ISR_GIF1 << (hdma->ChannelIndex & 0x1FU));
/* Update error code */
hdma->ErrorCode = HAL_DMA_ERROR_TE;
/* Change the DMA state */
hdma->State = HAL_DMA_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hdma);
if (hdma->XferErrorCallback != NULL)
{
/* Transfer error callback */
hdma->XferErrorCallback(hdma);
}
}
else
{
/* Nothing To Do */
}
return;
}
/**
* @brief Register callbacks
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param CallbackID User Callback identifier
* a HAL_DMA_CallbackIDTypeDef ENUM as parameter.
* @param pCallback pointer to private callbacsk function which has pointer to
* a DMA_HandleTypeDef structure as parameter.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_RegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID, void (* pCallback)(DMA_HandleTypeDef *_hdma))
{
HAL_StatusTypeDef status = HAL_OK;
/* Process locked */
__HAL_LOCK(hdma);
if (HAL_DMA_STATE_READY == hdma->State)
{
switch (CallbackID)
{
case HAL_DMA_XFER_CPLT_CB_ID:
hdma->XferCpltCallback = pCallback;
break;
case HAL_DMA_XFER_HALFCPLT_CB_ID:
hdma->XferHalfCpltCallback = pCallback;
break;
case HAL_DMA_XFER_ERROR_CB_ID:
hdma->XferErrorCallback = pCallback;
break;
case HAL_DMA_XFER_ABORT_CB_ID:
hdma->XferAbortCallback = pCallback;
break;
default:
status = HAL_ERROR;
break;
}
}
else
{
status = HAL_ERROR;
}
/* Release Lock */
__HAL_UNLOCK(hdma);
return status;
}
/**
* @brief UnRegister callbacks
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param CallbackID User Callback identifier
* a HAL_DMA_CallbackIDTypeDef ENUM as parameter.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMA_UnRegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID)
{
HAL_StatusTypeDef status = HAL_OK;
/* Process locked */
__HAL_LOCK(hdma);
if (HAL_DMA_STATE_READY == hdma->State)
{
switch (CallbackID)
{
case HAL_DMA_XFER_CPLT_CB_ID:
hdma->XferCpltCallback = NULL;
break;
case HAL_DMA_XFER_HALFCPLT_CB_ID:
hdma->XferHalfCpltCallback = NULL;
break;
case HAL_DMA_XFER_ERROR_CB_ID:
hdma->XferErrorCallback = NULL;
break;
case HAL_DMA_XFER_ABORT_CB_ID:
hdma->XferAbortCallback = NULL;
break;
case HAL_DMA_XFER_ALL_CB_ID:
hdma->XferCpltCallback = NULL;
hdma->XferHalfCpltCallback = NULL;
hdma->XferErrorCallback = NULL;
hdma->XferAbortCallback = NULL;
break;
default:
status = HAL_ERROR;
break;
}
}
else
{
status = HAL_ERROR;
}
/* Release Lock */
__HAL_UNLOCK(hdma);
return status;
}
/**
* @}
*/
/** @defgroup DMA_Exported_Functions_Group3 Peripheral State and Errors functions
* @brief Peripheral State and Errors functions
*
@verbatim
===============================================================================
##### Peripheral State and Errors functions #####
===============================================================================
[..]
This subsection provides functions allowing to
(+) Check the DMA state
(+) Get error code
@endverbatim
* @{
*/
/**
* @brief Return the DMA hande state.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval HAL state
*/
HAL_DMA_StateTypeDef HAL_DMA_GetState(DMA_HandleTypeDef *hdma)
{
/* Return DMA handle state */
return hdma->State;
}
/**
* @brief Return the DMA error code.
* @param hdma : pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval DMA Error Code
*/
uint32_t HAL_DMA_GetError(DMA_HandleTypeDef *hdma)
{
return hdma->ErrorCode;
}
/**
* @}
*/
/**
* @}
*/
/** @addtogroup DMA_Private_Functions
* @{
*/
/**
* @brief Sets the DMA Transfer parameter.
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @param SrcAddress The source memory Buffer address
* @param DstAddress The destination memory Buffer address
* @param DataLength The length of data to be transferred from source to destination
* @retval HAL status
*/
static void DMA_SetConfig(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength)
{
/* Clear the DMAMUX synchro overrun flag */
hdma->DMAmuxChannelStatus->CFR = hdma->DMAmuxChannelStatusMask;
if (hdma->DMAmuxRequestGen != 0U)
{
/* Clear the DMAMUX request generator overrun flag */
hdma->DMAmuxRequestGenStatus->RGCFR = hdma->DMAmuxRequestGenStatusMask;
}
/* Clear all flags */
hdma->DmaBaseAddress->IFCR = (DMA_ISR_GIF1 << (hdma->ChannelIndex & 0x1FU));
/* Configure DMA Channel data length */
hdma->Instance->CNDTR = DataLength;
/* Memory to Peripheral */
if ((hdma->Init.Direction) == DMA_MEMORY_TO_PERIPH)
{
/* Configure DMA Channel destination address */
hdma->Instance->CPAR = DstAddress;
/* Configure DMA Channel source address */
hdma->Instance->CMAR = SrcAddress;
}
/* Peripheral to Memory */
else
{
/* Configure DMA Channel source address */
hdma->Instance->CPAR = SrcAddress;
/* Configure DMA Channel destination address */
hdma->Instance->CMAR = DstAddress;
}
}
/**
* @brief Updates the DMA handle with the DMAMUX channel and status mask depending on stream number
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Stream.
* @retval None
*/
static void DMA_CalcDMAMUXChannelBaseAndMask(DMA_HandleTypeDef *hdma)
{
uint32_t dmamux_base_addr;
uint32_t channel_number;
DMAMUX_Channel_TypeDef *DMAMUX1_ChannelBase;
/* check if instance is not outside the DMA channel range */
if ((uint32_t)hdma->Instance < (uint32_t)DMA2_Channel1)
{
/* DMA1 */
DMAMUX1_ChannelBase = DMAMUX1_Channel0;
}
else
{
/* DMA2 */
#if defined (STM32G471xx) || defined (STM32G473xx) || defined (STM32G474xx) || defined (STM32G483xx) || defined (STM32G484xx) || defined (STM32G491xx) || defined (STM32G4A1xx)
DMAMUX1_ChannelBase = DMAMUX1_Channel8;
#elif defined (STM32G431xx) || defined (STM32G441xx) || defined (STM32GBK1CB)
DMAMUX1_ChannelBase = DMAMUX1_Channel6;
#else
DMAMUX1_ChannelBase = DMAMUX1_Channel7;
#endif /* STM32G4x1xx) */
}
dmamux_base_addr = (uint32_t)DMAMUX1_ChannelBase;
channel_number = (((uint32_t)hdma->Instance & 0xFFU) - 8U) / 20U;
hdma->DMAmuxChannel = (DMAMUX_Channel_TypeDef *)(uint32_t)(dmamux_base_addr + ((hdma->ChannelIndex >> 2U) * ((uint32_t)DMAMUX1_Channel1 - (uint32_t)DMAMUX1_Channel0)));
hdma->DMAmuxChannelStatus = DMAMUX1_ChannelStatus;
hdma->DMAmuxChannelStatusMask = 1UL << (channel_number & 0x1FU);
}
/**
* @brief Updates the DMA handle with the DMAMUX request generator params
* @param hdma pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA Channel.
* @retval None
*/
static void DMA_CalcDMAMUXRequestGenBaseAndMask(DMA_HandleTypeDef *hdma)
{
uint32_t request = hdma->Init.Request & DMAMUX_CxCR_DMAREQ_ID;
/* DMA Channels are connected to DMAMUX1 request generator blocks*/
hdma->DMAmuxRequestGen = (DMAMUX_RequestGen_TypeDef *)((uint32_t)(((uint32_t)DMAMUX1_RequestGenerator0) + ((request - 1U) * 4U)));
hdma->DMAmuxRequestGenStatus = DMAMUX1_RequestGenStatus;
hdma->DMAmuxRequestGenStatusMask = 1UL << ((request - 1U) & 0x1FU);
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_DMA_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 34,993 | C | 30.49775 | 175 | 0.619152 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_rcc.c | /**
******************************************************************************
* @file stm32g4xx_hal_rcc.c
* @author MCD Application Team
* @brief RCC HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Reset and Clock Control (RCC) peripheral:
* + Initialization and de-initialization functions
* + Peripheral Control functions
*
@verbatim
==============================================================================
##### RCC specific features #####
==============================================================================
[..]
After reset the device is running from High Speed Internal oscillator
(16 MHz) with Flash 0 wait state. Flash prefetch buffer, D-Cache
and I-Cache are disabled, and all peripherals are off except internal
SRAM, Flash and JTAG.
(+) There is no prescaler on High speed (AHBs) and Low speed (APBs) buses:
all peripherals mapped on these buses are running at HSI speed.
(+) The clock for all peripherals is switched off, except the SRAM and FLASH.
(+) All GPIOs are in analog mode, except the JTAG pins which
are assigned to be used for debug purpose.
[..]
Once the device started from reset, the user application has to:
(+) Configure the clock source to be used to drive the System clock
(if the application needs higher frequency/performance)
(+) Configure the System clock frequency and Flash settings
(+) Configure the AHB and APB buses prescalers
(+) Enable the clock for the peripheral(s) to be used
(+) Configure the clock source(s) for peripherals which clocks are not
derived from the System clock (USB, RNG, USART, LPUART, FDCAN, some TIMERs,
UCPD, I2S, I2C, LPTIM, ADC, QSPI)
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup RCC RCC
* @brief RCC HAL module driver
* @{
*/
#ifdef HAL_RCC_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup RCC_Private_Constants RCC Private Constants
* @{
*/
#define HSE_TIMEOUT_VALUE HSE_STARTUP_TIMEOUT
#define HSI_TIMEOUT_VALUE 2U /* 2 ms (minimum Tick + 1) */
#define LSI_TIMEOUT_VALUE 2U /* 2 ms (minimum Tick + 1) */
#define HSI48_TIMEOUT_VALUE 2U /* 2 ms (minimum Tick + 1) */
#define PLL_TIMEOUT_VALUE 2U /* 2 ms (minimum Tick + 1) */
#define CLOCKSWITCH_TIMEOUT_VALUE 5000U /* 5 s */
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/** @defgroup RCC_Private_Macros RCC Private Macros
* @{
*/
#define RCC_GET_MCO_GPIO_PIN(__RCC_MCOx__) ((__RCC_MCOx__) & GPIO_PIN_MASK)
#define RCC_GET_MCO_GPIO_AF(__RCC_MCOx__) (((__RCC_MCOx__) & RCC_MCO_GPIOAF_MASK) >> RCC_MCO_GPIOAF_POS)
#define RCC_GET_MCO_GPIO_INDEX(__RCC_MCOx__) (((__RCC_MCOx__) & RCC_MCO_GPIOPORT_MASK) >> RCC_MCO_GPIOPORT_POS)
#define RCC_GET_MCO_GPIO_PORT(__RCC_MCOx__) (AHB2PERIPH_BASE + ((0x00000400UL) * RCC_GET_MCO_GPIO_INDEX(__RCC_MCOx__)))
#define RCC_PLL_OSCSOURCE_CONFIG(__HAL_RCC_PLLSOURCE__) \
(MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC, (__HAL_RCC_PLLSOURCE__)))
/**
* @}
*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup RCC_Private_Functions RCC Private Functions
* @{
*/
static uint32_t RCC_GetSysClockFreqFromPLLSource(void);
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup RCC_Exported_Functions RCC Exported Functions
* @{
*/
/** @defgroup RCC_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and Configuration functions
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..]
This section provides functions allowing to configure the internal and external oscillators
(HSE, HSI, LSE, LSI, PLL, CSS and MCO) and the System buses clocks (SYSCLK, AHB, APB1
and APB2).
[..] Internal/external clock and PLL configuration
(+) HSI (high-speed internal): 16 MHz factory-trimmed RC used directly or through
the PLL as System clock source.
(+) LSI (low-speed internal): 32 KHz low consumption RC used as IWDG and/or RTC
clock source.
(+) HSE (high-speed external): 4 to 48 MHz crystal oscillator used directly or
through the PLL as System clock source. Can be used also optionally as RTC clock source.
(+) LSE (low-speed external): 32.768 KHz oscillator used optionally as RTC clock source.
(+) PLL (clocked by HSI, HSE) providing up to three independent output clocks:
(++) The first output is used to generate the high speed system clock (up to 170 MHz).
(++) The second output is used to generate the clock for the USB (48 MHz),
the QSPI (<= 48 MHz), the FDCAN, the SAI and the I2S.
(++) The third output is used to generate a clock for ADC
(+) CSS (Clock security system): once enabled, if a HSE clock failure occurs
(HSE used directly or through PLL as System clock source), the System clock
is automatically switched to HSI and an interrupt is generated if enabled.
The interrupt is linked to the Cortex-M4 NMI (Non-Maskable Interrupt)
exception vector.
(+) MCO (microcontroller clock output): used to output LSI, HSI, LSE, HSE,
main PLL clock, system clock or RC48 clock (through a configurable prescaler) on PA8 pin.
[..] System, AHB and APB buses clocks configuration
(+) Several clock sources can be used to drive the System clock (SYSCLK): HSI,
HSE and main PLL.
The AHB clock (HCLK) is derived from System clock through configurable
prescaler and used to clock the CPU, memory and peripherals mapped
on AHB bus (DMA, GPIO...). APB1 (PCLK1) and APB2 (PCLK2) clocks are derived
from AHB clock through configurable prescalers and used to clock
the peripherals mapped on these buses. You can use
"HAL_RCC_GetSysClockFreq()" function to retrieve the frequencies of these clocks.
-@- All the peripheral clocks are derived from the System clock (SYSCLK) except:
(+@) RTC: the RTC clock can be derived either from the LSI, LSE or HSE clock
divided by 2 to 31.
You have to use __HAL_RCC_RTC_ENABLE() and HAL_RCCEx_PeriphCLKConfig() function
to configure this clock.
(+@) USB FS and RNG: USB FS requires a frequency equal to 48 MHz
to work correctly, while the RNG peripheral requires a frequency
equal or lower than to 48 MHz. This clock is derived of the main PLL
through PLLQ divider. You have to enable the peripheral clock and use
HAL_RCCEx_PeriphCLKConfig() function to configure this clock.
(+@) IWDG clock which is always the LSI clock.
(+) The maximum frequency of the SYSCLK, HCLK, PCLK1 and PCLK2 is 170 MHz.
The clock source frequency should be adapted depending on the device voltage range
as listed in the Reference Manual "Clock source frequency versus voltage scaling" chapter.
@endverbatim
Table 1. HCLK clock frequency for STM32G4xx devices
+----------------------------------------------------------------------------+
| Latency | HCLK clock frequency (MHz) |
| |----------------------------------------------------------|
| | voltage range 1 | voltage range 1 | voltage range 2 |
| | boost mode 1.28 V | normal mode 1.2 V | 1.0 V |
|-----------------|-------------------|-------------------|------------------|
|0WS(1 CPU cycles)| HCLK <= 34 | HCLK <= 30 | HCLK <= 13 |
|-----------------|-------------------|-------------------|------------------|
|1WS(2 CPU cycles)| HCLK <= 68 | HCLK <= 60 | HCLK <= 26 |
|-----------------|-------------------|-------------------|------------------|
|2WS(3 CPU cycles)| HCLK <= 102 | HCLK <= 90 | - |
|-----------------|-------------------|-------------------|------------------|
|3WS(4 CPU cycles)| HCLK <= 136 | HCLK <= 120 | - |
|-----------------|-------------------|-------------------|------------------|
|4WS(5 CPU cycles)| HCLK <= 170 | HCLK <= 150 | - |
+----------------------------------------------------------------------------+
* @{
*/
/**
* @brief Reset the RCC clock configuration to the default reset state.
* @note The default reset state of the clock configuration is given below:
* - HSI ON and used as system clock source
* - HSE, PLL OFF
* - AHB, APB1 and APB2 prescaler set to 1.
* - CSS, MCO1 OFF
* - All interrupts disabled
* - All interrupt and reset flags cleared
* @note This function doesn't modify the configuration of the
* - Peripheral clocks
* - LSI, LSE and RTC clocks
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCC_DeInit(void)
{
uint32_t tickstart;
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Set HSION bit to the reset value */
SET_BIT(RCC->CR, RCC_CR_HSION);
/* Wait till HSI is ready */
while (READ_BIT(RCC->CR, RCC_CR_HSIRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > HSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Set HSITRIM[6:0] bits to the reset value */
SET_BIT(RCC->ICSCR, RCC_HSICALIBRATION_DEFAULT << RCC_ICSCR_HSITRIM_Pos);
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Reset CFGR register (HSI is selected as system clock source) */
RCC->CFGR = 0x00000001u;
/* Wait till HSI is ready */
while (READ_BIT(RCC->CFGR, RCC_CFGR_SWS) != RCC_CFGR_SWS_HSI)
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Update the SystemCoreClock global variable */
SystemCoreClock = HSI_VALUE;
/* Adapt Systick interrupt period */
if (HAL_InitTick(uwTickPrio) != HAL_OK)
{
return HAL_ERROR;
}
/* Clear CR register in 2 steps: first to clear HSEON in case bypass was enabled */
RCC->CR = RCC_CR_HSION;
/* Then again to HSEBYP in case bypass was enabled */
RCC->CR = RCC_CR_HSION;
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL is OFF */
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* once PLL is OFF, reset PLLCFGR register to default value */
RCC->PLLCFGR = RCC_PLLCFGR_PLLN_4;
/* Disable all interrupts */
CLEAR_REG(RCC->CIER);
/* Clear all interrupt flags */
WRITE_REG(RCC->CICR, 0xFFFFFFFFU);
/* Clear all reset flags */
SET_BIT(RCC->CSR, RCC_CSR_RMVF);
return HAL_OK;
}
/**
* @brief Initialize the RCC Oscillators according to the specified parameters in the
* RCC_OscInitTypeDef.
* @param RCC_OscInitStruct pointer to an RCC_OscInitTypeDef structure that
* contains the configuration information for the RCC Oscillators.
* @note The PLL is not disabled when used as system clock.
* @note Transitions LSE Bypass to LSE On and LSE On to LSE Bypass are not
* supported by this macro. User should request a transition to LSE Off
* first and then LSE On or LSE Bypass.
* @note Transition HSE Bypass to HSE On and HSE On to HSE Bypass are not
* supported by this macro. User should request a transition to HSE Off
* first and then HSE On or HSE Bypass.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCC_OscConfig(RCC_OscInitTypeDef *RCC_OscInitStruct)
{
uint32_t tickstart;
uint32_t temp_sysclksrc;
uint32_t temp_pllckcfg;
/* Check Null pointer */
if (RCC_OscInitStruct == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_RCC_OSCILLATORTYPE(RCC_OscInitStruct->OscillatorType));
/*------------------------------- HSE Configuration ------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_HSE) == RCC_OSCILLATORTYPE_HSE)
{
/* Check the parameters */
assert_param(IS_RCC_HSE(RCC_OscInitStruct->HSEState));
temp_sysclksrc = __HAL_RCC_GET_SYSCLK_SOURCE();
temp_pllckcfg = __HAL_RCC_GET_PLL_OSCSOURCE();
/* When the HSE is used as system clock or clock source for PLL in these cases it is not allowed to be disabled */
if (((temp_sysclksrc == RCC_CFGR_SWS_PLL) && (temp_pllckcfg == RCC_PLLSOURCE_HSE)) || (temp_sysclksrc == RCC_CFGR_SWS_HSE))
{
if ((READ_BIT(RCC->CR, RCC_CR_HSERDY) != 0U) && (RCC_OscInitStruct->HSEState == RCC_HSE_OFF))
{
return HAL_ERROR;
}
}
else
{
/* Set the new HSE configuration ---------------------------------------*/
__HAL_RCC_HSE_CONFIG(RCC_OscInitStruct->HSEState);
/* Check the HSE State */
if (RCC_OscInitStruct->HSEState != RCC_HSE_OFF)
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSE is ready */
while (READ_BIT(RCC->CR, RCC_CR_HSERDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > HSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSE is disabled */
while (READ_BIT(RCC->CR, RCC_CR_HSERDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > HSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
}
/*----------------------------- HSI Configuration --------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_HSI) == RCC_OSCILLATORTYPE_HSI)
{
/* Check the parameters */
assert_param(IS_RCC_HSI(RCC_OscInitStruct->HSIState));
assert_param(IS_RCC_HSI_CALIBRATION_VALUE(RCC_OscInitStruct->HSICalibrationValue));
/* Check if HSI is used as system clock or as PLL source when PLL is selected as system clock */
temp_sysclksrc = __HAL_RCC_GET_SYSCLK_SOURCE();
temp_pllckcfg = __HAL_RCC_GET_PLL_OSCSOURCE();
if (((temp_sysclksrc == RCC_CFGR_SWS_PLL) && (temp_pllckcfg == RCC_PLLSOURCE_HSI)) || (temp_sysclksrc == RCC_CFGR_SWS_HSI))
{
/* When HSI is used as system clock it will not be disabled */
if ((READ_BIT(RCC->CR, RCC_CR_HSIRDY) != 0U) && (RCC_OscInitStruct->HSIState == RCC_HSI_OFF))
{
return HAL_ERROR;
}
/* Otherwise, just the calibration is allowed */
else
{
/* Adjusts the Internal High Speed oscillator (HSI) calibration value.*/
__HAL_RCC_HSI_CALIBRATIONVALUE_ADJUST(RCC_OscInitStruct->HSICalibrationValue);
/* Adapt Systick interrupt period */
if (HAL_InitTick(uwTickPrio) != HAL_OK)
{
return HAL_ERROR;
}
}
}
else
{
/* Check the HSI State */
if (RCC_OscInitStruct->HSIState != RCC_HSI_OFF)
{
/* Enable the Internal High Speed oscillator (HSI). */
__HAL_RCC_HSI_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI is ready */
while (READ_BIT(RCC->CR, RCC_CR_HSIRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > HSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Adjusts the Internal High Speed oscillator (HSI) calibration value.*/
__HAL_RCC_HSI_CALIBRATIONVALUE_ADJUST(RCC_OscInitStruct->HSICalibrationValue);
}
else
{
/* Disable the Internal High Speed oscillator (HSI). */
__HAL_RCC_HSI_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI is disabled */
while (READ_BIT(RCC->CR, RCC_CR_HSIRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > HSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
}
/*------------------------------ LSI Configuration -------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_LSI) == RCC_OSCILLATORTYPE_LSI)
{
/* Check the parameters */
assert_param(IS_RCC_LSI(RCC_OscInitStruct->LSIState));
/* Check the LSI State */
if(RCC_OscInitStruct->LSIState != RCC_LSI_OFF)
{
/* Enable the Internal Low Speed oscillator (LSI). */
__HAL_RCC_LSI_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSI is ready */
while (READ_BIT(RCC->CSR, RCC_CSR_LSIRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > LSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Disable the Internal Low Speed oscillator (LSI). */
__HAL_RCC_LSI_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSI is disabled */
while(READ_BIT(RCC->CSR, RCC_CSR_LSIRDY) != 0U)
{
if((HAL_GetTick() - tickstart) > LSI_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
/*------------------------------ LSE Configuration -------------------------*/
if (((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_LSE) == RCC_OSCILLATORTYPE_LSE)
{
FlagStatus pwrclkchanged = RESET;
/* Check the parameters */
assert_param(IS_RCC_LSE(RCC_OscInitStruct->LSEState));
/* Update LSE configuration in Backup Domain control register */
/* Requires to enable write access to Backup Domain if necessary */
if (__HAL_RCC_PWR_IS_CLK_DISABLED() != 0U)
{
__HAL_RCC_PWR_CLK_ENABLE();
pwrclkchanged = SET;
}
if (HAL_IS_BIT_CLR(PWR->CR1, PWR_CR1_DBP))
{
/* Enable write access to Backup domain */
SET_BIT(PWR->CR1, PWR_CR1_DBP);
/* Wait for Backup domain Write protection disable */
tickstart = HAL_GetTick();
while (HAL_IS_BIT_CLR(PWR->CR1, PWR_CR1_DBP))
{
if ((HAL_GetTick() - tickstart) > RCC_DBP_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
/* Set the new LSE configuration -----------------------------------------*/
__HAL_RCC_LSE_CONFIG(RCC_OscInitStruct->LSEState);
/* Check the LSE State */
if (RCC_OscInitStruct->LSEState != RCC_LSE_OFF)
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSE is ready */
while (READ_BIT(RCC->BDCR, RCC_BDCR_LSERDY) == 0U)
{
if((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSE is disabled */
while (READ_BIT(RCC->BDCR, RCC_BDCR_LSERDY) != 0U)
{
if((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
/* Restore clock configuration if changed */
if (pwrclkchanged == SET)
{
__HAL_RCC_PWR_CLK_DISABLE();
}
}
/*------------------------------ HSI48 Configuration -----------------------*/
if(((RCC_OscInitStruct->OscillatorType) & RCC_OSCILLATORTYPE_HSI48) == RCC_OSCILLATORTYPE_HSI48)
{
/* Check the parameters */
assert_param(IS_RCC_HSI48(RCC_OscInitStruct->HSI48State));
/* Check the HSI48 State */
if(RCC_OscInitStruct->HSI48State != RCC_HSI48_OFF)
{
/* Enable the Internal Low Speed oscillator (HSI48). */
__HAL_RCC_HSI48_ENABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI48 is ready */
while(READ_BIT(RCC->CRRCR, RCC_CRRCR_HSI48RDY) == 0U)
{
if((HAL_GetTick() - tickstart) > HSI48_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Disable the Internal Low Speed oscillator (HSI48). */
__HAL_RCC_HSI48_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till HSI48 is disabled */
while(READ_BIT(RCC->CRRCR, RCC_CRRCR_HSI48RDY) != 0U)
{
if((HAL_GetTick() - tickstart) > HSI48_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
}
/*-------------------------------- PLL Configuration -----------------------*/
/* Check the parameters */
assert_param(IS_RCC_PLL(RCC_OscInitStruct->PLL.PLLState));
if (RCC_OscInitStruct->PLL.PLLState != RCC_PLL_NONE)
{
/* Check if the PLL is used as system clock or not */
if (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_PLL)
{
if (RCC_OscInitStruct->PLL.PLLState == RCC_PLL_ON)
{
/* Check the parameters */
assert_param(IS_RCC_PLLSOURCE(RCC_OscInitStruct->PLL.PLLSource));
assert_param(IS_RCC_PLLM_VALUE(RCC_OscInitStruct->PLL.PLLM));
assert_param(IS_RCC_PLLN_VALUE(RCC_OscInitStruct->PLL.PLLN));
assert_param(IS_RCC_PLLP_VALUE(RCC_OscInitStruct->PLL.PLLP));
assert_param(IS_RCC_PLLQ_VALUE(RCC_OscInitStruct->PLL.PLLQ));
assert_param(IS_RCC_PLLR_VALUE(RCC_OscInitStruct->PLL.PLLR));
/* Disable the main PLL. */
__HAL_RCC_PLL_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL is disabled */
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Configure the main PLL clock source, multiplication and division factors. */
__HAL_RCC_PLL_CONFIG(RCC_OscInitStruct->PLL.PLLSource,
RCC_OscInitStruct->PLL.PLLM,
RCC_OscInitStruct->PLL.PLLN,
RCC_OscInitStruct->PLL.PLLP,
RCC_OscInitStruct->PLL.PLLQ,
RCC_OscInitStruct->PLL.PLLR);
/* Enable the main PLL. */
__HAL_RCC_PLL_ENABLE();
/* Enable PLL System Clock output. */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_SYSCLK);
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL is ready */
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY) == 0U)
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
else
{
/* Disable the main PLL. */
__HAL_RCC_PLL_DISABLE();
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till PLL is disabled */
while (READ_BIT(RCC->CR, RCC_CR_PLLRDY) != 0U)
{
if ((HAL_GetTick() - tickstart) > PLL_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
/* Unselect PLL clock source and disable outputs to save power */
RCC->PLLCFGR &= ~(RCC_PLLCFGR_PLLSRC | RCC_PLL_SYSCLK | RCC_PLL_48M1CLK | RCC_PLL_ADCCLK);
}
}
else
{
/* Check if there is a request to disable the PLL used as System clock source */
if((RCC_OscInitStruct->PLL.PLLState) == RCC_PLL_OFF)
{
return HAL_ERROR;
}
else
{
/* Do not return HAL_ERROR if request repeats the current configuration */
temp_pllckcfg = RCC->PLLCFGR;
if((READ_BIT(temp_pllckcfg, RCC_PLLCFGR_PLLSRC) != RCC_OscInitStruct->PLL.PLLSource) ||
(READ_BIT(temp_pllckcfg, RCC_PLLCFGR_PLLM) != (((RCC_OscInitStruct->PLL.PLLM) - 1U) << RCC_PLLCFGR_PLLM_Pos)) ||
(READ_BIT(temp_pllckcfg, RCC_PLLCFGR_PLLN) != ((RCC_OscInitStruct->PLL.PLLN) << RCC_PLLCFGR_PLLN_Pos)) ||
(READ_BIT(temp_pllckcfg, RCC_PLLCFGR_PLLPDIV) != ((RCC_OscInitStruct->PLL.PLLP) << RCC_PLLCFGR_PLLPDIV_Pos)) ||
(READ_BIT(temp_pllckcfg, RCC_PLLCFGR_PLLQ) != ((((RCC_OscInitStruct->PLL.PLLQ) >> 1U) - 1U) << RCC_PLLCFGR_PLLQ_Pos)) ||
(READ_BIT(temp_pllckcfg, RCC_PLLCFGR_PLLR) != ((((RCC_OscInitStruct->PLL.PLLR) >> 1U) - 1U) << RCC_PLLCFGR_PLLR_Pos)))
{
return HAL_ERROR;
}
}
}
}
return HAL_OK;
}
/**
* @brief Initialize the CPU, AHB and APB buses clocks according to the specified
* parameters in the RCC_ClkInitStruct.
* @param RCC_ClkInitStruct pointer to an RCC_OscInitTypeDef structure that
* contains the configuration information for the RCC peripheral.
* @param FLatency FLASH Latency
* This parameter can be one of the following values:
* @arg FLASH_LATENCY_0 FLASH 0 Latency cycle
* @arg FLASH_LATENCY_1 FLASH 1 Latency cycle
* @arg FLASH_LATENCY_2 FLASH 2 Latency cycles
* @arg FLASH_LATENCY_3 FLASH 3 Latency cycles
* @arg FLASH_LATENCY_4 FLASH 4 Latency cycles
* @arg FLASH_LATENCY_5 FLASH 5 Latency cycles
* @arg FLASH_LATENCY_6 FLASH 6 Latency cycles
* @arg FLASH_LATENCY_7 FLASH 7 Latency cycles
* @arg FLASH_LATENCY_8 FLASH 8 Latency cycles
* @arg FLASH_LATENCY_9 FLASH 9 Latency cycles
* @arg FLASH_LATENCY_10 FLASH 10 Latency cycles
* @arg FLASH_LATENCY_11 FLASH 11 Latency cycles
* @arg FLASH_LATENCY_12 FLASH 12 Latency cycles
* @arg FLASH_LATENCY_13 FLASH 13 Latency cycles
* @arg FLASH_LATENCY_14 FLASH 14 Latency cycles
* @arg FLASH_LATENCY_15 FLASH 15 Latency cycles
*
* @note The SystemCoreClock CMSIS variable is used to store System Clock Frequency
* and updated by HAL_RCC_GetHCLKFreq() function called within this function
*
* @note The HSI is used by default as system clock source after
* startup from Reset, wake-up from STANDBY mode. After restart from Reset,
* the HSI frequency is set to its default value 16 MHz.
*
* @note The HSI can be selected as system clock source after
* from STOP modes or in case of failure of the HSE used directly or indirectly
* as system clock (if the Clock Security System CSS is enabled).
*
* @note A switch from one clock source to another occurs only if the target
* clock source is ready (clock stable after startup delay or PLL locked).
* If a clock source which is not yet ready is selected, the switch will
* occur when the clock source is ready.
*
* @note You can use HAL_RCC_GetClockConfig() function to know which clock is
* currently used as system clock source.
*
* @note Depending on the device voltage range, the software has to set correctly
* HPRE[3:0] bits to ensure that HCLK not exceed the maximum allowed frequency
* (for more details refer to section above "Initialization/de-initialization functions")
* @retval None
*/
HAL_StatusTypeDef HAL_RCC_ClockConfig(RCC_ClkInitTypeDef *RCC_ClkInitStruct, uint32_t FLatency)
{
uint32_t tickstart;
uint32_t pllfreq;
uint32_t hpre = RCC_SYSCLK_DIV1;
/* Check Null pointer */
if (RCC_ClkInitStruct == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_RCC_CLOCKTYPE(RCC_ClkInitStruct->ClockType));
assert_param(IS_FLASH_LATENCY(FLatency));
/* To correctly read data from FLASH memory, the number of wait states (LATENCY)
must be correctly programmed according to the frequency of the CPU clock
(HCLK) and the supply voltage of the device. */
/* Increasing the number of wait states because of higher CPU frequency */
if (FLatency > __HAL_FLASH_GET_LATENCY())
{
/* Program the new number of wait states to the LATENCY bits in the FLASH_ACR register */
__HAL_FLASH_SET_LATENCY(FLatency);
/* Check that the new number of wait states is taken into account to access the Flash
memory by reading the FLASH_ACR register */
if (__HAL_FLASH_GET_LATENCY() != FLatency)
{
return HAL_ERROR;
}
}
/*------------------------- SYSCLK Configuration ---------------------------*/
if(((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_SYSCLK) == RCC_CLOCKTYPE_SYSCLK)
{
assert_param(IS_RCC_SYSCLKSOURCE(RCC_ClkInitStruct->SYSCLKSource));
/* PLL is selected as System Clock Source */
if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_PLLCLK)
{
/* Check the PLL ready flag */
if (READ_BIT(RCC->CR, RCC_CR_PLLRDY) == 0U)
{
return HAL_ERROR;
}
/* Undershoot management when selection PLL as SYSCLK source and frequency above 80Mhz */
/* Compute target PLL output frequency */
pllfreq = RCC_GetSysClockFreqFromPLLSource();
/* Intermediate step with HCLK prescaler 2 necessary before to go over 80Mhz */
if(pllfreq > 80000000U)
{
if (((READ_BIT(RCC->CFGR, RCC_CFGR_HPRE) == RCC_SYSCLK_DIV1)) ||
(((((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_HCLK) == RCC_CLOCKTYPE_HCLK) &&
(RCC_ClkInitStruct->AHBCLKDivider == RCC_SYSCLK_DIV1))))
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_SYSCLK_DIV2);
hpre = RCC_SYSCLK_DIV2;
}
}
}
else
{
/* HSE is selected as System Clock Source */
if (RCC_ClkInitStruct->SYSCLKSource == RCC_SYSCLKSOURCE_HSE)
{
/* Check the HSE ready flag */
if(READ_BIT(RCC->CR, RCC_CR_HSERDY) == 0U)
{
return HAL_ERROR;
}
}
/* HSI is selected as System Clock Source */
else
{
/* Check the HSI ready flag */
if(READ_BIT(RCC->CR, RCC_CR_HSIRDY) == 0U)
{
return HAL_ERROR;
}
}
/* Overshoot management when going down from PLL as SYSCLK source and frequency above 80Mhz */
pllfreq = HAL_RCC_GetSysClockFreq();
/* Intermediate step with HCLK prescaler 2 necessary before to go under 80Mhz */
if(pllfreq > 80000000U)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_SYSCLK_DIV2);
hpre = RCC_SYSCLK_DIV2;
}
}
MODIFY_REG(RCC->CFGR, RCC_CFGR_SW, RCC_ClkInitStruct->SYSCLKSource);
/* Get Start Tick*/
tickstart = HAL_GetTick();
while (__HAL_RCC_GET_SYSCLK_SOURCE() != (RCC_ClkInitStruct->SYSCLKSource << RCC_CFGR_SWS_Pos))
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
/*-------------------------- HCLK Configuration --------------------------*/
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_HCLK) == RCC_CLOCKTYPE_HCLK)
{
/* Set the highest APB divider in order to ensure that we do not go through
a non-spec phase whatever we decrease or increase HCLK. */
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_PCLK1) == RCC_CLOCKTYPE_PCLK1)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE1, RCC_HCLK_DIV16);
}
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_PCLK2) == RCC_CLOCKTYPE_PCLK2)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE2, RCC_HCLK_DIV16);
}
/* Set the new HCLK clock divider */
assert_param(IS_RCC_HCLK(RCC_ClkInitStruct->AHBCLKDivider));
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_ClkInitStruct->AHBCLKDivider);
}
else
{
/* Is intermediate HCLK prescaler 2 applied internally, complete with HCLK prescaler 1 */
if(hpre == RCC_SYSCLK_DIV2)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, RCC_SYSCLK_DIV1);
}
}
/* Decreasing the number of wait states because of lower CPU frequency */
if (FLatency < __HAL_FLASH_GET_LATENCY())
{
/* Program the new number of wait states to the LATENCY bits in the FLASH_ACR register */
__HAL_FLASH_SET_LATENCY(FLatency);
/* Check that the new number of wait states is taken into account to access the Flash
memory by polling the FLASH_ACR register */
tickstart = HAL_GetTick();
while (__HAL_FLASH_GET_LATENCY() != FLatency)
{
if ((HAL_GetTick() - tickstart) > CLOCKSWITCH_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
}
/*-------------------------- PCLK1 Configuration ---------------------------*/
if (((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_PCLK1) == RCC_CLOCKTYPE_PCLK1)
{
assert_param(IS_RCC_PCLK(RCC_ClkInitStruct->APB1CLKDivider));
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE1, RCC_ClkInitStruct->APB1CLKDivider);
}
/*-------------------------- PCLK2 Configuration ---------------------------*/
if(((RCC_ClkInitStruct->ClockType) & RCC_CLOCKTYPE_PCLK2) == RCC_CLOCKTYPE_PCLK2)
{
assert_param(IS_RCC_PCLK(RCC_ClkInitStruct->APB2CLKDivider));
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE2, ((RCC_ClkInitStruct->APB2CLKDivider) << 3U));
}
/* Update the SystemCoreClock global variable */
SystemCoreClock = HAL_RCC_GetSysClockFreq() >> (AHBPrescTable[READ_BIT(RCC->CFGR, RCC_CFGR_HPRE) >> RCC_CFGR_HPRE_Pos] & 0x1FU);
/* Configure the source of time base considering new system clocks settings*/
return HAL_InitTick(uwTickPrio);
}
/**
* @}
*/
/** @defgroup RCC_Exported_Functions_Group2 Peripheral Control functions
* @brief RCC clocks control functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to:
(+) Output clock to MCO pin.
(+) Retrieve current clock frequencies.
(+) Enable the Clock Security System.
@endverbatim
* @{
*/
/**
* @brief Select the clock source to output on MCO pin(PA8/PG10).
* @note PA8/PG10 should be configured in alternate function mode.
* @note The default configuration of the GPIOG pin 10 (PG10) is set to reset mode (NRST pin)
* and user shall set the NRST_MODE Bit in the FLASH OPTR register to be able to use it
* as an MCO pin.
* The @ref HAL_FLASHEx_OBProgram() API can be used to configure the NRST_MODE Bit value.
* @param RCC_MCOx specifies the output direction for the clock source.
* For STM32G4xx family this parameter can have only one value:
* @arg @ref RCC_MCO_PA8 Clock source to output on MCO1 pin(PA8).
* @arg @ref RCC_MCO_PG10 Clock source to output on MCO1 pin(PG10).
* @param RCC_MCOSource specifies the clock source to output.
* This parameter can be one of the following values:
* @arg @ref RCC_MCO1SOURCE_NOCLOCK MCO output disabled, no clock on MCO
* @arg @ref RCC_MCO1SOURCE_SYSCLK system clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSI HSI clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSE HSE clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_PLLCLK main PLL clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_LSI LSI clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_LSE LSE clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSI48 HSI48 clock selected as MCO source for devices with HSI48
* @param RCC_MCODiv specifies the MCO prescaler.
* This parameter can be one of the following values:
* @arg @ref RCC_MCODIV_1 no division applied to MCO clock
* @arg @ref RCC_MCODIV_2 division by 2 applied to MCO clock
* @arg @ref RCC_MCODIV_4 division by 4 applied to MCO clock
* @arg @ref RCC_MCODIV_8 division by 8 applied to MCO clock
* @arg @ref RCC_MCODIV_16 division by 16 applied to MCO clock
* @retval None
*/
void HAL_RCC_MCOConfig(uint32_t RCC_MCOx, uint32_t RCC_MCOSource, uint32_t RCC_MCODiv)
{
GPIO_InitTypeDef gpio_initstruct;
uint32_t mcoindex;
uint32_t mco_gpio_index;
GPIO_TypeDef * mco_gpio_port;
/* Check the parameters */
assert_param(IS_RCC_MCO(RCC_MCOx));
/* Common GPIO init parameters */
gpio_initstruct.Mode = GPIO_MODE_AF_PP;
gpio_initstruct.Speed = GPIO_SPEED_FREQ_VERY_HIGH;
gpio_initstruct.Pull = GPIO_NOPULL;
/* Get MCOx selection */
mcoindex = RCC_MCOx & RCC_MCO_INDEX_MASK;
/* Get MCOx GPIO Port */
mco_gpio_port = (GPIO_TypeDef *) RCC_GET_MCO_GPIO_PORT(RCC_MCOx);
/* MCOx Clock Enable */
mco_gpio_index = RCC_GET_MCO_GPIO_INDEX(RCC_MCOx);
SET_BIT(RCC->AHB2ENR, (1UL << mco_gpio_index ));
/* Configure the MCOx pin in alternate function mode */
gpio_initstruct.Pin = RCC_GET_MCO_GPIO_PIN(RCC_MCOx);
gpio_initstruct.Alternate = RCC_GET_MCO_GPIO_AF(RCC_MCOx);
HAL_GPIO_Init(mco_gpio_port, &gpio_initstruct);
if (mcoindex == RCC_MCO1_INDEX)
{
assert_param(IS_RCC_MCODIV(RCC_MCODiv));
assert_param(IS_RCC_MCO1SOURCE(RCC_MCOSource));
/* Mask MCOSEL[] and MCOPRE[] bits then set MCO clock source and prescaler */
MODIFY_REG(RCC->CFGR, (RCC_CFGR_MCOSEL | RCC_CFGR_MCOPRE), (RCC_MCOSource | RCC_MCODiv));
}
}
/**
* @brief Return the SYSCLK frequency.
*
* @note The system frequency computed by this function is not the real
* frequency in the chip. It is calculated based on the predefined
* constant and the selected clock source:
* @note If SYSCLK source is HSI, function returns values based on HSI_VALUE(*)
* @note If SYSCLK source is HSE, function returns values based on HSE_VALUE(**)
* @note If SYSCLK source is PLL, function returns values based on HSE_VALUE(**),
* HSI_VALUE(*) Value multiplied/divided by the PLL factors.
* @note (*) HSI_VALUE is a constant defined in stm32g4xx_hal_conf.h file (default value
* 16 MHz) but the real value may vary depending on the variations
* in voltage and temperature.
* @note (**) HSE_VALUE is a constant defined in stm32g4xx_hal_conf.h file (default value
* 8 MHz), user has to ensure that HSE_VALUE is same as the real
* frequency of the crystal used. Otherwise, this function may
* have wrong result.
*
* @note The result of this function could be not correct when using fractional
* value for HSE crystal.
*
* @note This function can be used by the user application to compute the
* baudrate for the communication peripherals or configure other parameters.
*
* @note Each time SYSCLK changes, this function must be called to update the
* right SYSCLK value. Otherwise, any configuration based on this function will be incorrect.
*
*
* @retval SYSCLK frequency
*/
uint32_t HAL_RCC_GetSysClockFreq(void)
{
uint32_t pllvco, pllsource, pllr, pllm;
uint32_t sysclockfreq;
if (__HAL_RCC_GET_SYSCLK_SOURCE() == RCC_CFGR_SWS_HSI)
{
/* HSI used as system clock source */
sysclockfreq = HSI_VALUE;
}
else if (__HAL_RCC_GET_SYSCLK_SOURCE() == RCC_CFGR_SWS_HSE)
{
/* HSE used as system clock source */
sysclockfreq = HSE_VALUE;
}
else if (__HAL_RCC_GET_SYSCLK_SOURCE() == RCC_CFGR_SWS_PLL)
{
/* PLL used as system clock source */
/* PLL_VCO = ((HSE_VALUE or HSI_VALUE)/ PLLM) * PLLN
SYSCLK = PLL_VCO / PLLR
*/
pllsource = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC);
pllm = (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLM) >> RCC_PLLCFGR_PLLM_Pos) + 1U ;
switch (pllsource)
{
case RCC_PLLSOURCE_HSE: /* HSE used as PLL clock source */
pllvco = (HSE_VALUE / pllm) * (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
case RCC_PLLSOURCE_HSI: /* HSI used as PLL clock source */
default:
pllvco = (HSI_VALUE / pllm) * (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
}
pllr = ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLR) >> RCC_PLLCFGR_PLLR_Pos) + 1U ) * 2U;
sysclockfreq = pllvco/pllr;
}
else
{
sysclockfreq = 0U;
}
return sysclockfreq;
}
/**
* @brief Return the HCLK frequency.
* @note Each time HCLK changes, this function must be called to update the
* right HCLK value. Otherwise, any configuration based on this function will be incorrect.
*
* @note The SystemCoreClock CMSIS variable is used to store System Clock Frequency.
* @retval HCLK frequency in Hz
*/
uint32_t HAL_RCC_GetHCLKFreq(void)
{
return SystemCoreClock;
}
/**
* @brief Return the PCLK1 frequency.
* @note Each time PCLK1 changes, this function must be called to update the
* right PCLK1 value. Otherwise, any configuration based on this function will be incorrect.
* @retval PCLK1 frequency in Hz
*/
uint32_t HAL_RCC_GetPCLK1Freq(void)
{
/* Get HCLK source and Compute PCLK1 frequency ---------------------------*/
return (HAL_RCC_GetHCLKFreq() >> (APBPrescTable[READ_BIT(RCC->CFGR, RCC_CFGR_PPRE1) >> RCC_CFGR_PPRE1_Pos] & 0x1FU));
}
/**
* @brief Return the PCLK2 frequency.
* @note Each time PCLK2 changes, this function must be called to update the
* right PCLK2 value. Otherwise, any configuration based on this function will be incorrect.
* @retval PCLK2 frequency in Hz
*/
uint32_t HAL_RCC_GetPCLK2Freq(void)
{
/* Get HCLK source and Compute PCLK2 frequency ---------------------------*/
return (HAL_RCC_GetHCLKFreq()>> (APBPrescTable[READ_BIT(RCC->CFGR, RCC_CFGR_PPRE2) >> RCC_CFGR_PPRE2_Pos] & 0x1FU));
}
/**
* @brief Configure the RCC_OscInitStruct according to the internal
* RCC configuration registers.
* @param RCC_OscInitStruct pointer to an RCC_OscInitTypeDef structure that
* will be configured.
* @retval None
*/
void HAL_RCC_GetOscConfig(RCC_OscInitTypeDef *RCC_OscInitStruct)
{
/* Check the parameters */
assert_param(RCC_OscInitStruct != (void *)NULL);
/* Set all possible values for the Oscillator type parameter ---------------*/
RCC_OscInitStruct->OscillatorType = RCC_OSCILLATORTYPE_HSE | RCC_OSCILLATORTYPE_HSI | \
RCC_OSCILLATORTYPE_LSE | RCC_OSCILLATORTYPE_LSI | RCC_OSCILLATORTYPE_HSI48;
/* Get the HSE configuration -----------------------------------------------*/
if(READ_BIT(RCC->CR, RCC_CR_HSEBYP) == RCC_CR_HSEBYP)
{
RCC_OscInitStruct->HSEState = RCC_HSE_BYPASS;
}
else if(READ_BIT(RCC->CR, RCC_CR_HSEON) == RCC_CR_HSEON)
{
RCC_OscInitStruct->HSEState = RCC_HSE_ON;
}
else
{
RCC_OscInitStruct->HSEState = RCC_HSE_OFF;
}
/* Get the HSI configuration -----------------------------------------------*/
if(READ_BIT(RCC->CR, RCC_CR_HSION) == RCC_CR_HSION)
{
RCC_OscInitStruct->HSIState = RCC_HSI_ON;
}
else
{
RCC_OscInitStruct->HSIState = RCC_HSI_OFF;
}
RCC_OscInitStruct->HSICalibrationValue = READ_BIT(RCC->ICSCR, RCC_ICSCR_HSITRIM) >> RCC_ICSCR_HSITRIM_Pos;
/* Get the LSE configuration -----------------------------------------------*/
if(READ_BIT(RCC->BDCR, RCC_BDCR_LSEBYP) == RCC_BDCR_LSEBYP)
{
RCC_OscInitStruct->LSEState = RCC_LSE_BYPASS;
}
else if(READ_BIT(RCC->BDCR, RCC_BDCR_LSEON) == RCC_BDCR_LSEON)
{
RCC_OscInitStruct->LSEState = RCC_LSE_ON;
}
else
{
RCC_OscInitStruct->LSEState = RCC_LSE_OFF;
}
/* Get the LSI configuration -----------------------------------------------*/
if(READ_BIT(RCC->CSR, RCC_CSR_LSION) == RCC_CSR_LSION)
{
RCC_OscInitStruct->LSIState = RCC_LSI_ON;
}
else
{
RCC_OscInitStruct->LSIState = RCC_LSI_OFF;
}
/* Get the HSI48 configuration ---------------------------------------------*/
if(READ_BIT(RCC->CRRCR, RCC_CRRCR_HSI48ON) == RCC_CRRCR_HSI48ON)
{
RCC_OscInitStruct->HSI48State = RCC_HSI48_ON;
}
else
{
RCC_OscInitStruct->HSI48State = RCC_HSI48_OFF;
}
/* Get the PLL configuration -----------------------------------------------*/
if(READ_BIT(RCC->CR, RCC_CR_PLLON) == RCC_CR_PLLON)
{
RCC_OscInitStruct->PLL.PLLState = RCC_PLL_ON;
}
else
{
RCC_OscInitStruct->PLL.PLLState = RCC_PLL_OFF;
}
RCC_OscInitStruct->PLL.PLLSource = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC);
RCC_OscInitStruct->PLL.PLLM = (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLM) >> RCC_PLLCFGR_PLLM_Pos) + 1U;
RCC_OscInitStruct->PLL.PLLN = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
RCC_OscInitStruct->PLL.PLLQ = (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
RCC_OscInitStruct->PLL.PLLR = (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLR) >> RCC_PLLCFGR_PLLR_Pos) + 1U) << 1U);
RCC_OscInitStruct->PLL.PLLP = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPDIV) >> RCC_PLLCFGR_PLLPDIV_Pos;
}
/**
* @brief Configure the RCC_ClkInitStruct according to the internal
* RCC configuration registers.
* @param RCC_ClkInitStruct pointer to an RCC_ClkInitTypeDef structure that
* will be configured.
* @param pFLatency Pointer on the Flash Latency.
* @retval None
*/
void HAL_RCC_GetClockConfig(RCC_ClkInitTypeDef *RCC_ClkInitStruct, uint32_t *pFLatency)
{
/* Check the parameters */
assert_param(RCC_ClkInitStruct != (void *)NULL);
assert_param(pFLatency != (void *)NULL);
/* Set all possible values for the Clock type parameter --------------------*/
RCC_ClkInitStruct->ClockType = RCC_CLOCKTYPE_SYSCLK | RCC_CLOCKTYPE_HCLK | RCC_CLOCKTYPE_PCLK1 | RCC_CLOCKTYPE_PCLK2;
/* Get the SYSCLK configuration --------------------------------------------*/
RCC_ClkInitStruct->SYSCLKSource = READ_BIT(RCC->CFGR, RCC_CFGR_SW);
/* Get the HCLK configuration ----------------------------------------------*/
RCC_ClkInitStruct->AHBCLKDivider = READ_BIT(RCC->CFGR, RCC_CFGR_HPRE);
/* Get the APB1 configuration ----------------------------------------------*/
RCC_ClkInitStruct->APB1CLKDivider = READ_BIT(RCC->CFGR, RCC_CFGR_PPRE1);
/* Get the APB2 configuration ----------------------------------------------*/
RCC_ClkInitStruct->APB2CLKDivider = (READ_BIT(RCC->CFGR, RCC_CFGR_PPRE2) >> 3U);
/* Get the Flash Wait State (Latency) configuration ------------------------*/
*pFLatency = __HAL_FLASH_GET_LATENCY();
}
/**
* @brief Enable the Clock Security System.
* @note If a failure is detected on the HSE oscillator clock, this oscillator
* is automatically disabled and an interrupt is generated to inform the
* software about the failure (Clock Security System Interrupt, CSSI),
* allowing the MCU to perform rescue operations. The CSSI is linked to
* the Cortex-M4 NMI (Non-Maskable Interrupt) exception vector.
* @note The Clock Security System can only be cleared by reset.
* @retval None
*/
void HAL_RCC_EnableCSS(void)
{
SET_BIT(RCC->CR, RCC_CR_CSSON) ;
}
/**
* @brief Enable the LSE Clock Security System.
* @note If a failure is detected on the external 32 kHz oscillator,
* the LSE clock is no longer supplied to the RTC but no hardware action
* is made to the registers. If enabled, an interrupt will be generated
* and handle through @ref RCCEx_EXTI_LINE_LSECSS
* @note The Clock Security System can only be cleared by reset or after a LSE failure detection.
* @retval None
*/
void HAL_RCC_EnableLSECSS(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_LSECSSON) ;
}
/**
* @brief Disable the LSE Clock Security System.
* @note After LSE failure detection, the software must disable LSECSSON
* @note The Clock Security System can only be cleared by reset otherwise.
* @retval None
*/
void HAL_RCC_DisableLSECSS(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSECSSON) ;
}
/**
* @brief Handle the RCC Clock Security System interrupt request.
* @note This API should be called under the NMI_Handler().
* @retval None
*/
void HAL_RCC_NMI_IRQHandler(void)
{
/* Check RCC CSSF interrupt flag */
if(__HAL_RCC_GET_IT(RCC_IT_CSS))
{
/* RCC Clock Security System interrupt user callback */
HAL_RCC_CSSCallback();
/* Clear RCC CSS pending bit */
__HAL_RCC_CLEAR_IT(RCC_IT_CSS);
}
}
/**
* @brief RCC Clock Security System interrupt callback.
* @retval none
*/
__weak void HAL_RCC_CSSCallback(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_RCC_CSSCallback should be implemented in the user file
*/
}
/**
* @}
*/
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/** @addtogroup RCC_Private_Functions
* @{
*/
/**
* @brief Compute SYSCLK frequency based on PLL SYSCLK source.
* @retval SYSCLK frequency
*/
static uint32_t RCC_GetSysClockFreqFromPLLSource(void)
{
uint32_t pllvco, pllsource, pllr, pllm;
uint32_t sysclockfreq;
/* PLL_VCO = (HSE_VALUE or HSI_VALUE/ PLLM) * PLLN
SYSCLK = PLL_VCO / PLLR
*/
pllsource = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC);
pllm = (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLM) >> RCC_PLLCFGR_PLLM_Pos) + 1U ;
switch (pllsource)
{
case RCC_PLLSOURCE_HSE: /* HSE used as PLL clock source */
pllvco = (HSE_VALUE / pllm) * (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
case RCC_PLLSOURCE_HSI: /* HSI used as PLL clock source */
default:
pllvco = (HSI_VALUE / pllm) * (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
break;
}
pllr = ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLR) >> RCC_PLLCFGR_PLLR_Pos) + 1U ) * 2U;
sysclockfreq = pllvco/pllr;
return sysclockfreq;
}
/**
* @}
*/
#endif /* HAL_RCC_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 51,106 | C | 35.478944 | 130 | 0.583963 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_dma_ex.c | /**
******************************************************************************
* @file stm32g4xx_hal_dma_ex.c
* @author MCD Application Team
* @brief DMA Extension HAL module driver
* This file provides firmware functions to manage the following
* functionalities of the DMA Extension peripheral:
* + Extended features functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
The DMA Extension HAL driver can be used as follows:
(+) Configure the DMA_MUX Synchronization Block using HAL_DMAEx_ConfigMuxSync function.
(+) Configure the DMA_MUX Request Generator Block using HAL_DMAEx_ConfigMuxRequestGenerator function.
Functions HAL_DMAEx_EnableMuxRequestGenerator and HAL_DMAEx_DisableMuxRequestGenerator can then be used
to respectively enable/disable the request generator.
(+) To handle the DMAMUX Interrupts, the function HAL_DMAEx_MUX_IRQHandler should be called from
the DMAMUX IRQ handler i.e DMAMUX1_OVR_IRQHandler.
As only one interrupt line is available for all DMAMUX channels and request generators , HAL_DMAEx_MUX_IRQHandler should be
called with, as parameter, the appropriate DMA handle as many as used DMAs in the user project
(exception done if a given DMA is not using the DMAMUX SYNC block neither a request generator)
@endverbatim
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup DMAEx DMAEx
* @brief DMA Extended HAL module driver
* @{
*/
#ifdef HAL_DMA_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private Constants ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Private functions ---------------------------------------------------------*/
/** @defgroup DMAEx_Exported_Functions DMAEx Exported Functions
* @{
*/
/** @defgroup DMAEx_Exported_Functions_Group1 DMAEx Extended features functions
* @brief Extended features functions
*
@verbatim
===============================================================================
##### Extended features functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Configure the DMAMUX Synchronization Block using HAL_DMAEx_ConfigMuxSync function.
(+) Configure the DMAMUX Request Generator Block using HAL_DMAEx_ConfigMuxRequestGenerator function.
Functions HAL_DMAEx_EnableMuxRequestGenerator and HAL_DMAEx_DisableMuxRequestGenerator can then be used
to respectively enable/disable the request generator.
@endverbatim
* @{
*/
/**
* @brief Configure the DMAMUX synchronization parameters for a given DMA channel (instance).
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA channel.
* @param pSyncConfig : pointer to HAL_DMA_MuxSyncConfigTypeDef : contains the DMAMUX synchronization parameters
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMAEx_ConfigMuxSync(DMA_HandleTypeDef *hdma, HAL_DMA_MuxSyncConfigTypeDef *pSyncConfig)
{
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
assert_param(IS_DMAMUX_SYNC_SIGNAL_ID(pSyncConfig->SyncSignalID));
assert_param(IS_DMAMUX_SYNC_POLARITY(pSyncConfig-> SyncPolarity));
assert_param(IS_DMAMUX_SYNC_STATE(pSyncConfig->SyncEnable));
assert_param(IS_DMAMUX_SYNC_EVENT(pSyncConfig->EventEnable));
assert_param(IS_DMAMUX_SYNC_REQUEST_NUMBER(pSyncConfig->RequestNumber));
/*Check if the DMA state is ready */
if (hdma->State == HAL_DMA_STATE_READY)
{
/* Process Locked */
__HAL_LOCK(hdma);
/* Set the new synchronization parameters (and keep the request ID filled during the Init)*/
MODIFY_REG(hdma->DMAmuxChannel->CCR, \
(~DMAMUX_CxCR_DMAREQ_ID), \
((pSyncConfig->SyncSignalID) << DMAMUX_CxCR_SYNC_ID_Pos) | ((pSyncConfig->RequestNumber - 1U) << DMAMUX_CxCR_NBREQ_Pos) | \
pSyncConfig->SyncPolarity | ((uint32_t)pSyncConfig->SyncEnable << DMAMUX_CxCR_SE_Pos) | \
((uint32_t)pSyncConfig->EventEnable << DMAMUX_CxCR_EGE_Pos));
/* Process UnLocked */
__HAL_UNLOCK(hdma);
return HAL_OK;
}
else
{
/*DMA State not Ready*/
return HAL_ERROR;
}
}
/**
* @brief Configure the DMAMUX request generator block used by the given DMA channel (instance).
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA channel.
* @param pRequestGeneratorConfig : pointer to HAL_DMA_MuxRequestGeneratorConfigTypeDef :
* contains the request generator parameters.
*
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMAEx_ConfigMuxRequestGenerator(DMA_HandleTypeDef *hdma,
HAL_DMA_MuxRequestGeneratorConfigTypeDef *pRequestGeneratorConfig)
{
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
assert_param(IS_DMAMUX_REQUEST_GEN_SIGNAL_ID(pRequestGeneratorConfig->SignalID));
assert_param(IS_DMAMUX_REQUEST_GEN_POLARITY(pRequestGeneratorConfig->Polarity));
assert_param(IS_DMAMUX_REQUEST_GEN_REQUEST_NUMBER(pRequestGeneratorConfig->RequestNumber));
/* check if the DMA state is ready
and DMA is using a DMAMUX request generator block
*/
if ((hdma->State == HAL_DMA_STATE_READY) && (hdma->DMAmuxRequestGen != 0U))
{
/* Process Locked */
__HAL_LOCK(hdma);
/* Set the request generator new parameters */
hdma->DMAmuxRequestGen->RGCR = pRequestGeneratorConfig->SignalID | \
((pRequestGeneratorConfig->RequestNumber - 1U) << (POSITION_VAL(DMAMUX_RGxCR_GNBREQ) & 0x1FU)) | \
pRequestGeneratorConfig->Polarity;
/* Process UnLocked */
__HAL_UNLOCK(hdma);
return HAL_OK;
}
else
{
return HAL_ERROR;
}
}
/**
* @brief Enable the DMAMUX request generator block used by the given DMA channel (instance).
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMAEx_EnableMuxRequestGenerator(DMA_HandleTypeDef *hdma)
{
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
/* check if the DMA state is ready
and DMA is using a DMAMUX request generator block
*/
if ((hdma->State != HAL_DMA_STATE_RESET) && (hdma->DMAmuxRequestGen != 0))
{
/* Enable the request generator*/
hdma->DMAmuxRequestGen->RGCR |= DMAMUX_RGxCR_GE;
return HAL_OK;
}
else
{
return HAL_ERROR;
}
}
/**
* @brief Disable the DMAMUX request generator block used by the given DMA channel (instance).
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA channel.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DMAEx_DisableMuxRequestGenerator(DMA_HandleTypeDef *hdma)
{
/* Check the parameters */
assert_param(IS_DMA_ALL_INSTANCE(hdma->Instance));
/* check if the DMA state is ready
and DMA is using a DMAMUX request generator block
*/
if ((hdma->State != HAL_DMA_STATE_RESET) && (hdma->DMAmuxRequestGen != 0))
{
/* Disable the request generator*/
hdma->DMAmuxRequestGen->RGCR &= ~DMAMUX_RGxCR_GE;
return HAL_OK;
}
else
{
return HAL_ERROR;
}
}
/**
* @brief Handles DMAMUX interrupt request.
* @param hdma: pointer to a DMA_HandleTypeDef structure that contains
* the configuration information for the specified DMA channel.
* @retval None
*/
void HAL_DMAEx_MUX_IRQHandler(DMA_HandleTypeDef *hdma)
{
/* Check for DMAMUX Synchronization overrun */
if ((hdma->DMAmuxChannelStatus->CSR & hdma->DMAmuxChannelStatusMask) != 0U)
{
/* Disable the synchro overrun interrupt */
hdma->DMAmuxChannel->CCR &= ~DMAMUX_CxCR_SOIE;
/* Clear the DMAMUX synchro overrun flag */
hdma->DMAmuxChannelStatus->CFR = hdma->DMAmuxChannelStatusMask;
/* Update error code */
hdma->ErrorCode |= HAL_DMA_ERROR_SYNC;
if (hdma->XferErrorCallback != NULL)
{
/* Transfer error callback */
hdma->XferErrorCallback(hdma);
}
}
if (hdma->DMAmuxRequestGen != 0)
{
/* if using a DMAMUX request generator block Check for DMAMUX request generator overrun */
if ((hdma->DMAmuxRequestGenStatus->RGSR & hdma->DMAmuxRequestGenStatusMask) != 0U)
{
/* Disable the request gen overrun interrupt */
hdma->DMAmuxRequestGen->RGCR &= ~DMAMUX_RGxCR_OIE;
/* Clear the DMAMUX request generator overrun flag */
hdma->DMAmuxRequestGenStatus->RGCFR = hdma->DMAmuxRequestGenStatusMask;
/* Update error code */
hdma->ErrorCode |= HAL_DMA_ERROR_REQGEN;
if (hdma->XferErrorCallback != NULL)
{
/* Transfer error callback */
hdma->XferErrorCallback(hdma);
}
}
}
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_DMA_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 10,365 | C | 33.668896 | 138 | 0.606753 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_exti.c | /**
******************************************************************************
* @file stm32g4xx_hal_exti.c
* @author MCD Application Team
* @brief EXTI HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Extended Interrupts and events controller (EXTI) peripheral:
* functionalities of the General Purpose Input/Output (EXTI) peripheral:
* + Initialization and de-initialization functions
* + IO operation functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### EXTI Peripheral features #####
==============================================================================
[..]
(+) Each Exti line can be configured within this driver.
(+) Exti line can be configured in 3 different modes
(++) Interrupt
(++) Event
(++) Both of them
(+) Configurable Exti lines can be configured with 3 different triggers
(++) Rising
(++) Falling
(++) Both of them
(+) When set in interrupt mode, configurable Exti lines have two different
interrupt pending registers which allow to distinguish which transition
occurs:
(++) Rising edge pending interrupt
(++) Falling
(+) Exti lines 0 to 15 are linked to gpio pin number 0 to 15. Gpio port can
be selected through multiplexer.
##### How to use this driver #####
==============================================================================
[..]
(#) Configure the EXTI line using HAL_EXTI_SetConfigLine().
(++) Choose the interrupt line number by setting "Line" member from
EXTI_ConfigTypeDef structure.
(++) Configure the interrupt and/or event mode using "Mode" member from
EXTI_ConfigTypeDef structure.
(++) For configurable lines, configure rising and/or falling trigger
"Trigger" member from EXTI_ConfigTypeDef structure.
(++) For Exti lines linked to gpio, choose gpio port using "GPIOSel"
member from GPIO_InitTypeDef structure.
(#) Get current Exti configuration of a dedicated line using
HAL_EXTI_GetConfigLine().
(++) Provide exiting handle as parameter.
(++) Provide pointer on EXTI_ConfigTypeDef structure as second parameter.
(#) Clear Exti configuration of a dedicated line using HAL_EXTI_ClearConfigLine().
(++) Provide exiting handle as parameter.
(#) Register callback to treat Exti interrupts using HAL_EXTI_RegisterCallback().
(++) Provide exiting handle as first parameter.
(++) Provide which callback will be registered using one value from
EXTI_CallbackIDTypeDef.
(++) Provide callback function pointer.
(#) Get interrupt pending bit using HAL_EXTI_GetPending().
(#) Clear interrupt pending bit using HAL_EXTI_ClearPending().
(#) Generate software interrupt using HAL_EXTI_GenerateSWI().
@endverbatim
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup EXTI
* @{
*/
/** MISRA C:2012 deviation rule has been granted for following rule:
* Rule-18.1_b - Medium: Array `EXTICR' 1st subscript interval [0,7] may be out
* of bounds [0,3] in following API :
* HAL_EXTI_SetConfigLine
* HAL_EXTI_GetConfigLine
* HAL_EXTI_ClearConfigLine
*/
#ifdef HAL_EXTI_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private defines ------------------------------------------------------------*/
/** @defgroup EXTI_Private_Constants EXTI Private Constants
* @{
*/
#define EXTI_MODE_OFFSET 0x08U /* 0x20: offset between MCU IMR/EMR registers */
#define EXTI_CONFIG_OFFSET 0x08U /* 0x20: offset between MCU Rising/Falling configuration registers */
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup EXTI_Exported_Functions
* @{
*/
/** @addtogroup EXTI_Exported_Functions_Group1
* @brief Configuration functions
*
@verbatim
===============================================================================
##### Configuration functions #####
===============================================================================
@endverbatim
* @{
*/
/**
* @brief Set configuration of a dedicated Exti line.
* @param hexti Exti handle.
* @param pExtiConfig Pointer on EXTI configuration to be set.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_SetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig)
{
__IO uint32_t *regaddr;
uint32_t regval;
uint32_t linepos;
uint32_t maskline;
uint32_t offset;
/* Check null pointer */
if ((hexti == NULL) || (pExtiConfig == NULL))
{
return HAL_ERROR;
}
/* Check parameters */
assert_param(IS_EXTI_LINE(pExtiConfig->Line));
assert_param(IS_EXTI_MODE(pExtiConfig->Mode));
/* Assign line number to handle */
hexti->Line = pExtiConfig->Line;
/* Compute line register offset */
offset = ((pExtiConfig->Line & EXTI_REG_MASK) >> EXTI_REG_SHIFT);
/* Compute line position */
linepos = (pExtiConfig->Line & EXTI_PIN_MASK);
/* Compute line mask */
maskline = (1uL << linepos);
/* Configure triggers for configurable lines */
if ((pExtiConfig->Line & EXTI_CONFIG) != 0x00u)
{
assert_param(IS_EXTI_TRIGGER(pExtiConfig->Trigger));
/* Configure rising trigger */
regaddr = (&EXTI->RTSR1 + (EXTI_CONFIG_OFFSET * offset));
regval = *regaddr;
/* Mask or set line */
if ((pExtiConfig->Trigger & EXTI_TRIGGER_RISING) != 0x00u)
{
regval |= maskline;
}
else
{
regval &= ~maskline;
}
/* Store rising trigger mode */
*regaddr = regval;
/* Configure falling trigger */
regaddr = (&EXTI->FTSR1 + (EXTI_CONFIG_OFFSET * offset));
regval = *regaddr;
/* Mask or set line */
if ((pExtiConfig->Trigger & EXTI_TRIGGER_FALLING) != 0x00u)
{
regval |= maskline;
}
else
{
regval &= ~maskline;
}
/* Store falling trigger mode */
*regaddr = regval;
/* Configure gpio port selection in case of gpio exti line */
if ((pExtiConfig->Line & EXTI_GPIO) == EXTI_GPIO)
{
assert_param(IS_EXTI_GPIO_PORT(pExtiConfig->GPIOSel));
assert_param(IS_EXTI_GPIO_PIN(linepos));
regval = SYSCFG->EXTICR[linepos >> 2u];
regval &= ~(SYSCFG_EXTICR1_EXTI0 << (SYSCFG_EXTICR1_EXTI1_Pos * (linepos & 0x03u)));
regval |= (pExtiConfig->GPIOSel << (SYSCFG_EXTICR1_EXTI1_Pos * (linepos & 0x03u)));
SYSCFG->EXTICR[linepos >> 2u] = regval;
}
}
/* Configure interrupt mode : read current mode */
regaddr = (&EXTI->IMR1 + (EXTI_MODE_OFFSET * offset));
regval = *regaddr;
/* Mask or set line */
if ((pExtiConfig->Mode & EXTI_MODE_INTERRUPT) != 0x00u)
{
regval |= maskline;
}
else
{
regval &= ~maskline;
}
/* Store interrupt mode */
*regaddr = regval;
/* Configure event mode : read current mode */
regaddr = (&EXTI->EMR1 + (EXTI_MODE_OFFSET * offset));
regval = *regaddr;
/* Mask or set line */
if ((pExtiConfig->Mode & EXTI_MODE_EVENT) != 0x00u)
{
regval |= maskline;
}
else
{
regval &= ~maskline;
}
/* Store event mode */
*regaddr = regval;
return HAL_OK;
}
/**
* @brief Get configuration of a dedicated Exti line.
* @param hexti Exti handle.
* @param pExtiConfig Pointer on structure to store Exti configuration.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_GetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig)
{
__IO uint32_t *regaddr;
uint32_t regval;
uint32_t linepos;
uint32_t maskline;
uint32_t offset;
/* Check null pointer */
if ((hexti == NULL) || (pExtiConfig == NULL))
{
return HAL_ERROR;
}
/* Check the parameter */
assert_param(IS_EXTI_LINE(hexti->Line));
/* Store handle line number to configuration structure */
pExtiConfig->Line = hexti->Line;
/* Compute line register offset and line mask */
offset = ((pExtiConfig->Line & EXTI_REG_MASK) >> EXTI_REG_SHIFT);
/* Compute line position */
linepos = (pExtiConfig->Line & EXTI_PIN_MASK);
/* Compute mask */
maskline = (1uL << linepos);
/* 1] Get core mode : interrupt */
regaddr = (&EXTI->IMR1 + (EXTI_MODE_OFFSET * offset));
regval = *regaddr;
/* Check if selected line is enable */
if ((regval & maskline) != 0x00u)
{
pExtiConfig->Mode = EXTI_MODE_INTERRUPT;
}
else
{
pExtiConfig->Mode = EXTI_MODE_NONE;
}
/* Get event mode */
regaddr = (&EXTI->EMR1 + (EXTI_MODE_OFFSET * offset));
regval = *regaddr;
/* Check if selected line is enable */
if ((regval & maskline) != 0x00u)
{
pExtiConfig->Mode |= EXTI_MODE_EVENT;
}
/* Get default Trigger and GPIOSel configuration */
pExtiConfig->Trigger = EXTI_TRIGGER_NONE;
pExtiConfig->GPIOSel = 0x00u;
/* 2] Get trigger for configurable lines : rising */
if ((pExtiConfig->Line & EXTI_CONFIG) != 0x00u)
{
regaddr = (&EXTI->RTSR1 + (EXTI_CONFIG_OFFSET * offset));
regval = *regaddr;
/* Check if configuration of selected line is enable */
if ((regval & maskline) != 0x00u)
{
pExtiConfig->Trigger = EXTI_TRIGGER_RISING;
}
/* Get falling configuration */
regaddr = (&EXTI->FTSR1 + (EXTI_CONFIG_OFFSET * offset));
regval = *regaddr;
/* Check if configuration of selected line is enable */
if ((regval & maskline) != 0x00u)
{
pExtiConfig->Trigger |= EXTI_TRIGGER_FALLING;
}
/* Get Gpio port selection for gpio lines */
if ((pExtiConfig->Line & EXTI_GPIO) == EXTI_GPIO)
{
assert_param(IS_EXTI_GPIO_PIN(linepos));
regval = SYSCFG->EXTICR[linepos >> 2u];
pExtiConfig->GPIOSel = (regval >> (SYSCFG_EXTICR1_EXTI1_Pos * (linepos & 0x03u))) & SYSCFG_EXTICR1_EXTI0;
}
}
return HAL_OK;
}
/**
* @brief Clear whole configuration of a dedicated Exti line.
* @param hexti Exti handle.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_ClearConfigLine(EXTI_HandleTypeDef *hexti)
{
__IO uint32_t *regaddr;
uint32_t regval;
uint32_t linepos;
uint32_t maskline;
uint32_t offset;
/* Check null pointer */
if (hexti == NULL)
{
return HAL_ERROR;
}
/* Check the parameter */
assert_param(IS_EXTI_LINE(hexti->Line));
/* compute line register offset and line mask */
offset = ((hexti->Line & EXTI_REG_MASK) >> EXTI_REG_SHIFT);
/* compute line position */
linepos = (hexti->Line & EXTI_PIN_MASK);
/* compute line mask */
maskline = (1uL << linepos);
/* 1] Clear interrupt mode */
regaddr = (&EXTI->IMR1 + (EXTI_MODE_OFFSET * offset));
regval = (*regaddr & ~maskline);
*regaddr = regval;
/* 2] Clear event mode */
regaddr = (&EXTI->EMR1 + (EXTI_MODE_OFFSET * offset));
regval = (*regaddr & ~maskline);
*regaddr = regval;
/* 3] Clear triggers in case of configurable lines */
if ((hexti->Line & EXTI_CONFIG) != 0x00u)
{
regaddr = (&EXTI->RTSR1 + (EXTI_CONFIG_OFFSET * offset));
regval = (*regaddr & ~maskline);
*regaddr = regval;
regaddr = (&EXTI->FTSR1 + (EXTI_CONFIG_OFFSET * offset));
regval = (*regaddr & ~maskline);
*regaddr = regval;
/* Get Gpio port selection for gpio lines */
if ((hexti->Line & EXTI_GPIO) == EXTI_GPIO)
{
assert_param(IS_EXTI_GPIO_PIN(linepos));
regval = SYSCFG->EXTICR[linepos >> 2u];
regval &= ~(SYSCFG_EXTICR1_EXTI0 << (SYSCFG_EXTICR1_EXTI1_Pos * (linepos & 0x03u)));
SYSCFG->EXTICR[linepos >> 2u] = regval;
}
}
return HAL_OK;
}
/**
* @brief Register callback for a dedicated Exti line.
* @param hexti Exti handle.
* @param CallbackID User callback identifier.
* This parameter can be one of @arg @ref EXTI_CallbackIDTypeDef values.
* @param pPendingCbfn function pointer to be stored as callback.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_RegisterCallback(EXTI_HandleTypeDef *hexti, EXTI_CallbackIDTypeDef CallbackID, void (*pPendingCbfn)(void))
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_EXTI_CB(CallbackID));
switch (CallbackID)
{
/* set common callback */
case HAL_EXTI_COMMON_CB_ID:
hexti->PendingCallback = pPendingCbfn;
break;
default:
hexti->PendingCallback = NULL;
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Store line number as handle private field.
* @param hexti Exti handle.
* @param ExtiLine Exti line number.
* This parameter can be from 0 to @ref EXTI_LINE_NB.
* @retval HAL Status.
*/
HAL_StatusTypeDef HAL_EXTI_GetHandle(EXTI_HandleTypeDef *hexti, uint32_t ExtiLine)
{
/* Check the parameters */
assert_param(IS_EXTI_LINE(ExtiLine));
/* Check null pointer */
if (hexti == NULL)
{
return HAL_ERROR;
}
else
{
/* Store line number as handle private field */
hexti->Line = ExtiLine;
return HAL_OK;
}
}
/**
* @}
*/
/** @addtogroup EXTI_Exported_Functions_Group2
* @brief EXTI IO functions.
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
@endverbatim
* @{
*/
/**
* @brief Handle EXTI interrupt request.
* @param hexti Exti handle.
* @retval none.
*/
void HAL_EXTI_IRQHandler(EXTI_HandleTypeDef *hexti)
{
__IO uint32_t *regaddr;
uint32_t regval;
uint32_t maskline;
uint32_t offset;
/* Compute line register offset */
offset = ((hexti->Line & EXTI_REG_MASK) >> EXTI_REG_SHIFT);
/* compute line mask */
maskline = (1uL << (hexti->Line & EXTI_PIN_MASK));
/* Get pending bit */
regaddr = (&EXTI->PR1 + (EXTI_CONFIG_OFFSET * offset));
regval = (*regaddr & maskline);
if (regval != 0x00u)
{
/* Clear pending bit */
*regaddr = maskline;
/* Call pending callback */
if (hexti->PendingCallback != NULL)
{
hexti->PendingCallback();
}
}
}
/**
* @brief Get interrupt pending bit of a dedicated line.
* @param hexti Exti handle.
* @param Edge unused
* @retval 1 if interrupt is pending else 0.
*/
uint32_t HAL_EXTI_GetPending(EXTI_HandleTypeDef *hexti, uint32_t Edge)
{
__IO uint32_t *regaddr;
uint32_t regval;
uint32_t linepos;
uint32_t maskline;
uint32_t offset;
/* Check parameters */
assert_param(IS_EXTI_LINE(hexti->Line));
assert_param(IS_EXTI_CONFIG_LINE(hexti->Line));
UNUSED(Edge);
/* Compute line register offset */
offset = ((hexti->Line & EXTI_REG_MASK) >> EXTI_REG_SHIFT);
/* Compute line position */
linepos = (hexti->Line & EXTI_PIN_MASK);
/* Compute line mask */
maskline = (1uL << linepos);
/* Get pending bit */
regaddr = (&EXTI->PR1 + (EXTI_CONFIG_OFFSET * offset));
/* return 1 if bit is set else 0 */
regval = ((*regaddr & maskline) >> linepos);
return regval;
}
/**
* @brief Clear interrupt pending bit of a dedicated line.
* @param hexti Exti handle.
* @param Edge unused
* @retval None.
*/
void HAL_EXTI_ClearPending(EXTI_HandleTypeDef *hexti, uint32_t Edge)
{
__IO uint32_t *regaddr;
uint32_t maskline;
uint32_t offset;
/* Check parameters */
assert_param(IS_EXTI_LINE(hexti->Line));
assert_param(IS_EXTI_CONFIG_LINE(hexti->Line));
UNUSED(Edge);
/* Compute line register offset */
offset = ((hexti->Line & EXTI_REG_MASK) >> EXTI_REG_SHIFT);
/* Compute line mask */
maskline = (1uL << (hexti->Line & EXTI_PIN_MASK));
/* Get pending register address */
regaddr = (&EXTI->PR1 + (EXTI_CONFIG_OFFSET * offset));
/* Clear Pending bit */
*regaddr = maskline;
}
/**
* @brief Generate a software interrupt for a dedicated line.
* @param hexti Exti handle.
* @retval None.
*/
void HAL_EXTI_GenerateSWI(EXTI_HandleTypeDef *hexti)
{
__IO uint32_t *regaddr;
uint32_t maskline;
uint32_t offset;
/* Check parameter */
assert_param(IS_EXTI_LINE(hexti->Line));
assert_param(IS_EXTI_CONFIG_LINE(hexti->Line));
/* compute line register offset */
offset = ((hexti->Line & EXTI_REG_MASK) >> EXTI_REG_SHIFT);
/* compute line mask */
maskline = (1uL << (hexti->Line & EXTI_PIN_MASK));
regaddr = (&EXTI->SWIER1 + (EXTI_CONFIG_OFFSET * offset));
*regaddr = maskline;
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_EXTI_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 17,447 | C | 26.2625 | 133 | 0.58543 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_pwr_ex.c | /**
******************************************************************************
* @file stm32g4xx_hal_pwr_ex.c
* @author MCD Application Team
* @brief Extended PWR HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Power Controller (PWR) peripheral:
* + Extended Initialization and de-initialization functions
* + Extended Peripheral Control functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup PWREx PWREx
* @brief PWR Extended HAL module driver
* @{
*/
#ifdef HAL_PWR_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
#if defined (STM32G471xx) || defined (STM32G473xx) || defined (STM32G474xx) || defined (STM32G483xx) || defined (STM32G484xx)
#define PWR_PORTF_AVAILABLE_PINS 0x0000FFFFU /* PF0..PF15 */
#define PWR_PORTG_AVAILABLE_PINS 0x000007FFU /* PG0..PG10 */
#elif defined (STM32G431xx) || defined (STM32G441xx) || defined (STM32GBK1CB) || defined (STM32G491xx) || defined (STM32G4A1xx)
#define PWR_PORTF_AVAILABLE_PINS 0x00000607U /* PF0..PF2 and PF9 and PF10 */
#define PWR_PORTG_AVAILABLE_PINS 0x00000400U /* PG10 */
#endif
/** @defgroup PWR_Extended_Private_Defines PWR Extended Private Defines
* @{
*/
/** @defgroup PWREx_PVM_Mode_Mask PWR PVM Mode Mask
* @{
*/
#define PVM_MODE_IT 0x00010000U /*!< Mask for interruption yielded by PVM threshold crossing */
#define PVM_MODE_EVT 0x00020000U /*!< Mask for event yielded by PVM threshold crossing */
#define PVM_RISING_EDGE 0x00000001U /*!< Mask for rising edge set as PVM trigger */
#define PVM_FALLING_EDGE 0x00000002U /*!< Mask for falling edge set as PVM trigger */
/**
* @}
*/
/** @defgroup PWREx_TimeOut_Value PWR Extended Flag Setting Time Out Value
* @{
*/
#define PWR_FLAG_SETTING_DELAY_US 50UL /*!< Time out value for REGLPF and VOSF flags setting */
/**
* @}
*/
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup PWREx_Exported_Functions PWR Extended Exported Functions
* @{
*/
/** @defgroup PWREx_Exported_Functions_Group1 Extended Peripheral Control functions
* @brief Extended Peripheral Control functions
*
@verbatim
===============================================================================
##### Extended Peripheral Initialization and de-initialization functions #####
===============================================================================
[..]
@endverbatim
* @{
*/
/**
* @brief Return Voltage Scaling Range.
* @retval VOS bit field (PWR_REGULATOR_VOLTAGE_SCALE1 or PWR_REGULATOR_VOLTAGE_SCALE2
* or PWR_REGULATOR_VOLTAGE_SCALE1_BOOST when applicable)
*/
uint32_t HAL_PWREx_GetVoltageRange(void)
{
if (READ_BIT(PWR->CR1, PWR_CR1_VOS) == PWR_REGULATOR_VOLTAGE_SCALE2)
{
return PWR_REGULATOR_VOLTAGE_SCALE2;
}
else if (READ_BIT(PWR->CR5, PWR_CR5_R1MODE) == PWR_CR5_R1MODE)
{
/* PWR_CR5_R1MODE bit set means that Range 1 Boost is disabled */
return PWR_REGULATOR_VOLTAGE_SCALE1;
}
else
{
return PWR_REGULATOR_VOLTAGE_SCALE1_BOOST;
}
}
/**
* @brief Configure the main internal regulator output voltage.
* @param VoltageScaling: specifies the regulator output voltage to achieve
* a tradeoff between performance and power consumption.
* This parameter can be one of the following values:
* @arg @ref PWR_REGULATOR_VOLTAGE_SCALE1_BOOST when available, Regulator voltage output range 1 boost mode,
* typical output voltage at 1.28 V,
* system frequency up to 170 MHz.
* @arg @ref PWR_REGULATOR_VOLTAGE_SCALE1 Regulator voltage output range 1 mode,
* typical output voltage at 1.2 V,
* system frequency up to 150 MHz.
* @arg @ref PWR_REGULATOR_VOLTAGE_SCALE2 Regulator voltage output range 2 mode,
* typical output voltage at 1.0 V,
* system frequency up to 26 MHz.
* @note When moving from Range 1 to Range 2, the system frequency must be decreased to
* a value below 26 MHz before calling HAL_PWREx_ControlVoltageScaling() API.
* When moving from Range 2 to Range 1, the system frequency can be increased to
* a value up to 150 MHz after calling HAL_PWREx_ControlVoltageScaling() API.
* When moving from Range 1 to Boost Mode Range 1, the system frequency can be increased to
* a value up to 170 MHz after calling HAL_PWREx_ControlVoltageScaling() API.
* @note When moving from Range 2 to Range 1, the API waits for VOSF flag to be
* cleared before returning the status. If the flag is not cleared within
* 50 microseconds, HAL_TIMEOUT status is reported.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_PWREx_ControlVoltageScaling(uint32_t VoltageScaling)
{
uint32_t wait_loop_index;
assert_param(IS_PWR_VOLTAGE_SCALING_RANGE(VoltageScaling));
if (VoltageScaling == PWR_REGULATOR_VOLTAGE_SCALE1_BOOST)
{
/* If current range is range 2 */
if (READ_BIT(PWR->CR1, PWR_CR1_VOS) == PWR_REGULATOR_VOLTAGE_SCALE2)
{
/* Make sure Range 1 Boost is enabled */
CLEAR_BIT(PWR->CR5, PWR_CR5_R1MODE);
/* Set Range 1 */
MODIFY_REG(PWR->CR1, PWR_CR1_VOS, PWR_REGULATOR_VOLTAGE_SCALE1);
/* Wait until VOSF is cleared */
wait_loop_index = ((PWR_FLAG_SETTING_DELAY_US * SystemCoreClock) / 1000000U) + 1U;
while ((HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_VOSF)) && (wait_loop_index != 0U))
{
wait_loop_index--;
}
if (HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_VOSF))
{
return HAL_TIMEOUT;
}
}
/* If current range is range 1 normal or boost mode */
else
{
/* Enable Range 1 Boost (no issue if bit already reset) */
CLEAR_BIT(PWR->CR5, PWR_CR5_R1MODE);
}
}
else if (VoltageScaling == PWR_REGULATOR_VOLTAGE_SCALE1)
{
/* If current range is range 2 */
if (READ_BIT(PWR->CR1, PWR_CR1_VOS) == PWR_REGULATOR_VOLTAGE_SCALE2)
{
/* Make sure Range 1 Boost is disabled */
SET_BIT(PWR->CR5, PWR_CR5_R1MODE);
/* Set Range 1 */
MODIFY_REG(PWR->CR1, PWR_CR1_VOS, PWR_REGULATOR_VOLTAGE_SCALE1);
/* Wait until VOSF is cleared */
wait_loop_index = ((PWR_FLAG_SETTING_DELAY_US * SystemCoreClock) / 1000000U) + 1U;
while ((HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_VOSF)) && (wait_loop_index != 0U))
{
wait_loop_index--;
}
if (HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_VOSF))
{
return HAL_TIMEOUT;
}
}
/* If current range is range 1 normal or boost mode */
else
{
/* Disable Range 1 Boost (no issue if bit already set) */
SET_BIT(PWR->CR5, PWR_CR5_R1MODE);
}
}
else
{
/* Set Range 2 */
MODIFY_REG(PWR->CR1, PWR_CR1_VOS, PWR_REGULATOR_VOLTAGE_SCALE2);
/* No need to wait for VOSF to be cleared for this transition */
/* PWR_CR5_R1MODE bit setting has no effect in Range 2 */
}
return HAL_OK;
}
/**
* @brief Enable battery charging.
* When VDD is present, charge the external battery on VBAT through an internal resistor.
* @param ResistorSelection: specifies the resistor impedance.
* This parameter can be one of the following values:
* @arg @ref PWR_BATTERY_CHARGING_RESISTOR_5 5 kOhms resistor
* @arg @ref PWR_BATTERY_CHARGING_RESISTOR_1_5 1.5 kOhms resistor
* @retval None
*/
void HAL_PWREx_EnableBatteryCharging(uint32_t ResistorSelection)
{
assert_param(IS_PWR_BATTERY_RESISTOR_SELECT(ResistorSelection));
/* Specify resistor selection */
MODIFY_REG(PWR->CR4, PWR_CR4_VBRS, ResistorSelection);
/* Enable battery charging */
SET_BIT(PWR->CR4, PWR_CR4_VBE);
}
/**
* @brief Disable battery charging.
* @retval None
*/
void HAL_PWREx_DisableBatteryCharging(void)
{
CLEAR_BIT(PWR->CR4, PWR_CR4_VBE);
}
/**
* @brief Enable Internal Wake-up Line.
* @retval None
*/
void HAL_PWREx_EnableInternalWakeUpLine(void)
{
SET_BIT(PWR->CR3, PWR_CR3_EIWF);
}
/**
* @brief Disable Internal Wake-up Line.
* @retval None
*/
void HAL_PWREx_DisableInternalWakeUpLine(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_EIWF);
}
/**
* @brief Enable GPIO pull-up state in Standby and Shutdown modes.
* @note Set the relevant PUy bits of PWR_PUCRx register to configure the I/O in
* pull-up state in Standby and Shutdown modes.
* @note This state is effective in Standby and Shutdown modes only if APC bit
* is set through HAL_PWREx_EnablePullUpPullDownConfig() API.
* @note The configuration is lost when exiting the Shutdown mode due to the
* power-on reset, maintained when exiting the Standby mode.
* @note To avoid any conflict at Standby and Shutdown modes exits, the corresponding
* PDy bit of PWR_PDCRx register is cleared unless it is reserved.
* @note Even if a PUy bit to set is reserved, the other PUy bits entered as input
* parameter at the same time are set.
* @param GPIO: Specify the IO port. This parameter can be PWR_GPIO_A, ..., PWR_GPIO_G
* (or PWR_GPIO_I depending on the devices) to select the GPIO peripheral.
* @param GPIONumber: Specify the I/O pins numbers.
* This parameter can be one of the following values:
* PWR_GPIO_BIT_0, ..., PWR_GPIO_BIT_15 (except for the port where less
* I/O pins are available) or the logical OR of several of them to set
* several bits for a given port in a single API call.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_PWREx_EnableGPIOPullUp(uint32_t GPIO, uint32_t GPIONumber)
{
HAL_StatusTypeDef status = HAL_OK;
assert_param(IS_PWR_GPIO(GPIO));
assert_param(IS_PWR_GPIO_BIT_NUMBER(GPIONumber));
switch (GPIO)
{
case PWR_GPIO_A:
SET_BIT(PWR->PUCRA, (GPIONumber & (~(PWR_GPIO_BIT_14))));
CLEAR_BIT(PWR->PDCRA, (GPIONumber & (~(PWR_GPIO_BIT_13|PWR_GPIO_BIT_15))));
break;
case PWR_GPIO_B:
SET_BIT(PWR->PUCRB, GPIONumber);
CLEAR_BIT(PWR->PDCRB, (GPIONumber & (~(PWR_GPIO_BIT_4))));
break;
case PWR_GPIO_C:
SET_BIT(PWR->PUCRC, GPIONumber);
CLEAR_BIT(PWR->PDCRC, GPIONumber);
break;
case PWR_GPIO_D:
SET_BIT(PWR->PUCRD, GPIONumber);
CLEAR_BIT(PWR->PDCRD, GPIONumber);
break;
case PWR_GPIO_E:
SET_BIT(PWR->PUCRE, GPIONumber);
CLEAR_BIT(PWR->PDCRE, GPIONumber);
break;
case PWR_GPIO_F:
SET_BIT(PWR->PUCRF, (GPIONumber & PWR_PORTF_AVAILABLE_PINS));
CLEAR_BIT(PWR->PDCRF, (GPIONumber & PWR_PORTF_AVAILABLE_PINS));
break;
case PWR_GPIO_G:
SET_BIT(PWR->PUCRG, (GPIONumber & PWR_PORTG_AVAILABLE_PINS));
CLEAR_BIT(PWR->PDCRG, ((GPIONumber & PWR_PORTG_AVAILABLE_PINS) & (~(PWR_GPIO_BIT_10))));
break;
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Disable GPIO pull-up state in Standby mode and Shutdown modes.
* @note Reset the relevant PUy bits of PWR_PUCRx register used to configure the I/O
* in pull-up state in Standby and Shutdown modes.
* @note Even if a PUy bit to reset is reserved, the other PUy bits entered as input
* parameter at the same time are reset.
* @param GPIO: Specifies the IO port. This parameter can be PWR_GPIO_A, ..., PWR_GPIO_G
* (or PWR_GPIO_I depending on the devices) to select the GPIO peripheral.
* @param GPIONumber: Specify the I/O pins numbers.
* This parameter can be one of the following values:
* PWR_GPIO_BIT_0, ..., PWR_GPIO_BIT_15 (except for the port where less
* I/O pins are available) or the logical OR of several of them to reset
* several bits for a given port in a single API call.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_PWREx_DisableGPIOPullUp(uint32_t GPIO, uint32_t GPIONumber)
{
HAL_StatusTypeDef status = HAL_OK;
assert_param(IS_PWR_GPIO(GPIO));
assert_param(IS_PWR_GPIO_BIT_NUMBER(GPIONumber));
switch (GPIO)
{
case PWR_GPIO_A:
CLEAR_BIT(PWR->PUCRA, (GPIONumber & (~(PWR_GPIO_BIT_14))));
break;
case PWR_GPIO_B:
CLEAR_BIT(PWR->PUCRB, GPIONumber);
break;
case PWR_GPIO_C:
CLEAR_BIT(PWR->PUCRC, GPIONumber);
break;
case PWR_GPIO_D:
CLEAR_BIT(PWR->PUCRD, GPIONumber);
break;
case PWR_GPIO_E:
CLEAR_BIT(PWR->PUCRE, GPIONumber);
break;
case PWR_GPIO_F:
CLEAR_BIT(PWR->PUCRF, (GPIONumber & PWR_PORTF_AVAILABLE_PINS));
break;
case PWR_GPIO_G:
CLEAR_BIT(PWR->PUCRG, (GPIONumber & PWR_PORTG_AVAILABLE_PINS));
break;
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Enable GPIO pull-down state in Standby and Shutdown modes.
* @note Set the relevant PDy bits of PWR_PDCRx register to configure the I/O in
* pull-down state in Standby and Shutdown modes.
* @note This state is effective in Standby and Shutdown modes only if APC bit
* is set through HAL_PWREx_EnablePullUpPullDownConfig() API.
* @note The configuration is lost when exiting the Shutdown mode due to the
* power-on reset, maintained when exiting the Standby mode.
* @note To avoid any conflict at Standby and Shutdown modes exits, the corresponding
* PUy bit of PWR_PUCRx register is cleared unless it is reserved.
* @note Even if a PDy bit to set is reserved, the other PDy bits entered as input
* parameter at the same time are set.
* @param GPIO: Specify the IO port. This parameter can be PWR_GPIO_A..PWR_GPIO_G
* (or PWR_GPIO_I depending on the devices) to select the GPIO peripheral.
* @param GPIONumber: Specify the I/O pins numbers.
* This parameter can be one of the following values:
* PWR_GPIO_BIT_0, ..., PWR_GPIO_BIT_15 (except for the port where less
* I/O pins are available) or the logical OR of several of them to set
* several bits for a given port in a single API call.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_PWREx_EnableGPIOPullDown(uint32_t GPIO, uint32_t GPIONumber)
{
HAL_StatusTypeDef status = HAL_OK;
assert_param(IS_PWR_GPIO(GPIO));
assert_param(IS_PWR_GPIO_BIT_NUMBER(GPIONumber));
switch (GPIO)
{
case PWR_GPIO_A:
SET_BIT(PWR->PDCRA, (GPIONumber & (~(PWR_GPIO_BIT_13|PWR_GPIO_BIT_15))));
CLEAR_BIT(PWR->PUCRA, (GPIONumber & (~(PWR_GPIO_BIT_14))));
break;
case PWR_GPIO_B:
SET_BIT(PWR->PDCRB, (GPIONumber & (~(PWR_GPIO_BIT_4))));
CLEAR_BIT(PWR->PUCRB, GPIONumber);
break;
case PWR_GPIO_C:
SET_BIT(PWR->PDCRC, GPIONumber);
CLEAR_BIT(PWR->PUCRC, GPIONumber);
break;
case PWR_GPIO_D:
SET_BIT(PWR->PDCRD, GPIONumber);
CLEAR_BIT(PWR->PUCRD, GPIONumber);
break;
case PWR_GPIO_E:
SET_BIT(PWR->PDCRE, GPIONumber);
CLEAR_BIT(PWR->PUCRE, GPIONumber);
break;
case PWR_GPIO_F:
SET_BIT(PWR->PDCRF, (GPIONumber & PWR_PORTF_AVAILABLE_PINS));
CLEAR_BIT(PWR->PUCRF, (GPIONumber & PWR_PORTF_AVAILABLE_PINS));
break;
case PWR_GPIO_G:
SET_BIT(PWR->PDCRG, ((GPIONumber & PWR_PORTG_AVAILABLE_PINS) & (~(PWR_GPIO_BIT_10))));
CLEAR_BIT(PWR->PUCRG, (GPIONumber & PWR_PORTG_AVAILABLE_PINS));
break;
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Disable GPIO pull-down state in Standby and Shutdown modes.
* @note Reset the relevant PDy bits of PWR_PDCRx register used to configure the I/O
* in pull-down state in Standby and Shutdown modes.
* @note Even if a PDy bit to reset is reserved, the other PDy bits entered as input
* parameter at the same time are reset.
* @param GPIO: Specifies the IO port. This parameter can be PWR_GPIO_A..PWR_GPIO_G
* (or PWR_GPIO_I depending on the devices) to select the GPIO peripheral.
* @param GPIONumber: Specify the I/O pins numbers.
* This parameter can be one of the following values:
* PWR_GPIO_BIT_0, ..., PWR_GPIO_BIT_15 (except for the port where less
* I/O pins are available) or the logical OR of several of them to reset
* several bits for a given port in a single API call.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_PWREx_DisableGPIOPullDown(uint32_t GPIO, uint32_t GPIONumber)
{
HAL_StatusTypeDef status = HAL_OK;
assert_param(IS_PWR_GPIO(GPIO));
assert_param(IS_PWR_GPIO_BIT_NUMBER(GPIONumber));
switch (GPIO)
{
case PWR_GPIO_A:
CLEAR_BIT(PWR->PDCRA, (GPIONumber & (~(PWR_GPIO_BIT_13|PWR_GPIO_BIT_15))));
break;
case PWR_GPIO_B:
CLEAR_BIT(PWR->PDCRB, (GPIONumber & (~(PWR_GPIO_BIT_4))));
break;
case PWR_GPIO_C:
CLEAR_BIT(PWR->PDCRC, GPIONumber);
break;
case PWR_GPIO_D:
CLEAR_BIT(PWR->PDCRD, GPIONumber);
break;
case PWR_GPIO_E:
CLEAR_BIT(PWR->PDCRE, GPIONumber);
break;
case PWR_GPIO_F:
CLEAR_BIT(PWR->PDCRF, (GPIONumber & PWR_PORTF_AVAILABLE_PINS));
break;
case PWR_GPIO_G:
CLEAR_BIT(PWR->PDCRG, ((GPIONumber & PWR_PORTG_AVAILABLE_PINS) & (~(PWR_GPIO_BIT_10))));
break;
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Enable pull-up and pull-down configuration.
* @note When APC bit is set, the I/O pull-up and pull-down configurations defined in
* PWR_PUCRx and PWR_PDCRx registers are applied in Standby and Shutdown modes.
* @note Pull-up set by PUy bit of PWR_PUCRx register is not activated if the corresponding
* PDy bit of PWR_PDCRx register is also set (pull-down configuration priority is higher).
* HAL_PWREx_EnableGPIOPullUp() and HAL_PWREx_EnableGPIOPullDown() API's ensure there
* is no conflict when setting PUy or PDy bit.
* @retval None
*/
void HAL_PWREx_EnablePullUpPullDownConfig(void)
{
SET_BIT(PWR->CR3, PWR_CR3_APC);
}
/**
* @brief Disable pull-up and pull-down configuration.
* @note When APC bit is cleared, the I/O pull-up and pull-down configurations defined in
* PWR_PUCRx and PWR_PDCRx registers are not applied in Standby and Shutdown modes.
* @retval None
*/
void HAL_PWREx_DisablePullUpPullDownConfig(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_APC);
}
/**
* @brief Enable SRAM2 content retention in Standby mode.
* @note When RRS bit is set, SRAM2 is powered by the low-power regulator in
* Standby mode and its content is kept.
* @retval None
*/
void HAL_PWREx_EnableSRAM2ContentRetention(void)
{
SET_BIT(PWR->CR3, PWR_CR3_RRS);
}
/**
* @brief Disable SRAM2 content retention in Standby mode.
* @note When RRS bit is reset, SRAM2 is powered off in Standby mode
* and its content is lost.
* @retval None
*/
void HAL_PWREx_DisableSRAM2ContentRetention(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_RRS);
}
#if defined(PWR_CR2_PVME1)
/**
* @brief Enable the Power Voltage Monitoring 1: VDDA versus FASTCOMP minimum voltage.
* @retval None
*/
void HAL_PWREx_EnablePVM1(void)
{
SET_BIT(PWR->CR2, PWR_PVM_1);
}
/**
* @brief Disable the Power Voltage Monitoring 1: VDDA versus FASTCOMP minimum voltage.
* @retval None
*/
void HAL_PWREx_DisablePVM1(void)
{
CLEAR_BIT(PWR->CR2, PWR_PVM_1);
}
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
/**
* @brief Enable the Power Voltage Monitoring 2: VDDA versus FASTDAC minimum voltage.
* @retval None
*/
void HAL_PWREx_EnablePVM2(void)
{
SET_BIT(PWR->CR2, PWR_PVM_2);
}
/**
* @brief Disable the Power Voltage Monitoring 2: VDDA versus FASTDAC minimum voltage.
* @retval None
*/
void HAL_PWREx_DisablePVM2(void)
{
CLEAR_BIT(PWR->CR2, PWR_PVM_2);
}
#endif /* PWR_CR2_PVME2 */
/**
* @brief Enable the Power Voltage Monitoring 3: VDDA versus ADC minimum voltage 1.62V.
* @retval None
*/
void HAL_PWREx_EnablePVM3(void)
{
SET_BIT(PWR->CR2, PWR_PVM_3);
}
/**
* @brief Disable the Power Voltage Monitoring 3: VDDA versus ADC minimum voltage 1.62V.
* @retval None
*/
void HAL_PWREx_DisablePVM3(void)
{
CLEAR_BIT(PWR->CR2, PWR_PVM_3);
}
/**
* @brief Enable the Power Voltage Monitoring 4: VDDA versus OPAMP/DAC minimum voltage 1.8V.
* @retval None
*/
void HAL_PWREx_EnablePVM4(void)
{
SET_BIT(PWR->CR2, PWR_PVM_4);
}
/**
* @brief Disable the Power Voltage Monitoring 4: VDDA versus OPAMP/DAC minimum voltage 1.8V.
* @retval None
*/
void HAL_PWREx_DisablePVM4(void)
{
CLEAR_BIT(PWR->CR2, PWR_PVM_4);
}
/**
* @brief Configure the Peripheral Voltage Monitoring (PVM).
* @param sConfigPVM: pointer to a PWR_PVMTypeDef structure that contains the
* PVM configuration information.
* @note The API configures a single PVM according to the information contained
* in the input structure. To configure several PVMs, the API must be singly
* called for each PVM used.
* @note Refer to the electrical characteristics of your device datasheet for
* more details about the voltage thresholds corresponding to each
* detection level and to each monitored supply.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_PWREx_ConfigPVM(PWR_PVMTypeDef *sConfigPVM)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_PWR_PVM_TYPE(sConfigPVM->PVMType));
assert_param(IS_PWR_PVM_MODE(sConfigPVM->Mode));
/* Configure EXTI 35 to 38 interrupts if so required:
scan through PVMType to detect which PVMx is set and
configure the corresponding EXTI line accordingly. */
switch (sConfigPVM->PVMType)
{
#if defined(PWR_CR2_PVME1)
case PWR_PVM_1:
/* Clear any previous config. Keep it clear if no event or IT mode is selected */
__HAL_PWR_PVM1_EXTI_DISABLE_EVENT();
__HAL_PWR_PVM1_EXTI_DISABLE_IT();
__HAL_PWR_PVM1_EXTI_DISABLE_FALLING_EDGE();
__HAL_PWR_PVM1_EXTI_DISABLE_RISING_EDGE();
/* Configure interrupt mode */
if((sConfigPVM->Mode & PVM_MODE_IT) == PVM_MODE_IT)
{
__HAL_PWR_PVM1_EXTI_ENABLE_IT();
}
/* Configure event mode */
if((sConfigPVM->Mode & PVM_MODE_EVT) == PVM_MODE_EVT)
{
__HAL_PWR_PVM1_EXTI_ENABLE_EVENT();
}
/* Configure the edge */
if((sConfigPVM->Mode & PVM_RISING_EDGE) == PVM_RISING_EDGE)
{
__HAL_PWR_PVM1_EXTI_ENABLE_RISING_EDGE();
}
if((sConfigPVM->Mode & PVM_FALLING_EDGE) == PVM_FALLING_EDGE)
{
__HAL_PWR_PVM1_EXTI_ENABLE_FALLING_EDGE();
}
break;
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
case PWR_PVM_2:
/* Clear any previous config. Keep it clear if no event or IT mode is selected */
__HAL_PWR_PVM2_EXTI_DISABLE_EVENT();
__HAL_PWR_PVM2_EXTI_DISABLE_IT();
__HAL_PWR_PVM2_EXTI_DISABLE_FALLING_EDGE();
__HAL_PWR_PVM2_EXTI_DISABLE_RISING_EDGE();
/* Configure interrupt mode */
if((sConfigPVM->Mode & PVM_MODE_IT) == PVM_MODE_IT)
{
__HAL_PWR_PVM2_EXTI_ENABLE_IT();
}
/* Configure event mode */
if((sConfigPVM->Mode & PVM_MODE_EVT) == PVM_MODE_EVT)
{
__HAL_PWR_PVM2_EXTI_ENABLE_EVENT();
}
/* Configure the edge */
if((sConfigPVM->Mode & PVM_RISING_EDGE) == PVM_RISING_EDGE)
{
__HAL_PWR_PVM2_EXTI_ENABLE_RISING_EDGE();
}
if((sConfigPVM->Mode & PVM_FALLING_EDGE) == PVM_FALLING_EDGE)
{
__HAL_PWR_PVM2_EXTI_ENABLE_FALLING_EDGE();
}
break;
#endif /* PWR_CR2_PVME2 */
case PWR_PVM_3:
/* Clear any previous config. Keep it clear if no event or IT mode is selected */
__HAL_PWR_PVM3_EXTI_DISABLE_EVENT();
__HAL_PWR_PVM3_EXTI_DISABLE_IT();
__HAL_PWR_PVM3_EXTI_DISABLE_FALLING_EDGE();
__HAL_PWR_PVM3_EXTI_DISABLE_RISING_EDGE();
/* Configure interrupt mode */
if((sConfigPVM->Mode & PVM_MODE_IT) == PVM_MODE_IT)
{
__HAL_PWR_PVM3_EXTI_ENABLE_IT();
}
/* Configure event mode */
if((sConfigPVM->Mode & PVM_MODE_EVT) == PVM_MODE_EVT)
{
__HAL_PWR_PVM3_EXTI_ENABLE_EVENT();
}
/* Configure the edge */
if((sConfigPVM->Mode & PVM_RISING_EDGE) == PVM_RISING_EDGE)
{
__HAL_PWR_PVM3_EXTI_ENABLE_RISING_EDGE();
}
if((sConfigPVM->Mode & PVM_FALLING_EDGE) == PVM_FALLING_EDGE)
{
__HAL_PWR_PVM3_EXTI_ENABLE_FALLING_EDGE();
}
break;
case PWR_PVM_4:
/* Clear any previous config. Keep it clear if no event or IT mode is selected */
__HAL_PWR_PVM4_EXTI_DISABLE_EVENT();
__HAL_PWR_PVM4_EXTI_DISABLE_IT();
__HAL_PWR_PVM4_EXTI_DISABLE_FALLING_EDGE();
__HAL_PWR_PVM4_EXTI_DISABLE_RISING_EDGE();
/* Configure interrupt mode */
if((sConfigPVM->Mode & PVM_MODE_IT) == PVM_MODE_IT)
{
__HAL_PWR_PVM4_EXTI_ENABLE_IT();
}
/* Configure event mode */
if((sConfigPVM->Mode & PVM_MODE_EVT) == PVM_MODE_EVT)
{
__HAL_PWR_PVM4_EXTI_ENABLE_EVENT();
}
/* Configure the edge */
if((sConfigPVM->Mode & PVM_RISING_EDGE) == PVM_RISING_EDGE)
{
__HAL_PWR_PVM4_EXTI_ENABLE_RISING_EDGE();
}
if((sConfigPVM->Mode & PVM_FALLING_EDGE) == PVM_FALLING_EDGE)
{
__HAL_PWR_PVM4_EXTI_ENABLE_FALLING_EDGE();
}
break;
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Enter Low-power Run mode
* @note In Low-power Run mode, all I/O pins keep the same state as in Run mode.
* @note When Regulator is set to PWR_LOWPOWERREGULATOR_ON, the user can optionally configure the
* Flash in power-down monde in setting the RUN_PD bit in FLASH_ACR register.
* Additionally, the clock frequency must be reduced below 2 MHz.
* Setting RUN_PD in FLASH_ACR then appropriately reducing the clock frequency must
* be done before calling HAL_PWREx_EnableLowPowerRunMode() API.
* @retval None
*/
void HAL_PWREx_EnableLowPowerRunMode(void)
{
/* Set Regulator parameter */
SET_BIT(PWR->CR1, PWR_CR1_LPR);
}
/**
* @brief Exit Low-power Run mode.
* @note Before HAL_PWREx_DisableLowPowerRunMode() completion, the function checks that
* REGLPF has been properly reset (otherwise, HAL_PWREx_DisableLowPowerRunMode
* returns HAL_TIMEOUT status). The system clock frequency can then be
* increased above 2 MHz.
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_PWREx_DisableLowPowerRunMode(void)
{
uint32_t wait_loop_index;
/* Clear LPR bit */
CLEAR_BIT(PWR->CR1, PWR_CR1_LPR);
/* Wait until REGLPF is reset */
wait_loop_index = (PWR_FLAG_SETTING_DELAY_US * (SystemCoreClock / 1000000U));
while ((HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_REGLPF)) && (wait_loop_index != 0U))
{
wait_loop_index--;
}
if (HAL_IS_BIT_SET(PWR->SR2, PWR_SR2_REGLPF))
{
return HAL_TIMEOUT;
}
return HAL_OK;
}
/**
* @brief Enter Stop 0 mode.
* @note In Stop 0 mode, main and low voltage regulators are ON.
* @note In Stop 0 mode, all I/O pins keep the same state as in Run mode.
* @note All clocks in the VCORE domain are stopped; the PLL, the HSI
* and the HSE oscillators are disabled. Some peripherals with the wakeup capability
* (I2Cx, USARTx and LPUART) can switch on the HSI to receive a frame, and switch off the HSI
* after receiving the frame if it is not a wakeup frame. In this case, the HSI clock is propagated
* only to the peripheral requesting it.
* SRAM1, SRAM2 and register contents are preserved.
* The BOR is available.
* @note When exiting Stop 0 mode by issuing an interrupt or a wakeup event,
* the HSI RC oscillator is selected as system clock if STOPWUCK bit in RCC_CFGR register
* is set; the HSI oscillator is selected if STOPWUCK is cleared.
* @note By keeping the internal regulator ON during Stop 0 mode, the consumption
* is higher although the startup time is reduced.
* @param STOPEntry specifies if Stop mode in entered with WFI or WFE instruction.
* This parameter can be one of the following values:
* @arg @ref PWR_STOPENTRY_WFI Enter Stop mode with WFI instruction
* @arg @ref PWR_STOPENTRY_WFE Enter Stop mode with WFE instruction
* @retval None
*/
void HAL_PWREx_EnterSTOP0Mode(uint8_t STOPEntry)
{
/* Check the parameters */
assert_param(IS_PWR_STOP_ENTRY(STOPEntry));
/* Stop 0 mode with Main Regulator */
MODIFY_REG(PWR->CR1, PWR_CR1_LPMS, PWR_CR1_LPMS_STOP0);
/* Set SLEEPDEEP bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* Select Stop mode entry --------------------------------------------------*/
if(STOPEntry == PWR_STOPENTRY_WFI)
{
/* Request Wait For Interrupt */
__WFI();
}
else
{
/* Request Wait For Event */
__SEV();
__WFE();
__WFE();
}
/* Reset SLEEPDEEP bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
}
/**
* @brief Enter Stop 1 mode.
* @note In Stop 1 mode, only low power voltage regulator is ON.
* @note In Stop 1 mode, all I/O pins keep the same state as in Run mode.
* @note All clocks in the VCORE domain are stopped; the PLL, the HSI
* and the HSE oscillators are disabled. Some peripherals with the wakeup capability
* (I2Cx, USARTx and LPUART) can switch on the HSI to receive a frame, and switch off the HSI
* after receiving the frame if it is not a wakeup frame. In this case, the HSI clock is propagated
* only to the peripheral requesting it.
* SRAM1, SRAM2 and register contents are preserved.
* The BOR is available.
* @note When exiting Stop 1 mode by issuing an interrupt or a wakeup event,
* the HSI RC oscillator is selected as system clock if STOPWUCK bit in RCC_CFGR register
* is set.
* @note Due to low power mode, an additional startup delay is incurred when waking up from Stop 1 mode.
* @param STOPEntry specifies if Stop mode in entered with WFI or WFE instruction.
* This parameter can be one of the following values:
* @arg @ref PWR_STOPENTRY_WFI Enter Stop mode with WFI instruction
* @arg @ref PWR_STOPENTRY_WFE Enter Stop mode with WFE instruction
* @retval None
*/
void HAL_PWREx_EnterSTOP1Mode(uint8_t STOPEntry)
{
/* Check the parameters */
assert_param(IS_PWR_STOP_ENTRY(STOPEntry));
/* Stop 1 mode with Low-Power Regulator */
MODIFY_REG(PWR->CR1, PWR_CR1_LPMS, PWR_CR1_LPMS_STOP1);
/* Set SLEEPDEEP bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* Select Stop mode entry --------------------------------------------------*/
if(STOPEntry == PWR_STOPENTRY_WFI)
{
/* Request Wait For Interrupt */
__WFI();
}
else
{
/* Request Wait For Event */
__SEV();
__WFE();
__WFE();
}
/* Reset SLEEPDEEP bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
}
/**
* @brief Enter Shutdown mode.
* @note In Shutdown mode, the PLL, the HSI, the LSI and the HSE oscillators are switched
* off. The voltage regulator is disabled and Vcore domain is powered off.
* SRAM1, SRAM2 and registers contents are lost except for registers in the Backup domain.
* The BOR is not available.
* @note The I/Os can be configured either with a pull-up or pull-down or can be kept in analog state.
* @retval None
*/
void HAL_PWREx_EnterSHUTDOWNMode(void)
{
/* Set Shutdown mode */
MODIFY_REG(PWR->CR1, PWR_CR1_LPMS, PWR_CR1_LPMS_SHUTDOWN);
/* Set SLEEPDEEP bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
/* This option is used to ensure that store operations are completed */
#if defined ( __CC_ARM)
__force_stores();
#endif
/* Request Wait For Interrupt */
__WFI();
}
/**
* @brief This function handles the PWR PVD/PVMx interrupt request.
* @note This API should be called under the PVD_PVM_IRQHandler().
* @retval None
*/
void HAL_PWREx_PVD_PVM_IRQHandler(void)
{
/* Check PWR exti flag */
if(__HAL_PWR_PVD_EXTI_GET_FLAG() != 0U)
{
/* PWR PVD interrupt user callback */
HAL_PWR_PVDCallback();
/* Clear PVD exti pending bit */
__HAL_PWR_PVD_EXTI_CLEAR_FLAG();
}
/* Next, successively check PVMx exti flags */
#if defined(PWR_CR2_PVME1)
if(__HAL_PWR_PVM1_EXTI_GET_FLAG() != 0U)
{
/* PWR PVM1 interrupt user callback */
HAL_PWREx_PVM1Callback();
/* Clear PVM1 exti pending bit */
__HAL_PWR_PVM1_EXTI_CLEAR_FLAG();
}
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
if(__HAL_PWR_PVM2_EXTI_GET_FLAG() != 0U)
{
/* PWR PVM2 interrupt user callback */
HAL_PWREx_PVM2Callback();
/* Clear PVM2 exti pending bit */
__HAL_PWR_PVM2_EXTI_CLEAR_FLAG();
}
#endif /* PWR_CR2_PVME2 */
if(__HAL_PWR_PVM3_EXTI_GET_FLAG() != 0U)
{
/* PWR PVM3 interrupt user callback */
HAL_PWREx_PVM3Callback();
/* Clear PVM3 exti pending bit */
__HAL_PWR_PVM3_EXTI_CLEAR_FLAG();
}
if(__HAL_PWR_PVM4_EXTI_GET_FLAG() != 0U)
{
/* PWR PVM4 interrupt user callback */
HAL_PWREx_PVM4Callback();
/* Clear PVM4 exti pending bit */
__HAL_PWR_PVM4_EXTI_CLEAR_FLAG();
}
}
#if defined(PWR_CR2_PVME1)
/**
* @brief PWR PVM1 interrupt callback
* @retval None
*/
__weak void HAL_PWREx_PVM1Callback(void)
{
/* NOTE : This function should not be modified; when the callback is needed,
HAL_PWREx_PVM1Callback() API can be implemented in the user file
*/
}
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
/**
* @brief PWR PVM2 interrupt callback
* @retval None
*/
__weak void HAL_PWREx_PVM2Callback(void)
{
/* NOTE : This function should not be modified; when the callback is needed,
HAL_PWREx_PVM2Callback() API can be implemented in the user file
*/
}
#endif /* PWR_CR2_PVME2 */
/**
* @brief PWR PVM3 interrupt callback
* @retval None
*/
__weak void HAL_PWREx_PVM3Callback(void)
{
/* NOTE : This function should not be modified; when the callback is needed,
HAL_PWREx_PVM3Callback() API can be implemented in the user file
*/
}
/**
* @brief PWR PVM4 interrupt callback
* @retval None
*/
__weak void HAL_PWREx_PVM4Callback(void)
{
/* NOTE : This function should not be modified; when the callback is needed,
HAL_PWREx_PVM4Callback() API can be implemented in the user file
*/
}
#if defined(PWR_CR3_UCPD_STDBY)
/**
* @brief Enable UCPD configuration memorization in Standby.
* @retval None
*/
void HAL_PWREx_EnableUCPDStandbyMode(void)
{
/* Memorize UCPD configuration when entering standby mode */
SET_BIT(PWR->CR3, PWR_CR3_UCPD_STDBY);
}
/**
* @brief Disable UCPD configuration memorization in Standby.
* @note This function must be called on exiting the Standby mode and before any UCPD
* configuration update.
* @retval None
*/
void HAL_PWREx_DisableUCPDStandbyMode(void)
{
/* Write 0 immediately after Standby exit when using UCPD,
and before writing any UCPD registers */
CLEAR_BIT(PWR->CR3, PWR_CR3_UCPD_STDBY);
}
#endif /* PWR_CR3_UCPD_STDBY */
#if defined(PWR_CR3_UCPD_DBDIS)
/**
* @brief Enable the USB Type-C dead battery pull-down behavior
* on UCPDx_CC1 and UCPDx_CC2 pins
* @retval None
*/
void HAL_PWREx_EnableUCPDDeadBattery(void)
{
/* Write 0 to enable the USB Type-C dead battery pull-down behavior */
CLEAR_BIT(PWR->CR3, PWR_CR3_UCPD_DBDIS);
}
/**
* @brief Disable the USB Type-C dead battery pull-down behavior
* on UCPDx_CC1 and UCPDx_CC2 pins
* @note After exiting reset, the USB Type-C dead battery behavior will be enabled,
* which may have a pull-down effect on CC1 and CC2 pins.
* It is recommended to disable it in all cases, either to stop this pull-down
* or to hand over control to the UCPD (which should therefore be
* initialized before doing the disable).
* @retval None
*/
void HAL_PWREx_DisableUCPDDeadBattery(void)
{
/* Write 1 to disable the USB Type-C dead battery pull-down behavior */
SET_BIT(PWR->CR3, PWR_CR3_UCPD_DBDIS);
}
#endif /* PWR_CR3_UCPD_DBDIS */
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_PWR_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 37,944 | C | 31.075232 | 127 | 0.626239 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_uart.c | /**
******************************************************************************
* @file stm32g4xx_hal_uart.c
* @author MCD Application Team
* @brief UART HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Universal Asynchronous Receiver Transmitter Peripheral (UART).
* + Initialization and de-initialization functions
* + IO operation functions
* + Peripheral Control functions
*
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
===============================================================================
##### How to use this driver #####
===============================================================================
[..]
The UART HAL driver can be used as follows:
(#) Declare a UART_HandleTypeDef handle structure (eg. UART_HandleTypeDef huart).
(#) Initialize the UART low level resources by implementing the HAL_UART_MspInit() API:
(++) Enable the USARTx interface clock.
(++) UART pins configuration:
(+++) Enable the clock for the UART GPIOs.
(+++) Configure these UART pins as alternate function pull-up.
(++) NVIC configuration if you need to use interrupt process (HAL_UART_Transmit_IT()
and HAL_UART_Receive_IT() APIs):
(+++) Configure the USARTx interrupt priority.
(+++) Enable the NVIC USART IRQ handle.
(++) UART interrupts handling:
-@@- The specific UART interrupts (Transmission complete interrupt,
RXNE interrupt, RX/TX FIFOs related interrupts and Error Interrupts)
are managed using the macros __HAL_UART_ENABLE_IT() and __HAL_UART_DISABLE_IT()
inside the transmit and receive processes.
(++) DMA Configuration if you need to use DMA process (HAL_UART_Transmit_DMA()
and HAL_UART_Receive_DMA() APIs):
(+++) Declare a DMA handle structure for the Tx/Rx channel.
(+++) Enable the DMAx interface clock.
(+++) Configure the declared DMA handle structure with the required Tx/Rx parameters.
(+++) Configure the DMA Tx/Rx channel.
(+++) Associate the initialized DMA handle to the UART DMA Tx/Rx handle.
(+++) Configure the priority and enable the NVIC for the transfer complete
interrupt on the DMA Tx/Rx channel.
(#) Program the Baud Rate, Word Length, Stop Bit, Parity, Prescaler value , Hardware
flow control and Mode (Receiver/Transmitter) in the huart handle Init structure.
(#) If required, program UART advanced features (TX/RX pins swap, auto Baud rate detection,...)
in the huart handle AdvancedInit structure.
(#) For the UART asynchronous mode, initialize the UART registers by calling
the HAL_UART_Init() API.
(#) For the UART Half duplex mode, initialize the UART registers by calling
the HAL_HalfDuplex_Init() API.
(#) For the UART LIN (Local Interconnection Network) mode, initialize the UART registers
by calling the HAL_LIN_Init() API.
(#) For the UART Multiprocessor mode, initialize the UART registers
by calling the HAL_MultiProcessor_Init() API.
(#) For the UART RS485 Driver Enabled mode, initialize the UART registers
by calling the HAL_RS485Ex_Init() API.
[..]
(@) These API's (HAL_UART_Init(), HAL_HalfDuplex_Init(), HAL_LIN_Init(), HAL_MultiProcessor_Init(),
also configure the low level Hardware GPIO, CLOCK, CORTEX...etc) by
calling the customized HAL_UART_MspInit() API.
##### Callback registration #####
==================================
[..]
The compilation define USE_HAL_UART_REGISTER_CALLBACKS when set to 1
allows the user to configure dynamically the driver callbacks.
[..]
Use Function HAL_UART_RegisterCallback() to register a user callback.
Function HAL_UART_RegisterCallback() allows to register following callbacks:
(+) TxHalfCpltCallback : Tx Half Complete Callback.
(+) TxCpltCallback : Tx Complete Callback.
(+) RxHalfCpltCallback : Rx Half Complete Callback.
(+) RxCpltCallback : Rx Complete Callback.
(+) ErrorCallback : Error Callback.
(+) AbortCpltCallback : Abort Complete Callback.
(+) AbortTransmitCpltCallback : Abort Transmit Complete Callback.
(+) AbortReceiveCpltCallback : Abort Receive Complete Callback.
(+) WakeupCallback : Wakeup Callback.
(+) RxFifoFullCallback : Rx Fifo Full Callback.
(+) TxFifoEmptyCallback : Tx Fifo Empty Callback.
(+) MspInitCallback : UART MspInit.
(+) MspDeInitCallback : UART MspDeInit.
This function takes as parameters the HAL peripheral handle, the Callback ID
and a pointer to the user callback function.
[..]
Use function HAL_UART_UnRegisterCallback() to reset a callback to the default
weak function.
HAL_UART_UnRegisterCallback() takes as parameters the HAL peripheral handle,
and the Callback ID.
This function allows to reset following callbacks:
(+) TxHalfCpltCallback : Tx Half Complete Callback.
(+) TxCpltCallback : Tx Complete Callback.
(+) RxHalfCpltCallback : Rx Half Complete Callback.
(+) RxCpltCallback : Rx Complete Callback.
(+) ErrorCallback : Error Callback.
(+) AbortCpltCallback : Abort Complete Callback.
(+) AbortTransmitCpltCallback : Abort Transmit Complete Callback.
(+) AbortReceiveCpltCallback : Abort Receive Complete Callback.
(+) WakeupCallback : Wakeup Callback.
(+) RxFifoFullCallback : Rx Fifo Full Callback.
(+) TxFifoEmptyCallback : Tx Fifo Empty Callback.
(+) MspInitCallback : UART MspInit.
(+) MspDeInitCallback : UART MspDeInit.
[..]
For specific callback RxEventCallback, use dedicated registration/reset functions:
respectively HAL_UART_RegisterRxEventCallback() , HAL_UART_UnRegisterRxEventCallback().
[..]
By default, after the HAL_UART_Init() and when the state is HAL_UART_STATE_RESET
all callbacks are set to the corresponding weak functions:
examples HAL_UART_TxCpltCallback(), HAL_UART_RxHalfCpltCallback().
Exception done for MspInit and MspDeInit functions that are respectively
reset to the legacy weak functions in the HAL_UART_Init()
and HAL_UART_DeInit() only when these callbacks are null (not registered beforehand).
If not, MspInit or MspDeInit are not null, the HAL_UART_Init() and HAL_UART_DeInit()
keep and use the user MspInit/MspDeInit callbacks (registered beforehand).
[..]
Callbacks can be registered/unregistered in HAL_UART_STATE_READY state only.
Exception done MspInit/MspDeInit that can be registered/unregistered
in HAL_UART_STATE_READY or HAL_UART_STATE_RESET state, thus registered (user)
MspInit/DeInit callbacks can be used during the Init/DeInit.
In that case first register the MspInit/MspDeInit user callbacks
using HAL_UART_RegisterCallback() before calling HAL_UART_DeInit()
or HAL_UART_Init() function.
[..]
When The compilation define USE_HAL_UART_REGISTER_CALLBACKS is set to 0 or
not defined, the callback registration feature is not available
and weak callbacks are used.
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup UART UART
* @brief HAL UART module driver
* @{
*/
#ifdef HAL_UART_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @defgroup UART_Private_Constants UART Private Constants
* @{
*/
#define USART_CR1_FIELDS ((uint32_t)(USART_CR1_M | USART_CR1_PCE | USART_CR1_PS | USART_CR1_TE | USART_CR1_RE | \
USART_CR1_OVER8 | USART_CR1_FIFOEN)) /*!< UART or USART CR1 fields of parameters set by UART_SetConfig API */
#define USART_CR3_FIELDS ((uint32_t)(USART_CR3_RTSE | USART_CR3_CTSE | USART_CR3_ONEBIT | USART_CR3_TXFTCFG | \
USART_CR3_RXFTCFG)) /*!< UART or USART CR3 fields of parameters set by UART_SetConfig API */
#define LPUART_BRR_MIN 0x00000300U /* LPUART BRR minimum authorized value */
#define LPUART_BRR_MAX 0x000FFFFFU /* LPUART BRR maximum authorized value */
#define UART_BRR_MIN 0x10U /* UART BRR minimum authorized value */
#define UART_BRR_MAX 0x0000FFFFU /* UART BRR maximum authorized value */
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @addtogroup UART_Private_Functions
* @{
*/
static void UART_EndRxTransfer(UART_HandleTypeDef *huart);
static void UART_EndTxTransfer(UART_HandleTypeDef *huart);
static void UART_DMATransmitCplt(DMA_HandleTypeDef *hdma);
static void UART_DMAReceiveCplt(DMA_HandleTypeDef *hdma);
static void UART_DMARxHalfCplt(DMA_HandleTypeDef *hdma);
static void UART_DMATxHalfCplt(DMA_HandleTypeDef *hdma);
static void UART_DMAError(DMA_HandleTypeDef *hdma);
static void UART_DMAAbortOnError(DMA_HandleTypeDef *hdma);
static void UART_DMATxAbortCallback(DMA_HandleTypeDef *hdma);
static void UART_DMARxAbortCallback(DMA_HandleTypeDef *hdma);
static void UART_DMATxOnlyAbortCallback(DMA_HandleTypeDef *hdma);
static void UART_DMARxOnlyAbortCallback(DMA_HandleTypeDef *hdma);
static void UART_TxISR_8BIT(UART_HandleTypeDef *huart);
static void UART_TxISR_16BIT(UART_HandleTypeDef *huart);
static void UART_TxISR_8BIT_FIFOEN(UART_HandleTypeDef *huart);
static void UART_TxISR_16BIT_FIFOEN(UART_HandleTypeDef *huart);
static void UART_EndTransmit_IT(UART_HandleTypeDef *huart);
static void UART_RxISR_8BIT(UART_HandleTypeDef *huart);
static void UART_RxISR_16BIT(UART_HandleTypeDef *huart);
static void UART_RxISR_8BIT_FIFOEN(UART_HandleTypeDef *huart);
static void UART_RxISR_16BIT_FIFOEN(UART_HandleTypeDef *huart);
/**
* @}
*/
/* Private variables ---------------------------------------------------------*/
/** @addtogroup UART_Private_variables
* @{
*/
const uint16_t UARTPrescTable[12] = {1U, 2U, 4U, 6U, 8U, 10U, 12U, 16U, 32U, 64U, 128U, 256U};
/**
* @}
*/
/* Exported Constants --------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup UART_Exported_Functions UART Exported Functions
* @{
*/
/** @defgroup UART_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and Configuration functions
*
@verbatim
===============================================================================
##### Initialization and Configuration functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to initialize the USARTx or the UARTy
in asynchronous mode.
(+) For the asynchronous mode the parameters below can be configured:
(++) Baud Rate
(++) Word Length
(++) Stop Bit
(++) Parity: If the parity is enabled, then the MSB bit of the data written
in the data register is transmitted but is changed by the parity bit.
(++) Hardware flow control
(++) Receiver/transmitter modes
(++) Over Sampling Method
(++) One-Bit Sampling Method
(+) For the asynchronous mode, the following advanced features can be configured as well:
(++) TX and/or RX pin level inversion
(++) data logical level inversion
(++) RX and TX pins swap
(++) RX overrun detection disabling
(++) DMA disabling on RX error
(++) MSB first on communication line
(++) auto Baud rate detection
[..]
The HAL_UART_Init(), HAL_HalfDuplex_Init(), HAL_LIN_Init()and HAL_MultiProcessor_Init()API
follow respectively the UART asynchronous, UART Half duplex, UART LIN mode
and UART multiprocessor mode configuration procedures (details for the procedures
are available in reference manual).
@endverbatim
Depending on the frame length defined by the M1 and M0 bits (7-bit,
8-bit or 9-bit), the possible UART formats are listed in the
following table.
Table 1. UART frame format.
+-----------------------------------------------------------------------+
| M1 bit | M0 bit | PCE bit | UART frame |
|---------|---------|-----------|---------------------------------------|
| 0 | 0 | 0 | | SB | 8 bit data | STB | |
|---------|---------|-----------|---------------------------------------|
| 0 | 0 | 1 | | SB | 7 bit data | PB | STB | |
|---------|---------|-----------|---------------------------------------|
| 0 | 1 | 0 | | SB | 9 bit data | STB | |
|---------|---------|-----------|---------------------------------------|
| 0 | 1 | 1 | | SB | 8 bit data | PB | STB | |
|---------|---------|-----------|---------------------------------------|
| 1 | 0 | 0 | | SB | 7 bit data | STB | |
|---------|---------|-----------|---------------------------------------|
| 1 | 0 | 1 | | SB | 6 bit data | PB | STB | |
+-----------------------------------------------------------------------+
* @{
*/
/**
* @brief Initialize the UART mode according to the specified
* parameters in the UART_InitTypeDef and initialize the associated handle.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Init(UART_HandleTypeDef *huart)
{
/* Check the UART handle allocation */
if (huart == NULL)
{
return HAL_ERROR;
}
if (huart->Init.HwFlowCtl != UART_HWCONTROL_NONE)
{
/* Check the parameters */
assert_param(IS_UART_HWFLOW_INSTANCE(huart->Instance));
}
else
{
/* Check the parameters */
assert_param((IS_UART_INSTANCE(huart->Instance)) || (IS_LPUART_INSTANCE(huart->Instance)));
}
if (huart->gState == HAL_UART_STATE_RESET)
{
/* Allocate lock resource and initialize it */
huart->Lock = HAL_UNLOCKED;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
UART_InitCallbacksToDefault(huart);
if (huart->MspInitCallback == NULL)
{
huart->MspInitCallback = HAL_UART_MspInit;
}
/* Init the low level hardware */
huart->MspInitCallback(huart);
#else
/* Init the low level hardware : GPIO, CLOCK */
HAL_UART_MspInit(huart);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
huart->gState = HAL_UART_STATE_BUSY;
__HAL_UART_DISABLE(huart);
/* Perform advanced settings configuration */
/* For some items, configuration requires to be done prior TE and RE bits are set */
if (huart->AdvancedInit.AdvFeatureInit != UART_ADVFEATURE_NO_INIT)
{
UART_AdvFeatureConfig(huart);
}
/* Set the UART Communication parameters */
if (UART_SetConfig(huart) == HAL_ERROR)
{
return HAL_ERROR;
}
/* In asynchronous mode, the following bits must be kept cleared:
- LINEN and CLKEN bits in the USART_CR2 register,
- SCEN, HDSEL and IREN bits in the USART_CR3 register.*/
CLEAR_BIT(huart->Instance->CR2, (USART_CR2_LINEN | USART_CR2_CLKEN));
CLEAR_BIT(huart->Instance->CR3, (USART_CR3_SCEN | USART_CR3_HDSEL | USART_CR3_IREN));
__HAL_UART_ENABLE(huart);
/* TEACK and/or REACK to check before moving huart->gState and huart->RxState to Ready */
return (UART_CheckIdleState(huart));
}
/**
* @brief Initialize the half-duplex mode according to the specified
* parameters in the UART_InitTypeDef and creates the associated handle.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_HalfDuplex_Init(UART_HandleTypeDef *huart)
{
/* Check the UART handle allocation */
if (huart == NULL)
{
return HAL_ERROR;
}
/* Check UART instance */
assert_param(IS_UART_HALFDUPLEX_INSTANCE(huart->Instance));
if (huart->gState == HAL_UART_STATE_RESET)
{
/* Allocate lock resource and initialize it */
huart->Lock = HAL_UNLOCKED;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
UART_InitCallbacksToDefault(huart);
if (huart->MspInitCallback == NULL)
{
huart->MspInitCallback = HAL_UART_MspInit;
}
/* Init the low level hardware */
huart->MspInitCallback(huart);
#else
/* Init the low level hardware : GPIO, CLOCK */
HAL_UART_MspInit(huart);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
huart->gState = HAL_UART_STATE_BUSY;
__HAL_UART_DISABLE(huart);
/* Perform advanced settings configuration */
/* For some items, configuration requires to be done prior TE and RE bits are set */
if (huart->AdvancedInit.AdvFeatureInit != UART_ADVFEATURE_NO_INIT)
{
UART_AdvFeatureConfig(huart);
}
/* Set the UART Communication parameters */
if (UART_SetConfig(huart) == HAL_ERROR)
{
return HAL_ERROR;
}
/* In half-duplex mode, the following bits must be kept cleared:
- LINEN and CLKEN bits in the USART_CR2 register,
- SCEN and IREN bits in the USART_CR3 register.*/
CLEAR_BIT(huart->Instance->CR2, (USART_CR2_LINEN | USART_CR2_CLKEN));
CLEAR_BIT(huart->Instance->CR3, (USART_CR3_IREN | USART_CR3_SCEN));
/* Enable the Half-Duplex mode by setting the HDSEL bit in the CR3 register */
SET_BIT(huart->Instance->CR3, USART_CR3_HDSEL);
__HAL_UART_ENABLE(huart);
/* TEACK and/or REACK to check before moving huart->gState and huart->RxState to Ready */
return (UART_CheckIdleState(huart));
}
/**
* @brief Initialize the LIN mode according to the specified
* parameters in the UART_InitTypeDef and creates the associated handle.
* @param huart UART handle.
* @param BreakDetectLength Specifies the LIN break detection length.
* This parameter can be one of the following values:
* @arg @ref UART_LINBREAKDETECTLENGTH_10B 10-bit break detection
* @arg @ref UART_LINBREAKDETECTLENGTH_11B 11-bit break detection
* @retval HAL status
*/
HAL_StatusTypeDef HAL_LIN_Init(UART_HandleTypeDef *huart, uint32_t BreakDetectLength)
{
/* Check the UART handle allocation */
if (huart == NULL)
{
return HAL_ERROR;
}
/* Check the LIN UART instance */
assert_param(IS_UART_LIN_INSTANCE(huart->Instance));
/* Check the Break detection length parameter */
assert_param(IS_UART_LIN_BREAK_DETECT_LENGTH(BreakDetectLength));
/* LIN mode limited to 16-bit oversampling only */
if (huart->Init.OverSampling == UART_OVERSAMPLING_8)
{
return HAL_ERROR;
}
/* LIN mode limited to 8-bit data length */
if (huart->Init.WordLength != UART_WORDLENGTH_8B)
{
return HAL_ERROR;
}
if (huart->gState == HAL_UART_STATE_RESET)
{
/* Allocate lock resource and initialize it */
huart->Lock = HAL_UNLOCKED;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
UART_InitCallbacksToDefault(huart);
if (huart->MspInitCallback == NULL)
{
huart->MspInitCallback = HAL_UART_MspInit;
}
/* Init the low level hardware */
huart->MspInitCallback(huart);
#else
/* Init the low level hardware : GPIO, CLOCK */
HAL_UART_MspInit(huart);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
huart->gState = HAL_UART_STATE_BUSY;
__HAL_UART_DISABLE(huart);
/* Perform advanced settings configuration */
/* For some items, configuration requires to be done prior TE and RE bits are set */
if (huart->AdvancedInit.AdvFeatureInit != UART_ADVFEATURE_NO_INIT)
{
UART_AdvFeatureConfig(huart);
}
/* Set the UART Communication parameters */
if (UART_SetConfig(huart) == HAL_ERROR)
{
return HAL_ERROR;
}
/* In LIN mode, the following bits must be kept cleared:
- LINEN and CLKEN bits in the USART_CR2 register,
- SCEN and IREN bits in the USART_CR3 register.*/
CLEAR_BIT(huart->Instance->CR2, USART_CR2_CLKEN);
CLEAR_BIT(huart->Instance->CR3, (USART_CR3_HDSEL | USART_CR3_IREN | USART_CR3_SCEN));
/* Enable the LIN mode by setting the LINEN bit in the CR2 register */
SET_BIT(huart->Instance->CR2, USART_CR2_LINEN);
/* Set the USART LIN Break detection length. */
MODIFY_REG(huart->Instance->CR2, USART_CR2_LBDL, BreakDetectLength);
__HAL_UART_ENABLE(huart);
/* TEACK and/or REACK to check before moving huart->gState and huart->RxState to Ready */
return (UART_CheckIdleState(huart));
}
/**
* @brief Initialize the multiprocessor mode according to the specified
* parameters in the UART_InitTypeDef and initialize the associated handle.
* @param huart UART handle.
* @param Address UART node address (4-, 6-, 7- or 8-bit long).
* @param WakeUpMethod Specifies the UART wakeup method.
* This parameter can be one of the following values:
* @arg @ref UART_WAKEUPMETHOD_IDLELINE WakeUp by an idle line detection
* @arg @ref UART_WAKEUPMETHOD_ADDRESSMARK WakeUp by an address mark
* @note If the user resorts to idle line detection wake up, the Address parameter
* is useless and ignored by the initialization function.
* @note If the user resorts to address mark wake up, the address length detection
* is configured by default to 4 bits only. For the UART to be able to
* manage 6-, 7- or 8-bit long addresses detection, the API
* HAL_MultiProcessorEx_AddressLength_Set() must be called after
* HAL_MultiProcessor_Init().
* @retval HAL status
*/
HAL_StatusTypeDef HAL_MultiProcessor_Init(UART_HandleTypeDef *huart, uint8_t Address, uint32_t WakeUpMethod)
{
/* Check the UART handle allocation */
if (huart == NULL)
{
return HAL_ERROR;
}
/* Check the wake up method parameter */
assert_param(IS_UART_WAKEUPMETHOD(WakeUpMethod));
if (huart->gState == HAL_UART_STATE_RESET)
{
/* Allocate lock resource and initialize it */
huart->Lock = HAL_UNLOCKED;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
UART_InitCallbacksToDefault(huart);
if (huart->MspInitCallback == NULL)
{
huart->MspInitCallback = HAL_UART_MspInit;
}
/* Init the low level hardware */
huart->MspInitCallback(huart);
#else
/* Init the low level hardware : GPIO, CLOCK */
HAL_UART_MspInit(huart);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
huart->gState = HAL_UART_STATE_BUSY;
__HAL_UART_DISABLE(huart);
/* Perform advanced settings configuration */
/* For some items, configuration requires to be done prior TE and RE bits are set */
if (huart->AdvancedInit.AdvFeatureInit != UART_ADVFEATURE_NO_INIT)
{
UART_AdvFeatureConfig(huart);
}
/* Set the UART Communication parameters */
if (UART_SetConfig(huart) == HAL_ERROR)
{
return HAL_ERROR;
}
/* In multiprocessor mode, the following bits must be kept cleared:
- LINEN and CLKEN bits in the USART_CR2 register,
- SCEN, HDSEL and IREN bits in the USART_CR3 register. */
CLEAR_BIT(huart->Instance->CR2, (USART_CR2_LINEN | USART_CR2_CLKEN));
CLEAR_BIT(huart->Instance->CR3, (USART_CR3_SCEN | USART_CR3_HDSEL | USART_CR3_IREN));
if (WakeUpMethod == UART_WAKEUPMETHOD_ADDRESSMARK)
{
/* If address mark wake up method is chosen, set the USART address node */
MODIFY_REG(huart->Instance->CR2, USART_CR2_ADD, ((uint32_t)Address << UART_CR2_ADDRESS_LSB_POS));
}
/* Set the wake up method by setting the WAKE bit in the CR1 register */
MODIFY_REG(huart->Instance->CR1, USART_CR1_WAKE, WakeUpMethod);
__HAL_UART_ENABLE(huart);
/* TEACK and/or REACK to check before moving huart->gState and huart->RxState to Ready */
return (UART_CheckIdleState(huart));
}
/**
* @brief DeInitialize the UART peripheral.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_DeInit(UART_HandleTypeDef *huart)
{
/* Check the UART handle allocation */
if (huart == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param((IS_UART_INSTANCE(huart->Instance)) || (IS_LPUART_INSTANCE(huart->Instance)));
huart->gState = HAL_UART_STATE_BUSY;
__HAL_UART_DISABLE(huart);
huart->Instance->CR1 = 0x0U;
huart->Instance->CR2 = 0x0U;
huart->Instance->CR3 = 0x0U;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
if (huart->MspDeInitCallback == NULL)
{
huart->MspDeInitCallback = HAL_UART_MspDeInit;
}
/* DeInit the low level hardware */
huart->MspDeInitCallback(huart);
#else
/* DeInit the low level hardware */
HAL_UART_MspDeInit(huart);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->gState = HAL_UART_STATE_RESET;
huart->RxState = HAL_UART_STATE_RESET;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
huart->RxEventType = HAL_UART_RXEVENT_TC;
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Initialize the UART MSP.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_MspInit(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_MspInit can be implemented in the user file
*/
}
/**
* @brief DeInitialize the UART MSP.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_MspDeInit(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_MspDeInit can be implemented in the user file
*/
}
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/**
* @brief Register a User UART Callback
* To be used to override the weak predefined callback
* @note The HAL_UART_RegisterCallback() may be called before HAL_UART_Init(), HAL_HalfDuplex_Init(),
* HAL_LIN_Init(), HAL_MultiProcessor_Init() or HAL_RS485Ex_Init() in HAL_UART_STATE_RESET to register
* callbacks for HAL_UART_MSPINIT_CB_ID and HAL_UART_MSPDEINIT_CB_ID
* @param huart uart handle
* @param CallbackID ID of the callback to be registered
* This parameter can be one of the following values:
* @arg @ref HAL_UART_TX_HALFCOMPLETE_CB_ID Tx Half Complete Callback ID
* @arg @ref HAL_UART_TX_COMPLETE_CB_ID Tx Complete Callback ID
* @arg @ref HAL_UART_RX_HALFCOMPLETE_CB_ID Rx Half Complete Callback ID
* @arg @ref HAL_UART_RX_COMPLETE_CB_ID Rx Complete Callback ID
* @arg @ref HAL_UART_ERROR_CB_ID Error Callback ID
* @arg @ref HAL_UART_ABORT_COMPLETE_CB_ID Abort Complete Callback ID
* @arg @ref HAL_UART_ABORT_TRANSMIT_COMPLETE_CB_ID Abort Transmit Complete Callback ID
* @arg @ref HAL_UART_ABORT_RECEIVE_COMPLETE_CB_ID Abort Receive Complete Callback ID
* @arg @ref HAL_UART_WAKEUP_CB_ID Wakeup Callback ID
* @arg @ref HAL_UART_RX_FIFO_FULL_CB_ID Rx Fifo Full Callback ID
* @arg @ref HAL_UART_TX_FIFO_EMPTY_CB_ID Tx Fifo Empty Callback ID
* @arg @ref HAL_UART_MSPINIT_CB_ID MspInit Callback ID
* @arg @ref HAL_UART_MSPDEINIT_CB_ID MspDeInit Callback ID
* @param pCallback pointer to the Callback function
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_RegisterCallback(UART_HandleTypeDef *huart, HAL_UART_CallbackIDTypeDef CallbackID,
pUART_CallbackTypeDef pCallback)
{
HAL_StatusTypeDef status = HAL_OK;
if (pCallback == NULL)
{
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
return HAL_ERROR;
}
if (huart->gState == HAL_UART_STATE_READY)
{
switch (CallbackID)
{
case HAL_UART_TX_HALFCOMPLETE_CB_ID :
huart->TxHalfCpltCallback = pCallback;
break;
case HAL_UART_TX_COMPLETE_CB_ID :
huart->TxCpltCallback = pCallback;
break;
case HAL_UART_RX_HALFCOMPLETE_CB_ID :
huart->RxHalfCpltCallback = pCallback;
break;
case HAL_UART_RX_COMPLETE_CB_ID :
huart->RxCpltCallback = pCallback;
break;
case HAL_UART_ERROR_CB_ID :
huart->ErrorCallback = pCallback;
break;
case HAL_UART_ABORT_COMPLETE_CB_ID :
huart->AbortCpltCallback = pCallback;
break;
case HAL_UART_ABORT_TRANSMIT_COMPLETE_CB_ID :
huart->AbortTransmitCpltCallback = pCallback;
break;
case HAL_UART_ABORT_RECEIVE_COMPLETE_CB_ID :
huart->AbortReceiveCpltCallback = pCallback;
break;
case HAL_UART_WAKEUP_CB_ID :
huart->WakeupCallback = pCallback;
break;
case HAL_UART_RX_FIFO_FULL_CB_ID :
huart->RxFifoFullCallback = pCallback;
break;
case HAL_UART_TX_FIFO_EMPTY_CB_ID :
huart->TxFifoEmptyCallback = pCallback;
break;
case HAL_UART_MSPINIT_CB_ID :
huart->MspInitCallback = pCallback;
break;
case HAL_UART_MSPDEINIT_CB_ID :
huart->MspDeInitCallback = pCallback;
break;
default :
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
break;
}
}
else if (huart->gState == HAL_UART_STATE_RESET)
{
switch (CallbackID)
{
case HAL_UART_MSPINIT_CB_ID :
huart->MspInitCallback = pCallback;
break;
case HAL_UART_MSPDEINIT_CB_ID :
huart->MspDeInitCallback = pCallback;
break;
default :
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
break;
}
}
else
{
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
}
return status;
}
/**
* @brief Unregister an UART Callback
* UART callaback is redirected to the weak predefined callback
* @note The HAL_UART_UnRegisterCallback() may be called before HAL_UART_Init(), HAL_HalfDuplex_Init(),
* HAL_LIN_Init(), HAL_MultiProcessor_Init() or HAL_RS485Ex_Init() in HAL_UART_STATE_RESET to un-register
* callbacks for HAL_UART_MSPINIT_CB_ID and HAL_UART_MSPDEINIT_CB_ID
* @param huart uart handle
* @param CallbackID ID of the callback to be unregistered
* This parameter can be one of the following values:
* @arg @ref HAL_UART_TX_HALFCOMPLETE_CB_ID Tx Half Complete Callback ID
* @arg @ref HAL_UART_TX_COMPLETE_CB_ID Tx Complete Callback ID
* @arg @ref HAL_UART_RX_HALFCOMPLETE_CB_ID Rx Half Complete Callback ID
* @arg @ref HAL_UART_RX_COMPLETE_CB_ID Rx Complete Callback ID
* @arg @ref HAL_UART_ERROR_CB_ID Error Callback ID
* @arg @ref HAL_UART_ABORT_COMPLETE_CB_ID Abort Complete Callback ID
* @arg @ref HAL_UART_ABORT_TRANSMIT_COMPLETE_CB_ID Abort Transmit Complete Callback ID
* @arg @ref HAL_UART_ABORT_RECEIVE_COMPLETE_CB_ID Abort Receive Complete Callback ID
* @arg @ref HAL_UART_WAKEUP_CB_ID Wakeup Callback ID
* @arg @ref HAL_UART_RX_FIFO_FULL_CB_ID Rx Fifo Full Callback ID
* @arg @ref HAL_UART_TX_FIFO_EMPTY_CB_ID Tx Fifo Empty Callback ID
* @arg @ref HAL_UART_MSPINIT_CB_ID MspInit Callback ID
* @arg @ref HAL_UART_MSPDEINIT_CB_ID MspDeInit Callback ID
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_UnRegisterCallback(UART_HandleTypeDef *huart, HAL_UART_CallbackIDTypeDef CallbackID)
{
HAL_StatusTypeDef status = HAL_OK;
if (HAL_UART_STATE_READY == huart->gState)
{
switch (CallbackID)
{
case HAL_UART_TX_HALFCOMPLETE_CB_ID :
huart->TxHalfCpltCallback = HAL_UART_TxHalfCpltCallback; /* Legacy weak TxHalfCpltCallback */
break;
case HAL_UART_TX_COMPLETE_CB_ID :
huart->TxCpltCallback = HAL_UART_TxCpltCallback; /* Legacy weak TxCpltCallback */
break;
case HAL_UART_RX_HALFCOMPLETE_CB_ID :
huart->RxHalfCpltCallback = HAL_UART_RxHalfCpltCallback; /* Legacy weak RxHalfCpltCallback */
break;
case HAL_UART_RX_COMPLETE_CB_ID :
huart->RxCpltCallback = HAL_UART_RxCpltCallback; /* Legacy weak RxCpltCallback */
break;
case HAL_UART_ERROR_CB_ID :
huart->ErrorCallback = HAL_UART_ErrorCallback; /* Legacy weak ErrorCallback */
break;
case HAL_UART_ABORT_COMPLETE_CB_ID :
huart->AbortCpltCallback = HAL_UART_AbortCpltCallback; /* Legacy weak AbortCpltCallback */
break;
case HAL_UART_ABORT_TRANSMIT_COMPLETE_CB_ID :
huart->AbortTransmitCpltCallback = HAL_UART_AbortTransmitCpltCallback; /* Legacy weak
AbortTransmitCpltCallback */
break;
case HAL_UART_ABORT_RECEIVE_COMPLETE_CB_ID :
huart->AbortReceiveCpltCallback = HAL_UART_AbortReceiveCpltCallback; /* Legacy weak
AbortReceiveCpltCallback */
break;
case HAL_UART_WAKEUP_CB_ID :
huart->WakeupCallback = HAL_UARTEx_WakeupCallback; /* Legacy weak WakeupCallback */
break;
case HAL_UART_RX_FIFO_FULL_CB_ID :
huart->RxFifoFullCallback = HAL_UARTEx_RxFifoFullCallback; /* Legacy weak RxFifoFullCallback */
break;
case HAL_UART_TX_FIFO_EMPTY_CB_ID :
huart->TxFifoEmptyCallback = HAL_UARTEx_TxFifoEmptyCallback; /* Legacy weak TxFifoEmptyCallback */
break;
case HAL_UART_MSPINIT_CB_ID :
huart->MspInitCallback = HAL_UART_MspInit; /* Legacy weak MspInitCallback */
break;
case HAL_UART_MSPDEINIT_CB_ID :
huart->MspDeInitCallback = HAL_UART_MspDeInit; /* Legacy weak MspDeInitCallback */
break;
default :
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
break;
}
}
else if (HAL_UART_STATE_RESET == huart->gState)
{
switch (CallbackID)
{
case HAL_UART_MSPINIT_CB_ID :
huart->MspInitCallback = HAL_UART_MspInit;
break;
case HAL_UART_MSPDEINIT_CB_ID :
huart->MspDeInitCallback = HAL_UART_MspDeInit;
break;
default :
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
break;
}
}
else
{
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
}
return status;
}
/**
* @brief Register a User UART Rx Event Callback
* To be used instead of the weak predefined callback
* @param huart Uart handle
* @param pCallback Pointer to the Rx Event Callback function
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_RegisterRxEventCallback(UART_HandleTypeDef *huart, pUART_RxEventCallbackTypeDef pCallback)
{
HAL_StatusTypeDef status = HAL_OK;
if (pCallback == NULL)
{
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
return HAL_ERROR;
}
if (huart->RxState == HAL_UART_STATE_READY)
{
huart->RxEventCallback = pCallback;
}
else
{
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
}
return status;
}
/**
* @brief UnRegister the UART Rx Event Callback
* UART Rx Event Callback is redirected to the weak HAL_UARTEx_RxEventCallback() predefined callback
* @param huart Uart handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_UnRegisterRxEventCallback(UART_HandleTypeDef *huart)
{
HAL_StatusTypeDef status = HAL_OK;
if (huart->RxState == HAL_UART_STATE_READY)
{
huart->RxEventCallback = HAL_UARTEx_RxEventCallback; /* Legacy weak UART Rx Event Callback */
}
else
{
huart->ErrorCode |= HAL_UART_ERROR_INVALID_CALLBACK;
status = HAL_ERROR;
}
return status;
}
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
/**
* @}
*/
/** @defgroup UART_Exported_Functions_Group2 IO operation functions
* @brief UART Transmit/Receive functions
*
@verbatim
===============================================================================
##### IO operation functions #####
===============================================================================
This subsection provides a set of functions allowing to manage the UART asynchronous
and Half duplex data transfers.
(#) There are two mode of transfer:
(+) Blocking mode: The communication is performed in polling mode.
The HAL status of all data processing is returned by the same function
after finishing transfer.
(+) Non-Blocking mode: The communication is performed using Interrupts
or DMA, These API's return the HAL status.
The end of the data processing will be indicated through the
dedicated UART IRQ when using Interrupt mode or the DMA IRQ when
using DMA mode.
The HAL_UART_TxCpltCallback(), HAL_UART_RxCpltCallback() user callbacks
will be executed respectively at the end of the transmit or Receive process
The HAL_UART_ErrorCallback()user callback will be executed when a communication error is detected
(#) Blocking mode API's are :
(+) HAL_UART_Transmit()
(+) HAL_UART_Receive()
(#) Non-Blocking mode API's with Interrupt are :
(+) HAL_UART_Transmit_IT()
(+) HAL_UART_Receive_IT()
(+) HAL_UART_IRQHandler()
(#) Non-Blocking mode API's with DMA are :
(+) HAL_UART_Transmit_DMA()
(+) HAL_UART_Receive_DMA()
(+) HAL_UART_DMAPause()
(+) HAL_UART_DMAResume()
(+) HAL_UART_DMAStop()
(#) A set of Transfer Complete Callbacks are provided in Non_Blocking mode:
(+) HAL_UART_TxHalfCpltCallback()
(+) HAL_UART_TxCpltCallback()
(+) HAL_UART_RxHalfCpltCallback()
(+) HAL_UART_RxCpltCallback()
(+) HAL_UART_ErrorCallback()
(#) Non-Blocking mode transfers could be aborted using Abort API's :
(+) HAL_UART_Abort()
(+) HAL_UART_AbortTransmit()
(+) HAL_UART_AbortReceive()
(+) HAL_UART_Abort_IT()
(+) HAL_UART_AbortTransmit_IT()
(+) HAL_UART_AbortReceive_IT()
(#) For Abort services based on interrupts (HAL_UART_Abortxxx_IT), a set of Abort Complete Callbacks are provided:
(+) HAL_UART_AbortCpltCallback()
(+) HAL_UART_AbortTransmitCpltCallback()
(+) HAL_UART_AbortReceiveCpltCallback()
(#) A Rx Event Reception Callback (Rx event notification) is available for Non_Blocking modes of enhanced
reception services:
(+) HAL_UARTEx_RxEventCallback()
(#) In Non-Blocking mode transfers, possible errors are split into 2 categories.
Errors are handled as follows :
(+) Error is considered as Recoverable and non blocking : Transfer could go till end, but error severity is
to be evaluated by user : this concerns Frame Error, Parity Error or Noise Error
in Interrupt mode reception .
Received character is then retrieved and stored in Rx buffer, Error code is set to allow user
to identify error type, and HAL_UART_ErrorCallback() user callback is executed.
Transfer is kept ongoing on UART side.
If user wants to abort it, Abort services should be called by user.
(+) Error is considered as Blocking : Transfer could not be completed properly and is aborted.
This concerns Overrun Error In Interrupt mode reception and all errors in DMA mode.
Error code is set to allow user to identify error type, and HAL_UART_ErrorCallback()
user callback is executed.
-@- In the Half duplex communication, it is forbidden to run the transmit
and receive process in parallel, the UART state HAL_UART_STATE_BUSY_TX_RX can't be useful.
@endverbatim
* @{
*/
/**
* @brief Send an amount of data in blocking mode.
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the sent data is handled as a set of u16. In this case, Size must indicate the number
* of u16 provided through pData.
* @note When FIFO mode is enabled, writing a data in the TDR register adds one
* data to the TXFIFO. Write operations to the TDR register are performed
* when TXFNF flag is set. From hardware perspective, TXFNF flag and
* TXE are mapped on the same bit-field.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be sent.
* @param Timeout Timeout duration.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Transmit(UART_HandleTypeDef *huart, const uint8_t *pData, uint16_t Size, uint32_t Timeout)
{
const uint8_t *pdata8bits;
const uint16_t *pdata16bits;
uint32_t tickstart;
/* Check that a Tx process is not already ongoing */
if (huart->gState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->gState = HAL_UART_STATE_BUSY_TX;
/* Init tickstart for timeout management */
tickstart = HAL_GetTick();
huart->TxXferSize = Size;
huart->TxXferCount = Size;
/* In case of 9bits/No Parity transfer, pData needs to be handled as a uint16_t pointer */
if ((huart->Init.WordLength == UART_WORDLENGTH_9B) && (huart->Init.Parity == UART_PARITY_NONE))
{
pdata8bits = NULL;
pdata16bits = (const uint16_t *) pData;
}
else
{
pdata8bits = pData;
pdata16bits = NULL;
}
while (huart->TxXferCount > 0U)
{
if (UART_WaitOnFlagUntilTimeout(huart, UART_FLAG_TXE, RESET, tickstart, Timeout) != HAL_OK)
{
huart->gState = HAL_UART_STATE_READY;
return HAL_TIMEOUT;
}
if (pdata8bits == NULL)
{
huart->Instance->TDR = (uint16_t)(*pdata16bits & 0x01FFU);
pdata16bits++;
}
else
{
huart->Instance->TDR = (uint8_t)(*pdata8bits & 0xFFU);
pdata8bits++;
}
huart->TxXferCount--;
}
if (UART_WaitOnFlagUntilTimeout(huart, UART_FLAG_TC, RESET, tickstart, Timeout) != HAL_OK)
{
huart->gState = HAL_UART_STATE_READY;
return HAL_TIMEOUT;
}
/* At end of Tx process, restore huart->gState to Ready */
huart->gState = HAL_UART_STATE_READY;
return HAL_OK;
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Receive an amount of data in blocking mode.
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the received data is handled as a set of u16. In this case, Size must indicate the number
* of u16 available through pData.
* @note When FIFO mode is enabled, the RXFNE flag is set as long as the RXFIFO
* is not empty. Read operations from the RDR register are performed when
* RXFNE flag is set. From hardware perspective, RXFNE flag and
* RXNE are mapped on the same bit-field.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be received.
* @param Timeout Timeout duration.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Receive(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size, uint32_t Timeout)
{
uint8_t *pdata8bits;
uint16_t *pdata16bits;
uint16_t uhMask;
uint32_t tickstart;
/* Check that a Rx process is not already ongoing */
if (huart->RxState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->RxState = HAL_UART_STATE_BUSY_RX;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Init tickstart for timeout management */
tickstart = HAL_GetTick();
huart->RxXferSize = Size;
huart->RxXferCount = Size;
/* Computation of UART mask to apply to RDR register */
UART_MASK_COMPUTATION(huart);
uhMask = huart->Mask;
/* In case of 9bits/No Parity transfer, pRxData needs to be handled as a uint16_t pointer */
if ((huart->Init.WordLength == UART_WORDLENGTH_9B) && (huart->Init.Parity == UART_PARITY_NONE))
{
pdata8bits = NULL;
pdata16bits = (uint16_t *) pData;
}
else
{
pdata8bits = pData;
pdata16bits = NULL;
}
/* as long as data have to be received */
while (huart->RxXferCount > 0U)
{
if (UART_WaitOnFlagUntilTimeout(huart, UART_FLAG_RXNE, RESET, tickstart, Timeout) != HAL_OK)
{
huart->RxState = HAL_UART_STATE_READY;
return HAL_TIMEOUT;
}
if (pdata8bits == NULL)
{
*pdata16bits = (uint16_t)(huart->Instance->RDR & uhMask);
pdata16bits++;
}
else
{
*pdata8bits = (uint8_t)(huart->Instance->RDR & (uint8_t)uhMask);
pdata8bits++;
}
huart->RxXferCount--;
}
/* At end of Rx process, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
return HAL_OK;
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Send an amount of data in interrupt mode.
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the sent data is handled as a set of u16. In this case, Size must indicate the number
* of u16 provided through pData.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be sent.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Transmit_IT(UART_HandleTypeDef *huart, const uint8_t *pData, uint16_t Size)
{
/* Check that a Tx process is not already ongoing */
if (huart->gState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
huart->pTxBuffPtr = pData;
huart->TxXferSize = Size;
huart->TxXferCount = Size;
huart->TxISR = NULL;
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->gState = HAL_UART_STATE_BUSY_TX;
/* Configure Tx interrupt processing */
if (huart->FifoMode == UART_FIFOMODE_ENABLE)
{
/* Set the Tx ISR function pointer according to the data word length */
if ((huart->Init.WordLength == UART_WORDLENGTH_9B) && (huart->Init.Parity == UART_PARITY_NONE))
{
huart->TxISR = UART_TxISR_16BIT_FIFOEN;
}
else
{
huart->TxISR = UART_TxISR_8BIT_FIFOEN;
}
/* Enable the TX FIFO threshold interrupt */
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_TXFTIE);
}
else
{
/* Set the Tx ISR function pointer according to the data word length */
if ((huart->Init.WordLength == UART_WORDLENGTH_9B) && (huart->Init.Parity == UART_PARITY_NONE))
{
huart->TxISR = UART_TxISR_16BIT;
}
else
{
huart->TxISR = UART_TxISR_8BIT;
}
/* Enable the Transmit Data Register Empty interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_TXEIE_TXFNFIE);
}
return HAL_OK;
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Receive an amount of data in interrupt mode.
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the received data is handled as a set of u16. In this case, Size must indicate the number
* of u16 available through pData.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be received.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Receive_IT(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size)
{
/* Check that a Rx process is not already ongoing */
if (huart->RxState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
/* Set Reception type to Standard reception */
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
/* Check that USART RTOEN bit is set */
if (READ_BIT(huart->Instance->CR2, USART_CR2_RTOEN) != 0U)
{
/* Enable the UART Receiver Timeout Interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_RTOIE);
}
}
return (UART_Start_Receive_IT(huart, pData, Size));
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Send an amount of data in DMA mode.
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the sent data is handled as a set of u16. In this case, Size must indicate the number
* of u16 provided through pData.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be sent.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Transmit_DMA(UART_HandleTypeDef *huart, const uint8_t *pData, uint16_t Size)
{
/* Check that a Tx process is not already ongoing */
if (huart->gState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
huart->pTxBuffPtr = pData;
huart->TxXferSize = Size;
huart->TxXferCount = Size;
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->gState = HAL_UART_STATE_BUSY_TX;
if (huart->hdmatx != NULL)
{
/* Set the UART DMA transfer complete callback */
huart->hdmatx->XferCpltCallback = UART_DMATransmitCplt;
/* Set the UART DMA Half transfer complete callback */
huart->hdmatx->XferHalfCpltCallback = UART_DMATxHalfCplt;
/* Set the DMA error callback */
huart->hdmatx->XferErrorCallback = UART_DMAError;
/* Set the DMA abort callback */
huart->hdmatx->XferAbortCallback = NULL;
/* Enable the UART transmit DMA channel */
if (HAL_DMA_Start_IT(huart->hdmatx, (uint32_t)huart->pTxBuffPtr, (uint32_t)&huart->Instance->TDR, Size) != HAL_OK)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
/* Restore huart->gState to ready */
huart->gState = HAL_UART_STATE_READY;
return HAL_ERROR;
}
}
/* Clear the TC flag in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_TCF);
/* Enable the DMA transfer for transmit request by setting the DMAT bit
in the UART CR3 register */
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_DMAT);
return HAL_OK;
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Receive an amount of data in DMA mode.
* @note When the UART parity is enabled (PCE = 1), the received data contain
* the parity bit (MSB position).
* @note When UART parity is not enabled (PCE = 0), and Word Length is configured to 9 bits (M1-M0 = 01),
* the received data is handled as a set of u16. In this case, Size must indicate the number
* of u16 available through pData.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be received.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Receive_DMA(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size)
{
/* Check that a Rx process is not already ongoing */
if (huart->RxState == HAL_UART_STATE_READY)
{
if ((pData == NULL) || (Size == 0U))
{
return HAL_ERROR;
}
/* Set Reception type to Standard reception */
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
/* Check that USART RTOEN bit is set */
if (READ_BIT(huart->Instance->CR2, USART_CR2_RTOEN) != 0U)
{
/* Enable the UART Receiver Timeout Interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_RTOIE);
}
}
return (UART_Start_Receive_DMA(huart, pData, Size));
}
else
{
return HAL_BUSY;
}
}
/**
* @brief Pause the DMA Transfer.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_DMAPause(UART_HandleTypeDef *huart)
{
const HAL_UART_StateTypeDef gstate = huart->gState;
const HAL_UART_StateTypeDef rxstate = huart->RxState;
if ((HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT)) &&
(gstate == HAL_UART_STATE_BUSY_TX))
{
/* Disable the UART DMA Tx request */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAT);
}
if ((HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR)) &&
(rxstate == HAL_UART_STATE_BUSY_RX))
{
/* Disable PE and ERR (Frame error, noise error, overrun error) interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_PEIE);
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Disable the UART DMA Rx request */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
}
return HAL_OK;
}
/**
* @brief Resume the DMA Transfer.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_DMAResume(UART_HandleTypeDef *huart)
{
if (huart->gState == HAL_UART_STATE_BUSY_TX)
{
/* Enable the UART DMA Tx request */
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_DMAT);
}
if (huart->RxState == HAL_UART_STATE_BUSY_RX)
{
/* Clear the Overrun flag before resuming the Rx transfer */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF);
/* Re-enable PE and ERR (Frame error, noise error, overrun error) interrupts */
if (huart->Init.Parity != UART_PARITY_NONE)
{
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_PEIE);
}
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Enable the UART DMA Rx request */
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_DMAR);
}
return HAL_OK;
}
/**
* @brief Stop the DMA Transfer.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_DMAStop(UART_HandleTypeDef *huart)
{
/* The Lock is not implemented on this API to allow the user application
to call the HAL UART API under callbacks HAL_UART_TxCpltCallback() / HAL_UART_RxCpltCallback() /
HAL_UART_TxHalfCpltCallback / HAL_UART_RxHalfCpltCallback:
indeed, when HAL_DMA_Abort() API is called, the DMA TX/RX Transfer or Half Transfer complete
interrupt is generated if the DMA transfer interruption occurs at the middle or at the end of
the stream and the corresponding call back is executed. */
const HAL_UART_StateTypeDef gstate = huart->gState;
const HAL_UART_StateTypeDef rxstate = huart->RxState;
/* Stop UART DMA Tx request if ongoing */
if ((HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT)) &&
(gstate == HAL_UART_STATE_BUSY_TX))
{
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAT);
/* Abort the UART DMA Tx channel */
if (huart->hdmatx != NULL)
{
if (HAL_DMA_Abort(huart->hdmatx) != HAL_OK)
{
if (HAL_DMA_GetError(huart->hdmatx) == HAL_DMA_ERROR_TIMEOUT)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
return HAL_TIMEOUT;
}
}
}
UART_EndTxTransfer(huart);
}
/* Stop UART DMA Rx request if ongoing */
if ((HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR)) &&
(rxstate == HAL_UART_STATE_BUSY_RX))
{
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* Abort the UART DMA Rx channel */
if (huart->hdmarx != NULL)
{
if (HAL_DMA_Abort(huart->hdmarx) != HAL_OK)
{
if (HAL_DMA_GetError(huart->hdmarx) == HAL_DMA_ERROR_TIMEOUT)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
return HAL_TIMEOUT;
}
}
}
UART_EndRxTransfer(huart);
}
return HAL_OK;
}
/**
* @brief Abort ongoing transfers (blocking mode).
* @param huart UART handle.
* @note This procedure could be used for aborting any ongoing transfer started in Interrupt or DMA mode.
* This procedure performs following operations :
* - Disable UART Interrupts (Tx and Rx)
* - Disable the DMA transfer in the peripheral register (if enabled)
* - Abort DMA transfer by calling HAL_DMA_Abort (in case of transfer in DMA mode)
* - Set handle State to READY
* @note This procedure is executed in blocking mode : when exiting function, Abort is considered as completed.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Abort(UART_HandleTypeDef *huart)
{
/* Disable TXE, TC, RXNE, PE, RXFT, TXFT and ERR (Frame error, noise error, overrun error) interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_RXNEIE_RXFNEIE | USART_CR1_PEIE |
USART_CR1_TXEIE_TXFNFIE | USART_CR1_TCIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE | USART_CR3_RXFTIE | USART_CR3_TXFTIE);
/* If Reception till IDLE event was ongoing, disable IDLEIE interrupt */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_IDLEIE));
}
/* Abort the UART DMA Tx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT))
{
/* Disable the UART DMA Tx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAT);
/* Abort the UART DMA Tx channel : use blocking DMA Abort API (no callback) */
if (huart->hdmatx != NULL)
{
/* Set the UART DMA Abort callback to Null.
No call back execution at end of DMA abort procedure */
huart->hdmatx->XferAbortCallback = NULL;
if (HAL_DMA_Abort(huart->hdmatx) != HAL_OK)
{
if (HAL_DMA_GetError(huart->hdmatx) == HAL_DMA_ERROR_TIMEOUT)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
return HAL_TIMEOUT;
}
}
}
}
/* Abort the UART DMA Rx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR))
{
/* Disable the UART DMA Rx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* Abort the UART DMA Rx channel : use blocking DMA Abort API (no callback) */
if (huart->hdmarx != NULL)
{
/* Set the UART DMA Abort callback to Null.
No call back execution at end of DMA abort procedure */
huart->hdmarx->XferAbortCallback = NULL;
if (HAL_DMA_Abort(huart->hdmarx) != HAL_OK)
{
if (HAL_DMA_GetError(huart->hdmarx) == HAL_DMA_ERROR_TIMEOUT)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
return HAL_TIMEOUT;
}
}
}
}
/* Reset Tx and Rx transfer counters */
huart->TxXferCount = 0U;
huart->RxXferCount = 0U;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Flush the whole TX FIFO (if needed) */
if (huart->FifoMode == UART_FIFOMODE_ENABLE)
{
__HAL_UART_SEND_REQ(huart, UART_TXDATA_FLUSH_REQUEST);
}
/* Discard the received data */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
/* Restore huart->gState and huart->RxState to Ready */
huart->gState = HAL_UART_STATE_READY;
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
huart->ErrorCode = HAL_UART_ERROR_NONE;
return HAL_OK;
}
/**
* @brief Abort ongoing Transmit transfer (blocking mode).
* @param huart UART handle.
* @note This procedure could be used for aborting any ongoing Tx transfer started in Interrupt or DMA mode.
* This procedure performs following operations :
* - Disable UART Interrupts (Tx)
* - Disable the DMA transfer in the peripheral register (if enabled)
* - Abort DMA transfer by calling HAL_DMA_Abort (in case of transfer in DMA mode)
* - Set handle State to READY
* @note This procedure is executed in blocking mode : when exiting function, Abort is considered as completed.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_AbortTransmit(UART_HandleTypeDef *huart)
{
/* Disable TCIE, TXEIE and TXFTIE interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_TCIE | USART_CR1_TXEIE_TXFNFIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_TXFTIE);
/* Abort the UART DMA Tx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT))
{
/* Disable the UART DMA Tx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAT);
/* Abort the UART DMA Tx channel : use blocking DMA Abort API (no callback) */
if (huart->hdmatx != NULL)
{
/* Set the UART DMA Abort callback to Null.
No call back execution at end of DMA abort procedure */
huart->hdmatx->XferAbortCallback = NULL;
if (HAL_DMA_Abort(huart->hdmatx) != HAL_OK)
{
if (HAL_DMA_GetError(huart->hdmatx) == HAL_DMA_ERROR_TIMEOUT)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
return HAL_TIMEOUT;
}
}
}
}
/* Reset Tx transfer counter */
huart->TxXferCount = 0U;
/* Flush the whole TX FIFO (if needed) */
if (huart->FifoMode == UART_FIFOMODE_ENABLE)
{
__HAL_UART_SEND_REQ(huart, UART_TXDATA_FLUSH_REQUEST);
}
/* Restore huart->gState to Ready */
huart->gState = HAL_UART_STATE_READY;
return HAL_OK;
}
/**
* @brief Abort ongoing Receive transfer (blocking mode).
* @param huart UART handle.
* @note This procedure could be used for aborting any ongoing Rx transfer started in Interrupt or DMA mode.
* This procedure performs following operations :
* - Disable UART Interrupts (Rx)
* - Disable the DMA transfer in the peripheral register (if enabled)
* - Abort DMA transfer by calling HAL_DMA_Abort (in case of transfer in DMA mode)
* - Set handle State to READY
* @note This procedure is executed in blocking mode : when exiting function, Abort is considered as completed.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_AbortReceive(UART_HandleTypeDef *huart)
{
/* Disable PEIE, EIE, RXNEIE and RXFTIE interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_PEIE | USART_CR1_RXNEIE_RXFNEIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE | USART_CR3_RXFTIE);
/* If Reception till IDLE event was ongoing, disable IDLEIE interrupt */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_IDLEIE));
}
/* Abort the UART DMA Rx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR))
{
/* Disable the UART DMA Rx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* Abort the UART DMA Rx channel : use blocking DMA Abort API (no callback) */
if (huart->hdmarx != NULL)
{
/* Set the UART DMA Abort callback to Null.
No call back execution at end of DMA abort procedure */
huart->hdmarx->XferAbortCallback = NULL;
if (HAL_DMA_Abort(huart->hdmarx) != HAL_OK)
{
if (HAL_DMA_GetError(huart->hdmarx) == HAL_DMA_ERROR_TIMEOUT)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
return HAL_TIMEOUT;
}
}
}
}
/* Reset Rx transfer counter */
huart->RxXferCount = 0U;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Discard the received data */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
/* Restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
return HAL_OK;
}
/**
* @brief Abort ongoing transfers (Interrupt mode).
* @param huart UART handle.
* @note This procedure could be used for aborting any ongoing transfer started in Interrupt or DMA mode.
* This procedure performs following operations :
* - Disable UART Interrupts (Tx and Rx)
* - Disable the DMA transfer in the peripheral register (if enabled)
* - Abort DMA transfer by calling HAL_DMA_Abort_IT (in case of transfer in DMA mode)
* - Set handle State to READY
* - At abort completion, call user abort complete callback
* @note This procedure is executed in Interrupt mode, meaning that abort procedure could be
* considered as completed only when user abort complete callback is executed (not when exiting function).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_Abort_IT(UART_HandleTypeDef *huart)
{
uint32_t abortcplt = 1U;
/* Disable interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_PEIE | USART_CR1_TCIE | USART_CR1_RXNEIE_RXFNEIE |
USART_CR1_TXEIE_TXFNFIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, (USART_CR3_EIE | USART_CR3_RXFTIE | USART_CR3_TXFTIE));
/* If Reception till IDLE event was ongoing, disable IDLEIE interrupt */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_IDLEIE));
}
/* If DMA Tx and/or DMA Rx Handles are associated to UART Handle, DMA Abort complete callbacks should be initialised
before any call to DMA Abort functions */
/* DMA Tx Handle is valid */
if (huart->hdmatx != NULL)
{
/* Set DMA Abort Complete callback if UART DMA Tx request if enabled.
Otherwise, set it to NULL */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT))
{
huart->hdmatx->XferAbortCallback = UART_DMATxAbortCallback;
}
else
{
huart->hdmatx->XferAbortCallback = NULL;
}
}
/* DMA Rx Handle is valid */
if (huart->hdmarx != NULL)
{
/* Set DMA Abort Complete callback if UART DMA Rx request if enabled.
Otherwise, set it to NULL */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR))
{
huart->hdmarx->XferAbortCallback = UART_DMARxAbortCallback;
}
else
{
huart->hdmarx->XferAbortCallback = NULL;
}
}
/* Abort the UART DMA Tx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT))
{
/* Disable DMA Tx at UART level */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAT);
/* Abort the UART DMA Tx channel : use non blocking DMA Abort API (callback) */
if (huart->hdmatx != NULL)
{
/* UART Tx DMA Abort callback has already been initialised :
will lead to call HAL_UART_AbortCpltCallback() at end of DMA abort procedure */
/* Abort DMA TX */
if (HAL_DMA_Abort_IT(huart->hdmatx) != HAL_OK)
{
huart->hdmatx->XferAbortCallback = NULL;
}
else
{
abortcplt = 0U;
}
}
}
/* Abort the UART DMA Rx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR))
{
/* Disable the UART DMA Rx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* Abort the UART DMA Rx channel : use non blocking DMA Abort API (callback) */
if (huart->hdmarx != NULL)
{
/* UART Rx DMA Abort callback has already been initialised :
will lead to call HAL_UART_AbortCpltCallback() at end of DMA abort procedure */
/* Abort DMA RX */
if (HAL_DMA_Abort_IT(huart->hdmarx) != HAL_OK)
{
huart->hdmarx->XferAbortCallback = NULL;
abortcplt = 1U;
}
else
{
abortcplt = 0U;
}
}
}
/* if no DMA abort complete callback execution is required => call user Abort Complete callback */
if (abortcplt == 1U)
{
/* Reset Tx and Rx transfer counters */
huart->TxXferCount = 0U;
huart->RxXferCount = 0U;
/* Clear ISR function pointers */
huart->RxISR = NULL;
huart->TxISR = NULL;
/* Reset errorCode */
huart->ErrorCode = HAL_UART_ERROR_NONE;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Flush the whole TX FIFO (if needed) */
if (huart->FifoMode == UART_FIFOMODE_ENABLE)
{
__HAL_UART_SEND_REQ(huart, UART_TXDATA_FLUSH_REQUEST);
}
/* Discard the received data */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
/* Restore huart->gState and huart->RxState to Ready */
huart->gState = HAL_UART_STATE_READY;
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* As no DMA to be aborted, call directly user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort complete callback */
huart->AbortCpltCallback(huart);
#else
/* Call legacy weak Abort complete callback */
HAL_UART_AbortCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
return HAL_OK;
}
/**
* @brief Abort ongoing Transmit transfer (Interrupt mode).
* @param huart UART handle.
* @note This procedure could be used for aborting any ongoing Tx transfer started in Interrupt or DMA mode.
* This procedure performs following operations :
* - Disable UART Interrupts (Tx)
* - Disable the DMA transfer in the peripheral register (if enabled)
* - Abort DMA transfer by calling HAL_DMA_Abort_IT (in case of transfer in DMA mode)
* - Set handle State to READY
* - At abort completion, call user abort complete callback
* @note This procedure is executed in Interrupt mode, meaning that abort procedure could be
* considered as completed only when user abort complete callback is executed (not when exiting function).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_AbortTransmit_IT(UART_HandleTypeDef *huart)
{
/* Disable interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_TCIE | USART_CR1_TXEIE_TXFNFIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_TXFTIE);
/* Abort the UART DMA Tx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT))
{
/* Disable the UART DMA Tx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAT);
/* Abort the UART DMA Tx channel : use non blocking DMA Abort API (callback) */
if (huart->hdmatx != NULL)
{
/* Set the UART DMA Abort callback :
will lead to call HAL_UART_AbortCpltCallback() at end of DMA abort procedure */
huart->hdmatx->XferAbortCallback = UART_DMATxOnlyAbortCallback;
/* Abort DMA TX */
if (HAL_DMA_Abort_IT(huart->hdmatx) != HAL_OK)
{
/* Call Directly huart->hdmatx->XferAbortCallback function in case of error */
huart->hdmatx->XferAbortCallback(huart->hdmatx);
}
}
else
{
/* Reset Tx transfer counter */
huart->TxXferCount = 0U;
/* Clear TxISR function pointers */
huart->TxISR = NULL;
/* Restore huart->gState to Ready */
huart->gState = HAL_UART_STATE_READY;
/* As no DMA to be aborted, call directly user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort Transmit Complete Callback */
huart->AbortTransmitCpltCallback(huart);
#else
/* Call legacy weak Abort Transmit Complete Callback */
HAL_UART_AbortTransmitCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
else
{
/* Reset Tx transfer counter */
huart->TxXferCount = 0U;
/* Clear TxISR function pointers */
huart->TxISR = NULL;
/* Flush the whole TX FIFO (if needed) */
if (huart->FifoMode == UART_FIFOMODE_ENABLE)
{
__HAL_UART_SEND_REQ(huart, UART_TXDATA_FLUSH_REQUEST);
}
/* Restore huart->gState to Ready */
huart->gState = HAL_UART_STATE_READY;
/* As no DMA to be aborted, call directly user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort Transmit Complete Callback */
huart->AbortTransmitCpltCallback(huart);
#else
/* Call legacy weak Abort Transmit Complete Callback */
HAL_UART_AbortTransmitCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
return HAL_OK;
}
/**
* @brief Abort ongoing Receive transfer (Interrupt mode).
* @param huart UART handle.
* @note This procedure could be used for aborting any ongoing Rx transfer started in Interrupt or DMA mode.
* This procedure performs following operations :
* - Disable UART Interrupts (Rx)
* - Disable the DMA transfer in the peripheral register (if enabled)
* - Abort DMA transfer by calling HAL_DMA_Abort_IT (in case of transfer in DMA mode)
* - Set handle State to READY
* - At abort completion, call user abort complete callback
* @note This procedure is executed in Interrupt mode, meaning that abort procedure could be
* considered as completed only when user abort complete callback is executed (not when exiting function).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_AbortReceive_IT(UART_HandleTypeDef *huart)
{
/* Disable RXNE, PE and ERR (Frame error, noise error, overrun error) interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_PEIE | USART_CR1_RXNEIE_RXFNEIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, (USART_CR3_EIE | USART_CR3_RXFTIE));
/* If Reception till IDLE event was ongoing, disable IDLEIE interrupt */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_IDLEIE));
}
/* Abort the UART DMA Rx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR))
{
/* Disable the UART DMA Rx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* Abort the UART DMA Rx channel : use non blocking DMA Abort API (callback) */
if (huart->hdmarx != NULL)
{
/* Set the UART DMA Abort callback :
will lead to call HAL_UART_AbortCpltCallback() at end of DMA abort procedure */
huart->hdmarx->XferAbortCallback = UART_DMARxOnlyAbortCallback;
/* Abort DMA RX */
if (HAL_DMA_Abort_IT(huart->hdmarx) != HAL_OK)
{
/* Call Directly huart->hdmarx->XferAbortCallback function in case of error */
huart->hdmarx->XferAbortCallback(huart->hdmarx);
}
}
else
{
/* Reset Rx transfer counter */
huart->RxXferCount = 0U;
/* Clear RxISR function pointer */
huart->pRxBuffPtr = NULL;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Discard the received data */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
/* Restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* As no DMA to be aborted, call directly user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort Receive Complete Callback */
huart->AbortReceiveCpltCallback(huart);
#else
/* Call legacy weak Abort Receive Complete Callback */
HAL_UART_AbortReceiveCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
else
{
/* Reset Rx transfer counter */
huart->RxXferCount = 0U;
/* Clear RxISR function pointer */
huart->pRxBuffPtr = NULL;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* As no DMA to be aborted, call directly user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort Receive Complete Callback */
huart->AbortReceiveCpltCallback(huart);
#else
/* Call legacy weak Abort Receive Complete Callback */
HAL_UART_AbortReceiveCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
return HAL_OK;
}
/**
* @brief Handle UART interrupt request.
* @param huart UART handle.
* @retval None
*/
void HAL_UART_IRQHandler(UART_HandleTypeDef *huart)
{
uint32_t isrflags = READ_REG(huart->Instance->ISR);
uint32_t cr1its = READ_REG(huart->Instance->CR1);
uint32_t cr3its = READ_REG(huart->Instance->CR3);
uint32_t errorflags;
uint32_t errorcode;
/* If no error occurs */
errorflags = (isrflags & (uint32_t)(USART_ISR_PE | USART_ISR_FE | USART_ISR_ORE | USART_ISR_NE | USART_ISR_RTOF));
if (errorflags == 0U)
{
/* UART in mode Receiver ---------------------------------------------------*/
if (((isrflags & USART_ISR_RXNE_RXFNE) != 0U)
&& (((cr1its & USART_CR1_RXNEIE_RXFNEIE) != 0U)
|| ((cr3its & USART_CR3_RXFTIE) != 0U)))
{
if (huart->RxISR != NULL)
{
huart->RxISR(huart);
}
return;
}
}
/* If some errors occur */
if ((errorflags != 0U)
&& ((((cr3its & (USART_CR3_RXFTIE | USART_CR3_EIE)) != 0U)
|| ((cr1its & (USART_CR1_RXNEIE_RXFNEIE | USART_CR1_PEIE | USART_CR1_RTOIE)) != 0U))))
{
/* UART parity error interrupt occurred -------------------------------------*/
if (((isrflags & USART_ISR_PE) != 0U) && ((cr1its & USART_CR1_PEIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_PEF);
huart->ErrorCode |= HAL_UART_ERROR_PE;
}
/* UART frame error interrupt occurred --------------------------------------*/
if (((isrflags & USART_ISR_FE) != 0U) && ((cr3its & USART_CR3_EIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_FEF);
huart->ErrorCode |= HAL_UART_ERROR_FE;
}
/* UART noise error interrupt occurred --------------------------------------*/
if (((isrflags & USART_ISR_NE) != 0U) && ((cr3its & USART_CR3_EIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_NEF);
huart->ErrorCode |= HAL_UART_ERROR_NE;
}
/* UART Over-Run interrupt occurred -----------------------------------------*/
if (((isrflags & USART_ISR_ORE) != 0U)
&& (((cr1its & USART_CR1_RXNEIE_RXFNEIE) != 0U) ||
((cr3its & (USART_CR3_RXFTIE | USART_CR3_EIE)) != 0U)))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF);
huart->ErrorCode |= HAL_UART_ERROR_ORE;
}
/* UART Receiver Timeout interrupt occurred ---------------------------------*/
if (((isrflags & USART_ISR_RTOF) != 0U) && ((cr1its & USART_CR1_RTOIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_RTOF);
huart->ErrorCode |= HAL_UART_ERROR_RTO;
}
/* Call UART Error Call back function if need be ----------------------------*/
if (huart->ErrorCode != HAL_UART_ERROR_NONE)
{
/* UART in mode Receiver --------------------------------------------------*/
if (((isrflags & USART_ISR_RXNE_RXFNE) != 0U)
&& (((cr1its & USART_CR1_RXNEIE_RXFNEIE) != 0U)
|| ((cr3its & USART_CR3_RXFTIE) != 0U)))
{
if (huart->RxISR != NULL)
{
huart->RxISR(huart);
}
}
/* If Error is to be considered as blocking :
- Receiver Timeout error in Reception
- Overrun error in Reception
- any error occurs in DMA mode reception
*/
errorcode = huart->ErrorCode;
if ((HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR)) ||
((errorcode & (HAL_UART_ERROR_RTO | HAL_UART_ERROR_ORE)) != 0U))
{
/* Blocking error : transfer is aborted
Set the UART state ready to be able to start again the process,
Disable Rx Interrupts, and disable Rx DMA request, if ongoing */
UART_EndRxTransfer(huart);
/* Abort the UART DMA Rx channel if enabled */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR))
{
/* Disable the UART DMA Rx request if enabled */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* Abort the UART DMA Rx channel */
if (huart->hdmarx != NULL)
{
/* Set the UART DMA Abort callback :
will lead to call HAL_UART_ErrorCallback() at end of DMA abort procedure */
huart->hdmarx->XferAbortCallback = UART_DMAAbortOnError;
/* Abort DMA RX */
if (HAL_DMA_Abort_IT(huart->hdmarx) != HAL_OK)
{
/* Call Directly huart->hdmarx->XferAbortCallback function in case of error */
huart->hdmarx->XferAbortCallback(huart->hdmarx);
}
}
else
{
/* Call user error callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
huart->ErrorCallback(huart);
#else
/*Call legacy weak error callback*/
HAL_UART_ErrorCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
else
{
/* Call user error callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
huart->ErrorCallback(huart);
#else
/*Call legacy weak error callback*/
HAL_UART_ErrorCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
else
{
/* Non Blocking error : transfer could go on.
Error is notified to user through user error callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
huart->ErrorCallback(huart);
#else
/*Call legacy weak error callback*/
HAL_UART_ErrorCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
huart->ErrorCode = HAL_UART_ERROR_NONE;
}
}
return;
} /* End if some error occurs */
/* Check current reception Mode :
If Reception till IDLE event has been selected : */
if ((huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
&& ((isrflags & USART_ISR_IDLE) != 0U)
&& ((cr1its & USART_ISR_IDLE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
/* Check if DMA mode is enabled in UART */
if (HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR))
{
/* DMA mode enabled */
/* Check received length : If all expected data are received, do nothing,
(DMA cplt callback will be called).
Otherwise, if at least one data has already been received, IDLE event is to be notified to user */
uint16_t nb_remaining_rx_data = (uint16_t) __HAL_DMA_GET_COUNTER(huart->hdmarx);
if ((nb_remaining_rx_data > 0U)
&& (nb_remaining_rx_data < huart->RxXferSize))
{
/* Reception is not complete */
huart->RxXferCount = nb_remaining_rx_data;
/* In Normal mode, end DMA xfer and HAL UART Rx process*/
if (HAL_IS_BIT_CLR(huart->hdmarx->Instance->CCR, DMA_CCR_CIRC))
{
/* Disable PE and ERR (Frame error, noise error, overrun error) interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_PEIE);
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Disable the DMA transfer for the receiver request by resetting the DMAR bit
in the UART CR3 register */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* At end of Rx process, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
/* Last bytes received, so no need as the abort is immediate */
(void)HAL_DMA_Abort(huart->hdmarx);
}
/* Initialize type of RxEvent that correspond to RxEvent callback execution;
In this case, Rx Event type is Idle Event */
huart->RxEventType = HAL_UART_RXEVENT_IDLE;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Event callback*/
huart->RxEventCallback(huart, (huart->RxXferSize - huart->RxXferCount));
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, (huart->RxXferSize - huart->RxXferCount));
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
return;
}
else
{
/* DMA mode not enabled */
/* Check received length : If all expected data are received, do nothing.
Otherwise, if at least one data has already been received, IDLE event is to be notified to user */
uint16_t nb_rx_data = huart->RxXferSize - huart->RxXferCount;
if ((huart->RxXferCount > 0U)
&& (nb_rx_data > 0U))
{
/* Disable the UART Parity Error Interrupt and RXNE interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_RXNEIE_RXFNEIE | USART_CR1_PEIE));
/* Disable the UART Error Interrupt:(Frame error, noise error, overrun error) and RX FIFO Threshold interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, (USART_CR3_EIE | USART_CR3_RXFTIE));
/* Rx process is completed, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Clear RxISR function pointer */
huart->RxISR = NULL;
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
/* Initialize type of RxEvent that correspond to RxEvent callback execution;
In this case, Rx Event type is Idle Event */
huart->RxEventType = HAL_UART_RXEVENT_IDLE;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx complete callback*/
huart->RxEventCallback(huart, nb_rx_data);
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, nb_rx_data);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
return;
}
}
/* UART wakeup from Stop mode interrupt occurred ---------------------------*/
if (((isrflags & USART_ISR_WUF) != 0U) && ((cr3its & USART_CR3_WUFIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_WUF);
/* UART Rx state is not reset as a reception process might be ongoing.
If UART handle state fields need to be reset to READY, this could be done in Wakeup callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Wakeup Callback */
huart->WakeupCallback(huart);
#else
/* Call legacy weak Wakeup Callback */
HAL_UARTEx_WakeupCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
return;
}
/* UART in mode Transmitter ------------------------------------------------*/
if (((isrflags & USART_ISR_TXE_TXFNF) != 0U)
&& (((cr1its & USART_CR1_TXEIE_TXFNFIE) != 0U)
|| ((cr3its & USART_CR3_TXFTIE) != 0U)))
{
if (huart->TxISR != NULL)
{
huart->TxISR(huart);
}
return;
}
/* UART in mode Transmitter (transmission end) -----------------------------*/
if (((isrflags & USART_ISR_TC) != 0U) && ((cr1its & USART_CR1_TCIE) != 0U))
{
UART_EndTransmit_IT(huart);
return;
}
/* UART TX Fifo Empty occurred ----------------------------------------------*/
if (((isrflags & USART_ISR_TXFE) != 0U) && ((cr1its & USART_CR1_TXFEIE) != 0U))
{
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Tx Fifo Empty Callback */
huart->TxFifoEmptyCallback(huart);
#else
/* Call legacy weak Tx Fifo Empty Callback */
HAL_UARTEx_TxFifoEmptyCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
return;
}
/* UART RX Fifo Full occurred ----------------------------------------------*/
if (((isrflags & USART_ISR_RXFF) != 0U) && ((cr1its & USART_CR1_RXFFIE) != 0U))
{
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Rx Fifo Full Callback */
huart->RxFifoFullCallback(huart);
#else
/* Call legacy weak Rx Fifo Full Callback */
HAL_UARTEx_RxFifoFullCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
return;
}
}
/**
* @brief Tx Transfer completed callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_TxCpltCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_TxCpltCallback can be implemented in the user file.
*/
}
/**
* @brief Tx Half Transfer completed callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_TxHalfCpltCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE: This function should not be modified, when the callback is needed,
the HAL_UART_TxHalfCpltCallback can be implemented in the user file.
*/
}
/**
* @brief Rx Transfer completed callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_RxCpltCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_RxCpltCallback can be implemented in the user file.
*/
}
/**
* @brief Rx Half Transfer completed callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_RxHalfCpltCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE: This function should not be modified, when the callback is needed,
the HAL_UART_RxHalfCpltCallback can be implemented in the user file.
*/
}
/**
* @brief UART error callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_ErrorCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_ErrorCallback can be implemented in the user file.
*/
}
/**
* @brief UART Abort Complete callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_AbortCpltCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_AbortCpltCallback can be implemented in the user file.
*/
}
/**
* @brief UART Abort Complete callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_AbortTransmitCpltCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_AbortTransmitCpltCallback can be implemented in the user file.
*/
}
/**
* @brief UART Abort Receive Complete callback.
* @param huart UART handle.
* @retval None
*/
__weak void HAL_UART_AbortReceiveCpltCallback(UART_HandleTypeDef *huart)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UART_AbortReceiveCpltCallback can be implemented in the user file.
*/
}
/**
* @brief Reception Event Callback (Rx event notification called after use of advanced reception service).
* @param huart UART handle
* @param Size Number of data available in application reception buffer (indicates a position in
* reception buffer until which, data are available)
* @retval None
*/
__weak void HAL_UARTEx_RxEventCallback(UART_HandleTypeDef *huart, uint16_t Size)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(huart);
UNUSED(Size);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_UARTEx_RxEventCallback can be implemented in the user file.
*/
}
/**
* @}
*/
/** @defgroup UART_Exported_Functions_Group3 Peripheral Control functions
* @brief UART control functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the UART.
(+) HAL_UART_ReceiverTimeout_Config() API allows to configure the receiver timeout value on the fly
(+) HAL_UART_EnableReceiverTimeout() API enables the receiver timeout feature
(+) HAL_UART_DisableReceiverTimeout() API disables the receiver timeout feature
(+) HAL_MultiProcessor_EnableMuteMode() API enables mute mode
(+) HAL_MultiProcessor_DisableMuteMode() API disables mute mode
(+) HAL_MultiProcessor_EnterMuteMode() API enters mute mode
(+) UART_SetConfig() API configures the UART peripheral
(+) UART_AdvFeatureConfig() API optionally configures the UART advanced features
(+) UART_CheckIdleState() API ensures that TEACK and/or REACK are set after initialization
(+) HAL_HalfDuplex_EnableTransmitter() API disables receiver and enables transmitter
(+) HAL_HalfDuplex_EnableReceiver() API disables transmitter and enables receiver
(+) HAL_LIN_SendBreak() API transmits the break characters
@endverbatim
* @{
*/
/**
* @brief Update on the fly the receiver timeout value in RTOR register.
* @param huart Pointer to a UART_HandleTypeDef structure that contains
* the configuration information for the specified UART module.
* @param TimeoutValue receiver timeout value in number of baud blocks. The timeout
* value must be less or equal to 0x0FFFFFFFF.
* @retval None
*/
void HAL_UART_ReceiverTimeout_Config(UART_HandleTypeDef *huart, uint32_t TimeoutValue)
{
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
assert_param(IS_UART_RECEIVER_TIMEOUT_VALUE(TimeoutValue));
MODIFY_REG(huart->Instance->RTOR, USART_RTOR_RTO, TimeoutValue);
}
}
/**
* @brief Enable the UART receiver timeout feature.
* @param huart Pointer to a UART_HandleTypeDef structure that contains
* the configuration information for the specified UART module.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_EnableReceiverTimeout(UART_HandleTypeDef *huart)
{
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
if (huart->gState == HAL_UART_STATE_READY)
{
/* Process Locked */
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Set the USART RTOEN bit */
SET_BIT(huart->Instance->CR2, USART_CR2_RTOEN);
huart->gState = HAL_UART_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
else
{
return HAL_BUSY;
}
}
else
{
return HAL_ERROR;
}
}
/**
* @brief Disable the UART receiver timeout feature.
* @param huart Pointer to a UART_HandleTypeDef structure that contains
* the configuration information for the specified UART module.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_UART_DisableReceiverTimeout(UART_HandleTypeDef *huart)
{
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
if (huart->gState == HAL_UART_STATE_READY)
{
/* Process Locked */
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Clear the USART RTOEN bit */
CLEAR_BIT(huart->Instance->CR2, USART_CR2_RTOEN);
huart->gState = HAL_UART_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_OK;
}
else
{
return HAL_BUSY;
}
}
else
{
return HAL_ERROR;
}
}
/**
* @brief Enable UART in mute mode (does not mean UART enters mute mode;
* to enter mute mode, HAL_MultiProcessor_EnterMuteMode() API must be called).
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_MultiProcessor_EnableMuteMode(UART_HandleTypeDef *huart)
{
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Enable USART mute mode by setting the MME bit in the CR1 register */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_MME);
huart->gState = HAL_UART_STATE_READY;
return (UART_CheckIdleState(huart));
}
/**
* @brief Disable UART mute mode (does not mean the UART actually exits mute mode
* as it may not have been in mute mode at this very moment).
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_MultiProcessor_DisableMuteMode(UART_HandleTypeDef *huart)
{
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Disable USART mute mode by clearing the MME bit in the CR1 register */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_MME);
huart->gState = HAL_UART_STATE_READY;
return (UART_CheckIdleState(huart));
}
/**
* @brief Enter UART mute mode (means UART actually enters mute mode).
* @note To exit from mute mode, HAL_MultiProcessor_DisableMuteMode() API must be called.
* @param huart UART handle.
* @retval None
*/
void HAL_MultiProcessor_EnterMuteMode(UART_HandleTypeDef *huart)
{
__HAL_UART_SEND_REQ(huart, UART_MUTE_MODE_REQUEST);
}
/**
* @brief Enable the UART transmitter and disable the UART receiver.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_HalfDuplex_EnableTransmitter(UART_HandleTypeDef *huart)
{
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Clear TE and RE bits */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_TE | USART_CR1_RE));
/* Enable the USART's transmit interface by setting the TE bit in the USART CR1 register */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_TE);
huart->gState = HAL_UART_STATE_READY;
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Enable the UART receiver and disable the UART transmitter.
* @param huart UART handle.
* @retval HAL status.
*/
HAL_StatusTypeDef HAL_HalfDuplex_EnableReceiver(UART_HandleTypeDef *huart)
{
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Clear TE and RE bits */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_TE | USART_CR1_RE));
/* Enable the USART's receive interface by setting the RE bit in the USART CR1 register */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_RE);
huart->gState = HAL_UART_STATE_READY;
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief Transmit break characters.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_LIN_SendBreak(UART_HandleTypeDef *huart)
{
/* Check the parameters */
assert_param(IS_UART_LIN_INSTANCE(huart->Instance));
__HAL_LOCK(huart);
huart->gState = HAL_UART_STATE_BUSY;
/* Send break characters */
__HAL_UART_SEND_REQ(huart, UART_SENDBREAK_REQUEST);
huart->gState = HAL_UART_STATE_READY;
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @}
*/
/** @defgroup UART_Exported_Functions_Group4 Peripheral State and Error functions
* @brief UART Peripheral State functions
*
@verbatim
==============================================================================
##### Peripheral State and Error functions #####
==============================================================================
[..]
This subsection provides functions allowing to :
(+) Return the UART handle state.
(+) Return the UART handle error code
@endverbatim
* @{
*/
/**
* @brief Return the UART handle state.
* @param huart Pointer to a UART_HandleTypeDef structure that contains
* the configuration information for the specified UART.
* @retval HAL state
*/
HAL_UART_StateTypeDef HAL_UART_GetState(const UART_HandleTypeDef *huart)
{
uint32_t temp1;
uint32_t temp2;
temp1 = huart->gState;
temp2 = huart->RxState;
return (HAL_UART_StateTypeDef)(temp1 | temp2);
}
/**
* @brief Return the UART handle error code.
* @param huart Pointer to a UART_HandleTypeDef structure that contains
* the configuration information for the specified UART.
* @retval UART Error Code
*/
uint32_t HAL_UART_GetError(const UART_HandleTypeDef *huart)
{
return huart->ErrorCode;
}
/**
* @}
*/
/**
* @}
*/
/** @defgroup UART_Private_Functions UART Private Functions
* @{
*/
/**
* @brief Initialize the callbacks to their default values.
* @param huart UART handle.
* @retval none
*/
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
void UART_InitCallbacksToDefault(UART_HandleTypeDef *huart)
{
/* Init the UART Callback settings */
huart->TxHalfCpltCallback = HAL_UART_TxHalfCpltCallback; /* Legacy weak TxHalfCpltCallback */
huart->TxCpltCallback = HAL_UART_TxCpltCallback; /* Legacy weak TxCpltCallback */
huart->RxHalfCpltCallback = HAL_UART_RxHalfCpltCallback; /* Legacy weak RxHalfCpltCallback */
huart->RxCpltCallback = HAL_UART_RxCpltCallback; /* Legacy weak RxCpltCallback */
huart->ErrorCallback = HAL_UART_ErrorCallback; /* Legacy weak ErrorCallback */
huart->AbortCpltCallback = HAL_UART_AbortCpltCallback; /* Legacy weak AbortCpltCallback */
huart->AbortTransmitCpltCallback = HAL_UART_AbortTransmitCpltCallback; /* Legacy weak AbortTransmitCpltCallback */
huart->AbortReceiveCpltCallback = HAL_UART_AbortReceiveCpltCallback; /* Legacy weak AbortReceiveCpltCallback */
huart->WakeupCallback = HAL_UARTEx_WakeupCallback; /* Legacy weak WakeupCallback */
huart->RxFifoFullCallback = HAL_UARTEx_RxFifoFullCallback; /* Legacy weak RxFifoFullCallback */
huart->TxFifoEmptyCallback = HAL_UARTEx_TxFifoEmptyCallback; /* Legacy weak TxFifoEmptyCallback */
huart->RxEventCallback = HAL_UARTEx_RxEventCallback; /* Legacy weak RxEventCallback */
}
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
/**
* @brief Configure the UART peripheral.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef UART_SetConfig(UART_HandleTypeDef *huart)
{
uint32_t tmpreg;
uint16_t brrtemp;
UART_ClockSourceTypeDef clocksource;
uint32_t usartdiv;
HAL_StatusTypeDef ret = HAL_OK;
uint32_t lpuart_ker_ck_pres;
uint32_t pclk;
/* Check the parameters */
assert_param(IS_UART_BAUDRATE(huart->Init.BaudRate));
assert_param(IS_UART_WORD_LENGTH(huart->Init.WordLength));
if (UART_INSTANCE_LOWPOWER(huart))
{
assert_param(IS_LPUART_STOPBITS(huart->Init.StopBits));
}
else
{
assert_param(IS_UART_STOPBITS(huart->Init.StopBits));
assert_param(IS_UART_ONE_BIT_SAMPLE(huart->Init.OneBitSampling));
}
assert_param(IS_UART_PARITY(huart->Init.Parity));
assert_param(IS_UART_MODE(huart->Init.Mode));
assert_param(IS_UART_HARDWARE_FLOW_CONTROL(huart->Init.HwFlowCtl));
assert_param(IS_UART_OVERSAMPLING(huart->Init.OverSampling));
assert_param(IS_UART_PRESCALER(huart->Init.ClockPrescaler));
/*-------------------------- USART CR1 Configuration -----------------------*/
/* Clear M, PCE, PS, TE, RE and OVER8 bits and configure
* the UART Word Length, Parity, Mode and oversampling:
* set the M bits according to huart->Init.WordLength value
* set PCE and PS bits according to huart->Init.Parity value
* set TE and RE bits according to huart->Init.Mode value
* set OVER8 bit according to huart->Init.OverSampling value */
tmpreg = (uint32_t)huart->Init.WordLength | huart->Init.Parity | huart->Init.Mode | huart->Init.OverSampling ;
MODIFY_REG(huart->Instance->CR1, USART_CR1_FIELDS, tmpreg);
/*-------------------------- USART CR2 Configuration -----------------------*/
/* Configure the UART Stop Bits: Set STOP[13:12] bits according
* to huart->Init.StopBits value */
MODIFY_REG(huart->Instance->CR2, USART_CR2_STOP, huart->Init.StopBits);
/*-------------------------- USART CR3 Configuration -----------------------*/
/* Configure
* - UART HardWare Flow Control: set CTSE and RTSE bits according
* to huart->Init.HwFlowCtl value
* - one-bit sampling method versus three samples' majority rule according
* to huart->Init.OneBitSampling (not applicable to LPUART) */
tmpreg = (uint32_t)huart->Init.HwFlowCtl;
if (!(UART_INSTANCE_LOWPOWER(huart)))
{
tmpreg |= huart->Init.OneBitSampling;
}
MODIFY_REG(huart->Instance->CR3, USART_CR3_FIELDS, tmpreg);
/*-------------------------- USART PRESC Configuration -----------------------*/
/* Configure
* - UART Clock Prescaler : set PRESCALER according to huart->Init.ClockPrescaler value */
MODIFY_REG(huart->Instance->PRESC, USART_PRESC_PRESCALER, huart->Init.ClockPrescaler);
/*-------------------------- USART BRR Configuration -----------------------*/
UART_GETCLOCKSOURCE(huart, clocksource);
/* Check LPUART instance */
if (UART_INSTANCE_LOWPOWER(huart))
{
/* Retrieve frequency clock */
switch (clocksource)
{
case UART_CLOCKSOURCE_PCLK1:
pclk = HAL_RCC_GetPCLK1Freq();
break;
case UART_CLOCKSOURCE_HSI:
pclk = (uint32_t) HSI_VALUE;
break;
case UART_CLOCKSOURCE_SYSCLK:
pclk = HAL_RCC_GetSysClockFreq();
break;
case UART_CLOCKSOURCE_LSE:
pclk = (uint32_t) LSE_VALUE;
break;
default:
pclk = 0U;
ret = HAL_ERROR;
break;
}
/* If proper clock source reported */
if (pclk != 0U)
{
/* Compute clock after Prescaler */
lpuart_ker_ck_pres = (pclk / UARTPrescTable[huart->Init.ClockPrescaler]);
/* Ensure that Frequency clock is in the range [3 * baudrate, 4096 * baudrate] */
if ((lpuart_ker_ck_pres < (3U * huart->Init.BaudRate)) ||
(lpuart_ker_ck_pres > (4096U * huart->Init.BaudRate)))
{
ret = HAL_ERROR;
}
else
{
/* Check computed UsartDiv value is in allocated range
(it is forbidden to write values lower than 0x300 in the LPUART_BRR register) */
usartdiv = (uint32_t)(UART_DIV_LPUART(pclk, huart->Init.BaudRate, huart->Init.ClockPrescaler));
if ((usartdiv >= LPUART_BRR_MIN) && (usartdiv <= LPUART_BRR_MAX))
{
huart->Instance->BRR = usartdiv;
}
else
{
ret = HAL_ERROR;
}
} /* if ( (lpuart_ker_ck_pres < (3 * huart->Init.BaudRate) ) ||
(lpuart_ker_ck_pres > (4096 * huart->Init.BaudRate) )) */
} /* if (pclk != 0) */
}
/* Check UART Over Sampling to set Baud Rate Register */
else if (huart->Init.OverSampling == UART_OVERSAMPLING_8)
{
switch (clocksource)
{
case UART_CLOCKSOURCE_PCLK1:
pclk = HAL_RCC_GetPCLK1Freq();
break;
case UART_CLOCKSOURCE_PCLK2:
pclk = HAL_RCC_GetPCLK2Freq();
break;
case UART_CLOCKSOURCE_HSI:
pclk = (uint32_t) HSI_VALUE;
break;
case UART_CLOCKSOURCE_SYSCLK:
pclk = HAL_RCC_GetSysClockFreq();
break;
case UART_CLOCKSOURCE_LSE:
pclk = (uint32_t) LSE_VALUE;
break;
default:
pclk = 0U;
ret = HAL_ERROR;
break;
}
/* USARTDIV must be greater than or equal to 0d16 */
if (pclk != 0U)
{
usartdiv = (uint32_t)(UART_DIV_SAMPLING8(pclk, huart->Init.BaudRate, huart->Init.ClockPrescaler));
if ((usartdiv >= UART_BRR_MIN) && (usartdiv <= UART_BRR_MAX))
{
brrtemp = (uint16_t)(usartdiv & 0xFFF0U);
brrtemp |= (uint16_t)((usartdiv & (uint16_t)0x000FU) >> 1U);
huart->Instance->BRR = brrtemp;
}
else
{
ret = HAL_ERROR;
}
}
}
else
{
switch (clocksource)
{
case UART_CLOCKSOURCE_PCLK1:
pclk = HAL_RCC_GetPCLK1Freq();
break;
case UART_CLOCKSOURCE_PCLK2:
pclk = HAL_RCC_GetPCLK2Freq();
break;
case UART_CLOCKSOURCE_HSI:
pclk = (uint32_t) HSI_VALUE;
break;
case UART_CLOCKSOURCE_SYSCLK:
pclk = HAL_RCC_GetSysClockFreq();
break;
case UART_CLOCKSOURCE_LSE:
pclk = (uint32_t) LSE_VALUE;
break;
default:
pclk = 0U;
ret = HAL_ERROR;
break;
}
if (pclk != 0U)
{
/* USARTDIV must be greater than or equal to 0d16 */
usartdiv = (uint32_t)(UART_DIV_SAMPLING16(pclk, huart->Init.BaudRate, huart->Init.ClockPrescaler));
if ((usartdiv >= UART_BRR_MIN) && (usartdiv <= UART_BRR_MAX))
{
huart->Instance->BRR = (uint16_t)usartdiv;
}
else
{
ret = HAL_ERROR;
}
}
}
/* Initialize the number of data to process during RX/TX ISR execution */
huart->NbTxDataToProcess = 1;
huart->NbRxDataToProcess = 1;
/* Clear ISR function pointers */
huart->RxISR = NULL;
huart->TxISR = NULL;
return ret;
}
/**
* @brief Configure the UART peripheral advanced features.
* @param huart UART handle.
* @retval None
*/
void UART_AdvFeatureConfig(UART_HandleTypeDef *huart)
{
/* Check whether the set of advanced features to configure is properly set */
assert_param(IS_UART_ADVFEATURE_INIT(huart->AdvancedInit.AdvFeatureInit));
/* if required, configure RX/TX pins swap */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_SWAP_INIT))
{
assert_param(IS_UART_ADVFEATURE_SWAP(huart->AdvancedInit.Swap));
MODIFY_REG(huart->Instance->CR2, USART_CR2_SWAP, huart->AdvancedInit.Swap);
}
/* if required, configure TX pin active level inversion */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_TXINVERT_INIT))
{
assert_param(IS_UART_ADVFEATURE_TXINV(huart->AdvancedInit.TxPinLevelInvert));
MODIFY_REG(huart->Instance->CR2, USART_CR2_TXINV, huart->AdvancedInit.TxPinLevelInvert);
}
/* if required, configure RX pin active level inversion */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_RXINVERT_INIT))
{
assert_param(IS_UART_ADVFEATURE_RXINV(huart->AdvancedInit.RxPinLevelInvert));
MODIFY_REG(huart->Instance->CR2, USART_CR2_RXINV, huart->AdvancedInit.RxPinLevelInvert);
}
/* if required, configure data inversion */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_DATAINVERT_INIT))
{
assert_param(IS_UART_ADVFEATURE_DATAINV(huart->AdvancedInit.DataInvert));
MODIFY_REG(huart->Instance->CR2, USART_CR2_DATAINV, huart->AdvancedInit.DataInvert);
}
/* if required, configure RX overrun detection disabling */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_RXOVERRUNDISABLE_INIT))
{
assert_param(IS_UART_OVERRUN(huart->AdvancedInit.OverrunDisable));
MODIFY_REG(huart->Instance->CR3, USART_CR3_OVRDIS, huart->AdvancedInit.OverrunDisable);
}
/* if required, configure DMA disabling on reception error */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_DMADISABLEONERROR_INIT))
{
assert_param(IS_UART_ADVFEATURE_DMAONRXERROR(huart->AdvancedInit.DMADisableonRxError));
MODIFY_REG(huart->Instance->CR3, USART_CR3_DDRE, huart->AdvancedInit.DMADisableonRxError);
}
/* if required, configure auto Baud rate detection scheme */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_AUTOBAUDRATE_INIT))
{
assert_param(IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(huart->Instance));
assert_param(IS_UART_ADVFEATURE_AUTOBAUDRATE(huart->AdvancedInit.AutoBaudRateEnable));
MODIFY_REG(huart->Instance->CR2, USART_CR2_ABREN, huart->AdvancedInit.AutoBaudRateEnable);
/* set auto Baudrate detection parameters if detection is enabled */
if (huart->AdvancedInit.AutoBaudRateEnable == UART_ADVFEATURE_AUTOBAUDRATE_ENABLE)
{
assert_param(IS_UART_ADVFEATURE_AUTOBAUDRATEMODE(huart->AdvancedInit.AutoBaudRateMode));
MODIFY_REG(huart->Instance->CR2, USART_CR2_ABRMODE, huart->AdvancedInit.AutoBaudRateMode);
}
}
/* if required, configure MSB first on communication line */
if (HAL_IS_BIT_SET(huart->AdvancedInit.AdvFeatureInit, UART_ADVFEATURE_MSBFIRST_INIT))
{
assert_param(IS_UART_ADVFEATURE_MSBFIRST(huart->AdvancedInit.MSBFirst));
MODIFY_REG(huart->Instance->CR2, USART_CR2_MSBFIRST, huart->AdvancedInit.MSBFirst);
}
}
/**
* @brief Check the UART Idle State.
* @param huart UART handle.
* @retval HAL status
*/
HAL_StatusTypeDef UART_CheckIdleState(UART_HandleTypeDef *huart)
{
uint32_t tickstart;
/* Initialize the UART ErrorCode */
huart->ErrorCode = HAL_UART_ERROR_NONE;
/* Init tickstart for timeout management */
tickstart = HAL_GetTick();
/* Check if the Transmitter is enabled */
if ((huart->Instance->CR1 & USART_CR1_TE) == USART_CR1_TE)
{
/* Wait until TEACK flag is set */
if (UART_WaitOnFlagUntilTimeout(huart, USART_ISR_TEACK, RESET, tickstart, HAL_UART_TIMEOUT_VALUE) != HAL_OK)
{
/* Disable TXE interrupt for the interrupt process */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_TXEIE_TXFNFIE));
huart->gState = HAL_UART_STATE_READY;
__HAL_UNLOCK(huart);
/* Timeout occurred */
return HAL_TIMEOUT;
}
}
/* Check if the Receiver is enabled */
if ((huart->Instance->CR1 & USART_CR1_RE) == USART_CR1_RE)
{
/* Wait until REACK flag is set */
if (UART_WaitOnFlagUntilTimeout(huart, USART_ISR_REACK, RESET, tickstart, HAL_UART_TIMEOUT_VALUE) != HAL_OK)
{
/* Disable RXNE, PE and ERR (Frame error, noise error, overrun error)
interrupts for the interrupt process */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_RXNEIE_RXFNEIE | USART_CR1_PEIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE);
huart->RxState = HAL_UART_STATE_READY;
__HAL_UNLOCK(huart);
/* Timeout occurred */
return HAL_TIMEOUT;
}
}
/* Initialize the UART State */
huart->gState = HAL_UART_STATE_READY;
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
huart->RxEventType = HAL_UART_RXEVENT_TC;
__HAL_UNLOCK(huart);
return HAL_OK;
}
/**
* @brief This function handles UART Communication Timeout. It waits
* until a flag is no longer in the specified status.
* @param huart UART handle.
* @param Flag Specifies the UART flag to check
* @param Status The actual Flag status (SET or RESET)
* @param Tickstart Tick start value
* @param Timeout Timeout duration
* @retval HAL status
*/
HAL_StatusTypeDef UART_WaitOnFlagUntilTimeout(UART_HandleTypeDef *huart, uint32_t Flag, FlagStatus Status,
uint32_t Tickstart, uint32_t Timeout)
{
/* Wait until flag is set */
while ((__HAL_UART_GET_FLAG(huart, Flag) ? SET : RESET) == Status)
{
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - Tickstart) > Timeout) || (Timeout == 0U))
{
return HAL_TIMEOUT;
}
if ((READ_BIT(huart->Instance->CR1, USART_CR1_RE) != 0U) && (Flag != UART_FLAG_TXE) && (Flag != UART_FLAG_TC))
{
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_ORE) == SET)
{
/* Clear Overrun Error flag*/
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF);
/* Blocking error : transfer is aborted
Set the UART state ready to be able to start again the process,
Disable Rx Interrupts if ongoing */
UART_EndRxTransfer(huart);
huart->ErrorCode = HAL_UART_ERROR_ORE;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_ERROR;
}
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_RTOF) == SET)
{
/* Clear Receiver Timeout flag*/
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_RTOF);
/* Blocking error : transfer is aborted
Set the UART state ready to be able to start again the process,
Disable Rx Interrupts if ongoing */
UART_EndRxTransfer(huart);
huart->ErrorCode = HAL_UART_ERROR_RTO;
/* Process Unlocked */
__HAL_UNLOCK(huart);
return HAL_TIMEOUT;
}
}
}
}
return HAL_OK;
}
/**
* @brief Start Receive operation in interrupt mode.
* @note This function could be called by all HAL UART API providing reception in Interrupt mode.
* @note When calling this function, parameters validity is considered as already checked,
* i.e. Rx State, buffer address, ...
* UART Handle is assumed as Locked.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be received.
* @retval HAL status
*/
HAL_StatusTypeDef UART_Start_Receive_IT(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size)
{
huart->pRxBuffPtr = pData;
huart->RxXferSize = Size;
huart->RxXferCount = Size;
huart->RxISR = NULL;
/* Computation of UART mask to apply to RDR register */
UART_MASK_COMPUTATION(huart);
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->RxState = HAL_UART_STATE_BUSY_RX;
/* Enable the UART Error Interrupt: (Frame error, noise error, overrun error) */
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Configure Rx interrupt processing */
if ((huart->FifoMode == UART_FIFOMODE_ENABLE) && (Size >= huart->NbRxDataToProcess))
{
/* Set the Rx ISR function pointer according to the data word length */
if ((huart->Init.WordLength == UART_WORDLENGTH_9B) && (huart->Init.Parity == UART_PARITY_NONE))
{
huart->RxISR = UART_RxISR_16BIT_FIFOEN;
}
else
{
huart->RxISR = UART_RxISR_8BIT_FIFOEN;
}
/* Enable the UART Parity Error interrupt and RX FIFO Threshold interrupt */
if (huart->Init.Parity != UART_PARITY_NONE)
{
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_PEIE);
}
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_RXFTIE);
}
else
{
/* Set the Rx ISR function pointer according to the data word length */
if ((huart->Init.WordLength == UART_WORDLENGTH_9B) && (huart->Init.Parity == UART_PARITY_NONE))
{
huart->RxISR = UART_RxISR_16BIT;
}
else
{
huart->RxISR = UART_RxISR_8BIT;
}
/* Enable the UART Parity Error interrupt and Data Register Not Empty interrupt */
if (huart->Init.Parity != UART_PARITY_NONE)
{
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_PEIE | USART_CR1_RXNEIE_RXFNEIE);
}
else
{
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_RXNEIE_RXFNEIE);
}
}
return HAL_OK;
}
/**
* @brief Start Receive operation in DMA mode.
* @note This function could be called by all HAL UART API providing reception in DMA mode.
* @note When calling this function, parameters validity is considered as already checked,
* i.e. Rx State, buffer address, ...
* UART Handle is assumed as Locked.
* @param huart UART handle.
* @param pData Pointer to data buffer (u8 or u16 data elements).
* @param Size Amount of data elements (u8 or u16) to be received.
* @retval HAL status
*/
HAL_StatusTypeDef UART_Start_Receive_DMA(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size)
{
huart->pRxBuffPtr = pData;
huart->RxXferSize = Size;
huart->ErrorCode = HAL_UART_ERROR_NONE;
huart->RxState = HAL_UART_STATE_BUSY_RX;
if (huart->hdmarx != NULL)
{
/* Set the UART DMA transfer complete callback */
huart->hdmarx->XferCpltCallback = UART_DMAReceiveCplt;
/* Set the UART DMA Half transfer complete callback */
huart->hdmarx->XferHalfCpltCallback = UART_DMARxHalfCplt;
/* Set the DMA error callback */
huart->hdmarx->XferErrorCallback = UART_DMAError;
/* Set the DMA abort callback */
huart->hdmarx->XferAbortCallback = NULL;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(huart->hdmarx, (uint32_t)&huart->Instance->RDR, (uint32_t)huart->pRxBuffPtr, Size) != HAL_OK)
{
/* Set error code to DMA */
huart->ErrorCode = HAL_UART_ERROR_DMA;
/* Restore huart->RxState to ready */
huart->RxState = HAL_UART_STATE_READY;
return HAL_ERROR;
}
}
/* Enable the UART Parity Error Interrupt */
if (huart->Init.Parity != UART_PARITY_NONE)
{
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_PEIE);
}
/* Enable the UART Error Interrupt: (Frame error, noise error, overrun error) */
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Enable the DMA transfer for the receiver request by setting the DMAR bit
in the UART CR3 register */
ATOMIC_SET_BIT(huart->Instance->CR3, USART_CR3_DMAR);
return HAL_OK;
}
/**
* @brief End ongoing Tx transfer on UART peripheral (following error detection or Transmit completion).
* @param huart UART handle.
* @retval None
*/
static void UART_EndTxTransfer(UART_HandleTypeDef *huart)
{
/* Disable TXEIE, TCIE, TXFT interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_TXEIE_TXFNFIE | USART_CR1_TCIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, (USART_CR3_TXFTIE));
/* At end of Tx process, restore huart->gState to Ready */
huart->gState = HAL_UART_STATE_READY;
}
/**
* @brief End ongoing Rx transfer on UART peripheral (following error detection or Reception completion).
* @param huart UART handle.
* @retval None
*/
static void UART_EndRxTransfer(UART_HandleTypeDef *huart)
{
/* Disable RXNE, PE and ERR (Frame error, noise error, overrun error) interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_RXNEIE_RXFNEIE | USART_CR1_PEIE));
ATOMIC_CLEAR_BIT(huart->Instance->CR3, (USART_CR3_EIE | USART_CR3_RXFTIE));
/* In case of reception waiting for IDLE event, disable also the IDLE IE interrupt source */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
}
/* At end of Rx process, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Reset RxIsr function pointer */
huart->RxISR = NULL;
}
/**
* @brief DMA UART transmit process complete callback.
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMATransmitCplt(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
/* DMA Normal mode */
if (HAL_IS_BIT_CLR(hdma->Instance->CCR, DMA_CCR_CIRC))
{
huart->TxXferCount = 0U;
/* Disable the DMA transfer for transmit request by resetting the DMAT bit
in the UART CR3 register */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAT);
/* Enable the UART Transmit Complete Interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_TCIE);
}
/* DMA Circular mode */
else
{
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Tx complete callback*/
huart->TxCpltCallback(huart);
#else
/*Call legacy weak Tx complete callback*/
HAL_UART_TxCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
/**
* @brief DMA UART transmit process half complete callback.
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMATxHalfCplt(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Tx Half complete callback*/
huart->TxHalfCpltCallback(huart);
#else
/*Call legacy weak Tx Half complete callback*/
HAL_UART_TxHalfCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief DMA UART receive process complete callback.
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMAReceiveCplt(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
/* DMA Normal mode */
if (HAL_IS_BIT_CLR(hdma->Instance->CCR, DMA_CCR_CIRC))
{
huart->RxXferCount = 0U;
/* Disable PE and ERR (Frame error, noise error, overrun error) interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_PEIE);
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Disable the DMA transfer for the receiver request by resetting the DMAR bit
in the UART CR3 register */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_DMAR);
/* At end of Rx process, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
/* If Reception till IDLE event has been selected, Disable IDLE Interrupt */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
}
}
/* Initialize type of RxEvent that correspond to RxEvent callback execution;
In this case, Rx Event type is Transfer Complete */
huart->RxEventType = HAL_UART_RXEVENT_TC;
/* Check current reception Mode :
If Reception till IDLE event has been selected : use Rx Event callback */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Event callback*/
huart->RxEventCallback(huart, huart->RxXferSize);
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, huart->RxXferSize);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
else
{
/* In other cases : use Rx Complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx complete callback*/
huart->RxCpltCallback(huart);
#else
/*Call legacy weak Rx complete callback*/
HAL_UART_RxCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
/**
* @brief DMA UART receive process half complete callback.
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMARxHalfCplt(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
/* Initialize type of RxEvent that correspond to RxEvent callback execution;
In this case, Rx Event type is Half Transfer */
huart->RxEventType = HAL_UART_RXEVENT_HT;
/* Check current reception Mode :
If Reception till IDLE event has been selected : use Rx Event callback */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Event callback*/
huart->RxEventCallback(huart, huart->RxXferSize / 2U);
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, huart->RxXferSize / 2U);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
else
{
/* In other cases : use Rx Half Complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Half complete callback*/
huart->RxHalfCpltCallback(huart);
#else
/*Call legacy weak Rx Half complete callback*/
HAL_UART_RxHalfCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
/**
* @brief DMA UART communication error callback.
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMAError(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
const HAL_UART_StateTypeDef gstate = huart->gState;
const HAL_UART_StateTypeDef rxstate = huart->RxState;
/* Stop UART DMA Tx request if ongoing */
if ((HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAT)) &&
(gstate == HAL_UART_STATE_BUSY_TX))
{
huart->TxXferCount = 0U;
UART_EndTxTransfer(huart);
}
/* Stop UART DMA Rx request if ongoing */
if ((HAL_IS_BIT_SET(huart->Instance->CR3, USART_CR3_DMAR)) &&
(rxstate == HAL_UART_STATE_BUSY_RX))
{
huart->RxXferCount = 0U;
UART_EndRxTransfer(huart);
}
huart->ErrorCode |= HAL_UART_ERROR_DMA;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
huart->ErrorCallback(huart);
#else
/*Call legacy weak error callback*/
HAL_UART_ErrorCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief DMA UART communication abort callback, when initiated by HAL services on Error
* (To be called at end of DMA Abort procedure following error occurrence).
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMAAbortOnError(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
huart->RxXferCount = 0U;
huart->TxXferCount = 0U;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
huart->ErrorCallback(huart);
#else
/*Call legacy weak error callback*/
HAL_UART_ErrorCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief DMA UART Tx communication abort callback, when initiated by user
* (To be called at end of DMA Tx Abort procedure following user abort request).
* @note When this callback is executed, User Abort complete call back is called only if no
* Abort still ongoing for Rx DMA Handle.
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMATxAbortCallback(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
huart->hdmatx->XferAbortCallback = NULL;
/* Check if an Abort process is still ongoing */
if (huart->hdmarx != NULL)
{
if (huart->hdmarx->XferAbortCallback != NULL)
{
return;
}
}
/* No Abort process still ongoing : All DMA channels are aborted, call user Abort Complete callback */
huart->TxXferCount = 0U;
huart->RxXferCount = 0U;
/* Reset errorCode */
huart->ErrorCode = HAL_UART_ERROR_NONE;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Flush the whole TX FIFO (if needed) */
if (huart->FifoMode == UART_FIFOMODE_ENABLE)
{
__HAL_UART_SEND_REQ(huart, UART_TXDATA_FLUSH_REQUEST);
}
/* Restore huart->gState and huart->RxState to Ready */
huart->gState = HAL_UART_STATE_READY;
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Call user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort complete callback */
huart->AbortCpltCallback(huart);
#else
/* Call legacy weak Abort complete callback */
HAL_UART_AbortCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief DMA UART Rx communication abort callback, when initiated by user
* (To be called at end of DMA Rx Abort procedure following user abort request).
* @note When this callback is executed, User Abort complete call back is called only if no
* Abort still ongoing for Tx DMA Handle.
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMARxAbortCallback(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
huart->hdmarx->XferAbortCallback = NULL;
/* Check if an Abort process is still ongoing */
if (huart->hdmatx != NULL)
{
if (huart->hdmatx->XferAbortCallback != NULL)
{
return;
}
}
/* No Abort process still ongoing : All DMA channels are aborted, call user Abort Complete callback */
huart->TxXferCount = 0U;
huart->RxXferCount = 0U;
/* Reset errorCode */
huart->ErrorCode = HAL_UART_ERROR_NONE;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Discard the received data */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
/* Restore huart->gState and huart->RxState to Ready */
huart->gState = HAL_UART_STATE_READY;
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Call user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort complete callback */
huart->AbortCpltCallback(huart);
#else
/* Call legacy weak Abort complete callback */
HAL_UART_AbortCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief DMA UART Tx communication abort callback, when initiated by user by a call to
* HAL_UART_AbortTransmit_IT API (Abort only Tx transfer)
* (This callback is executed at end of DMA Tx Abort procedure following user abort request,
* and leads to user Tx Abort Complete callback execution).
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMATxOnlyAbortCallback(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)(hdma->Parent);
huart->TxXferCount = 0U;
/* Flush the whole TX FIFO (if needed) */
if (huart->FifoMode == UART_FIFOMODE_ENABLE)
{
__HAL_UART_SEND_REQ(huart, UART_TXDATA_FLUSH_REQUEST);
}
/* Restore huart->gState to Ready */
huart->gState = HAL_UART_STATE_READY;
/* Call user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort Transmit Complete Callback */
huart->AbortTransmitCpltCallback(huart);
#else
/* Call legacy weak Abort Transmit Complete Callback */
HAL_UART_AbortTransmitCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief DMA UART Rx communication abort callback, when initiated by user by a call to
* HAL_UART_AbortReceive_IT API (Abort only Rx transfer)
* (This callback is executed at end of DMA Rx Abort procedure following user abort request,
* and leads to user Rx Abort Complete callback execution).
* @param hdma DMA handle.
* @retval None
*/
static void UART_DMARxOnlyAbortCallback(DMA_HandleTypeDef *hdma)
{
UART_HandleTypeDef *huart = (UART_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
huart->RxXferCount = 0U;
/* Clear the Error flags in the ICR register */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_OREF | UART_CLEAR_NEF | UART_CLEAR_PEF | UART_CLEAR_FEF);
/* Discard the received data */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
/* Restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Call user Abort complete callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/* Call registered Abort Receive Complete Callback */
huart->AbortReceiveCpltCallback(huart);
#else
/* Call legacy weak Abort Receive Complete Callback */
HAL_UART_AbortReceiveCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief TX interrupt handler for 7 or 8 bits data word length .
* @note Function is called under interruption only, once
* interruptions have been enabled by HAL_UART_Transmit_IT().
* @param huart UART handle.
* @retval None
*/
static void UART_TxISR_8BIT(UART_HandleTypeDef *huart)
{
/* Check that a Tx process is ongoing */
if (huart->gState == HAL_UART_STATE_BUSY_TX)
{
if (huart->TxXferCount == 0U)
{
/* Disable the UART Transmit Data Register Empty Interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_TXEIE_TXFNFIE);
/* Enable the UART Transmit Complete Interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_TCIE);
}
else
{
huart->Instance->TDR = (uint8_t)(*huart->pTxBuffPtr & (uint8_t)0xFF);
huart->pTxBuffPtr++;
huart->TxXferCount--;
}
}
}
/**
* @brief TX interrupt handler for 9 bits data word length.
* @note Function is called under interruption only, once
* interruptions have been enabled by HAL_UART_Transmit_IT().
* @param huart UART handle.
* @retval None
*/
static void UART_TxISR_16BIT(UART_HandleTypeDef *huart)
{
const uint16_t *tmp;
/* Check that a Tx process is ongoing */
if (huart->gState == HAL_UART_STATE_BUSY_TX)
{
if (huart->TxXferCount == 0U)
{
/* Disable the UART Transmit Data Register Empty Interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_TXEIE_TXFNFIE);
/* Enable the UART Transmit Complete Interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_TCIE);
}
else
{
tmp = (const uint16_t *) huart->pTxBuffPtr;
huart->Instance->TDR = (((uint32_t)(*tmp)) & 0x01FFUL);
huart->pTxBuffPtr += 2U;
huart->TxXferCount--;
}
}
}
/**
* @brief TX interrupt handler for 7 or 8 bits data word length and FIFO mode is enabled.
* @note Function is called under interruption only, once
* interruptions have been enabled by HAL_UART_Transmit_IT().
* @param huart UART handle.
* @retval None
*/
static void UART_TxISR_8BIT_FIFOEN(UART_HandleTypeDef *huart)
{
uint16_t nb_tx_data;
/* Check that a Tx process is ongoing */
if (huart->gState == HAL_UART_STATE_BUSY_TX)
{
for (nb_tx_data = huart->NbTxDataToProcess ; nb_tx_data > 0U ; nb_tx_data--)
{
if (huart->TxXferCount == 0U)
{
/* Disable the TX FIFO threshold interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_TXFTIE);
/* Enable the UART Transmit Complete Interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_TCIE);
break; /* force exit loop */
}
else if (READ_BIT(huart->Instance->ISR, USART_ISR_TXE_TXFNF) != 0U)
{
huart->Instance->TDR = (uint8_t)(*huart->pTxBuffPtr & (uint8_t)0xFF);
huart->pTxBuffPtr++;
huart->TxXferCount--;
}
else
{
/* Nothing to do */
}
}
}
}
/**
* @brief TX interrupt handler for 9 bits data word length and FIFO mode is enabled.
* @note Function is called under interruption only, once
* interruptions have been enabled by HAL_UART_Transmit_IT().
* @param huart UART handle.
* @retval None
*/
static void UART_TxISR_16BIT_FIFOEN(UART_HandleTypeDef *huart)
{
const uint16_t *tmp;
uint16_t nb_tx_data;
/* Check that a Tx process is ongoing */
if (huart->gState == HAL_UART_STATE_BUSY_TX)
{
for (nb_tx_data = huart->NbTxDataToProcess ; nb_tx_data > 0U ; nb_tx_data--)
{
if (huart->TxXferCount == 0U)
{
/* Disable the TX FIFO threshold interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_TXFTIE);
/* Enable the UART Transmit Complete Interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_TCIE);
break; /* force exit loop */
}
else if (READ_BIT(huart->Instance->ISR, USART_ISR_TXE_TXFNF) != 0U)
{
tmp = (const uint16_t *) huart->pTxBuffPtr;
huart->Instance->TDR = (((uint32_t)(*tmp)) & 0x01FFUL);
huart->pTxBuffPtr += 2U;
huart->TxXferCount--;
}
else
{
/* Nothing to do */
}
}
}
}
/**
* @brief Wrap up transmission in non-blocking mode.
* @param huart pointer to a UART_HandleTypeDef structure that contains
* the configuration information for the specified UART module.
* @retval None
*/
static void UART_EndTransmit_IT(UART_HandleTypeDef *huart)
{
/* Disable the UART Transmit Complete Interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_TCIE);
/* Tx process is ended, restore huart->gState to Ready */
huart->gState = HAL_UART_STATE_READY;
/* Cleat TxISR function pointer */
huart->TxISR = NULL;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Tx complete callback*/
huart->TxCpltCallback(huart);
#else
/*Call legacy weak Tx complete callback*/
HAL_UART_TxCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
/**
* @brief RX interrupt handler for 7 or 8 bits data word length .
* @param huart UART handle.
* @retval None
*/
static void UART_RxISR_8BIT(UART_HandleTypeDef *huart)
{
uint16_t uhMask = huart->Mask;
uint16_t uhdata;
/* Check that a Rx process is ongoing */
if (huart->RxState == HAL_UART_STATE_BUSY_RX)
{
uhdata = (uint16_t) READ_REG(huart->Instance->RDR);
*huart->pRxBuffPtr = (uint8_t)(uhdata & (uint8_t)uhMask);
huart->pRxBuffPtr++;
huart->RxXferCount--;
if (huart->RxXferCount == 0U)
{
/* Disable the UART Parity Error Interrupt and RXNE interrupts */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_RXNEIE_RXFNEIE | USART_CR1_PEIE));
/* Disable the UART Error Interrupt: (Frame error, noise error, overrun error) */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Rx process is completed, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
/* Clear RxISR function pointer */
huart->RxISR = NULL;
/* Initialize type of RxEvent to Transfer Complete */
huart->RxEventType = HAL_UART_RXEVENT_TC;
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
/* Check that USART RTOEN bit is set */
if (READ_BIT(huart->Instance->CR2, USART_CR2_RTOEN) != 0U)
{
/* Enable the UART Receiver Timeout Interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_RTOIE);
}
}
/* Check current reception Mode :
If Reception till IDLE event has been selected : */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
/* Set reception type to Standard */
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Disable IDLE interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_IDLE) == SET)
{
/* Clear IDLE Flag */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
}
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Event callback*/
huart->RxEventCallback(huart, huart->RxXferSize);
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, huart->RxXferSize);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
else
{
/* Standard reception API called */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx complete callback*/
huart->RxCpltCallback(huart);
#else
/*Call legacy weak Rx complete callback*/
HAL_UART_RxCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
}
else
{
/* Clear RXNE interrupt flag */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
}
}
/**
* @brief RX interrupt handler for 9 bits data word length .
* @note Function is called under interruption only, once
* interruptions have been enabled by HAL_UART_Receive_IT()
* @param huart UART handle.
* @retval None
*/
static void UART_RxISR_16BIT(UART_HandleTypeDef *huart)
{
uint16_t *tmp;
uint16_t uhMask = huart->Mask;
uint16_t uhdata;
/* Check that a Rx process is ongoing */
if (huart->RxState == HAL_UART_STATE_BUSY_RX)
{
uhdata = (uint16_t) READ_REG(huart->Instance->RDR);
tmp = (uint16_t *) huart->pRxBuffPtr ;
*tmp = (uint16_t)(uhdata & uhMask);
huart->pRxBuffPtr += 2U;
huart->RxXferCount--;
if (huart->RxXferCount == 0U)
{
/* Disable the UART Parity Error Interrupt and RXNE interrupt*/
ATOMIC_CLEAR_BIT(huart->Instance->CR1, (USART_CR1_RXNEIE_RXFNEIE | USART_CR1_PEIE));
/* Disable the UART Error Interrupt: (Frame error, noise error, overrun error) */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_EIE);
/* Rx process is completed, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
/* Clear RxISR function pointer */
huart->RxISR = NULL;
/* Initialize type of RxEvent to Transfer Complete */
huart->RxEventType = HAL_UART_RXEVENT_TC;
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
/* Check that USART RTOEN bit is set */
if (READ_BIT(huart->Instance->CR2, USART_CR2_RTOEN) != 0U)
{
/* Enable the UART Receiver Timeout Interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_RTOIE);
}
}
/* Check current reception Mode :
If Reception till IDLE event has been selected : */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
/* Set reception type to Standard */
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Disable IDLE interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_IDLE) == SET)
{
/* Clear IDLE Flag */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
}
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Event callback*/
huart->RxEventCallback(huart, huart->RxXferSize);
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, huart->RxXferSize);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
else
{
/* Standard reception API called */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx complete callback*/
huart->RxCpltCallback(huart);
#else
/*Call legacy weak Rx complete callback*/
HAL_UART_RxCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
}
else
{
/* Clear RXNE interrupt flag */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
}
}
/**
* @brief RX interrupt handler for 7 or 8 bits data word length and FIFO mode is enabled.
* @note Function is called under interruption only, once
* interruptions have been enabled by HAL_UART_Receive_IT()
* @param huart UART handle.
* @retval None
*/
static void UART_RxISR_8BIT_FIFOEN(UART_HandleTypeDef *huart)
{
uint16_t uhMask = huart->Mask;
uint16_t uhdata;
uint16_t nb_rx_data;
uint16_t rxdatacount;
uint32_t isrflags = READ_REG(huart->Instance->ISR);
uint32_t cr1its = READ_REG(huart->Instance->CR1);
uint32_t cr3its = READ_REG(huart->Instance->CR3);
/* Check that a Rx process is ongoing */
if (huart->RxState == HAL_UART_STATE_BUSY_RX)
{
nb_rx_data = huart->NbRxDataToProcess;
while ((nb_rx_data > 0U) && ((isrflags & USART_ISR_RXNE_RXFNE) != 0U))
{
uhdata = (uint16_t) READ_REG(huart->Instance->RDR);
*huart->pRxBuffPtr = (uint8_t)(uhdata & (uint8_t)uhMask);
huart->pRxBuffPtr++;
huart->RxXferCount--;
isrflags = READ_REG(huart->Instance->ISR);
/* If some non blocking errors occurred */
if ((isrflags & (USART_ISR_PE | USART_ISR_FE | USART_ISR_NE)) != 0U)
{
/* UART parity error interrupt occurred -------------------------------------*/
if (((isrflags & USART_ISR_PE) != 0U) && ((cr1its & USART_CR1_PEIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_PEF);
huart->ErrorCode |= HAL_UART_ERROR_PE;
}
/* UART frame error interrupt occurred --------------------------------------*/
if (((isrflags & USART_ISR_FE) != 0U) && ((cr3its & USART_CR3_EIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_FEF);
huart->ErrorCode |= HAL_UART_ERROR_FE;
}
/* UART noise error interrupt occurred --------------------------------------*/
if (((isrflags & USART_ISR_NE) != 0U) && ((cr3its & USART_CR3_EIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_NEF);
huart->ErrorCode |= HAL_UART_ERROR_NE;
}
/* Call UART Error Call back function if need be ----------------------------*/
if (huart->ErrorCode != HAL_UART_ERROR_NONE)
{
/* Non Blocking error : transfer could go on.
Error is notified to user through user error callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
huart->ErrorCallback(huart);
#else
/*Call legacy weak error callback*/
HAL_UART_ErrorCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
huart->ErrorCode = HAL_UART_ERROR_NONE;
}
}
if (huart->RxXferCount == 0U)
{
/* Disable the UART Parity Error Interrupt and RXFT interrupt*/
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_PEIE);
/* Disable the UART Error Interrupt: (Frame error, noise error, overrun error)
and RX FIFO Threshold interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, (USART_CR3_EIE | USART_CR3_RXFTIE));
/* Rx process is completed, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
/* Clear RxISR function pointer */
huart->RxISR = NULL;
/* Initialize type of RxEvent to Transfer Complete */
huart->RxEventType = HAL_UART_RXEVENT_TC;
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
/* Check that USART RTOEN bit is set */
if (READ_BIT(huart->Instance->CR2, USART_CR2_RTOEN) != 0U)
{
/* Enable the UART Receiver Timeout Interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_RTOIE);
}
}
/* Check current reception Mode :
If Reception till IDLE event has been selected : */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
/* Set reception type to Standard */
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Disable IDLE interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_IDLE) == SET)
{
/* Clear IDLE Flag */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
}
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Event callback*/
huart->RxEventCallback(huart, huart->RxXferSize);
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, huart->RxXferSize);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
else
{
/* Standard reception API called */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx complete callback*/
huart->RxCpltCallback(huart);
#else
/*Call legacy weak Rx complete callback*/
HAL_UART_RxCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
}
/* When remaining number of bytes to receive is less than the RX FIFO
threshold, next incoming frames are processed as if FIFO mode was
disabled (i.e. one interrupt per received frame).
*/
rxdatacount = huart->RxXferCount;
if ((rxdatacount != 0U) && (rxdatacount < huart->NbRxDataToProcess))
{
/* Disable the UART RXFT interrupt*/
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_RXFTIE);
/* Update the RxISR function pointer */
huart->RxISR = UART_RxISR_8BIT;
/* Enable the UART Data Register Not Empty interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_RXNEIE_RXFNEIE);
}
}
else
{
/* Clear RXNE interrupt flag */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
}
}
/**
* @brief RX interrupt handler for 9 bits data word length and FIFO mode is enabled.
* @note Function is called under interruption only, once
* interruptions have been enabled by HAL_UART_Receive_IT()
* @param huart UART handle.
* @retval None
*/
static void UART_RxISR_16BIT_FIFOEN(UART_HandleTypeDef *huart)
{
uint16_t *tmp;
uint16_t uhMask = huart->Mask;
uint16_t uhdata;
uint16_t nb_rx_data;
uint16_t rxdatacount;
uint32_t isrflags = READ_REG(huart->Instance->ISR);
uint32_t cr1its = READ_REG(huart->Instance->CR1);
uint32_t cr3its = READ_REG(huart->Instance->CR3);
/* Check that a Rx process is ongoing */
if (huart->RxState == HAL_UART_STATE_BUSY_RX)
{
nb_rx_data = huart->NbRxDataToProcess;
while ((nb_rx_data > 0U) && ((isrflags & USART_ISR_RXNE_RXFNE) != 0U))
{
uhdata = (uint16_t) READ_REG(huart->Instance->RDR);
tmp = (uint16_t *) huart->pRxBuffPtr ;
*tmp = (uint16_t)(uhdata & uhMask);
huart->pRxBuffPtr += 2U;
huart->RxXferCount--;
isrflags = READ_REG(huart->Instance->ISR);
/* If some non blocking errors occurred */
if ((isrflags & (USART_ISR_PE | USART_ISR_FE | USART_ISR_NE)) != 0U)
{
/* UART parity error interrupt occurred -------------------------------------*/
if (((isrflags & USART_ISR_PE) != 0U) && ((cr1its & USART_CR1_PEIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_PEF);
huart->ErrorCode |= HAL_UART_ERROR_PE;
}
/* UART frame error interrupt occurred --------------------------------------*/
if (((isrflags & USART_ISR_FE) != 0U) && ((cr3its & USART_CR3_EIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_FEF);
huart->ErrorCode |= HAL_UART_ERROR_FE;
}
/* UART noise error interrupt occurred --------------------------------------*/
if (((isrflags & USART_ISR_NE) != 0U) && ((cr3its & USART_CR3_EIE) != 0U))
{
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_NEF);
huart->ErrorCode |= HAL_UART_ERROR_NE;
}
/* Call UART Error Call back function if need be ----------------------------*/
if (huart->ErrorCode != HAL_UART_ERROR_NONE)
{
/* Non Blocking error : transfer could go on.
Error is notified to user through user error callback */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
huart->ErrorCallback(huart);
#else
/*Call legacy weak error callback*/
HAL_UART_ErrorCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
huart->ErrorCode = HAL_UART_ERROR_NONE;
}
}
if (huart->RxXferCount == 0U)
{
/* Disable the UART Parity Error Interrupt and RXFT interrupt*/
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_PEIE);
/* Disable the UART Error Interrupt: (Frame error, noise error, overrun error)
and RX FIFO Threshold interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR3, (USART_CR3_EIE | USART_CR3_RXFTIE));
/* Rx process is completed, restore huart->RxState to Ready */
huart->RxState = HAL_UART_STATE_READY;
/* Clear RxISR function pointer */
huart->RxISR = NULL;
/* Initialize type of RxEvent to Transfer Complete */
huart->RxEventType = HAL_UART_RXEVENT_TC;
if (!(IS_LPUART_INSTANCE(huart->Instance)))
{
/* Check that USART RTOEN bit is set */
if (READ_BIT(huart->Instance->CR2, USART_CR2_RTOEN) != 0U)
{
/* Enable the UART Receiver Timeout Interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_RTOIE);
}
}
/* Check current reception Mode :
If Reception till IDLE event has been selected : */
if (huart->ReceptionType == HAL_UART_RECEPTION_TOIDLE)
{
/* Set reception type to Standard */
huart->ReceptionType = HAL_UART_RECEPTION_STANDARD;
/* Disable IDLE interrupt */
ATOMIC_CLEAR_BIT(huart->Instance->CR1, USART_CR1_IDLEIE);
if (__HAL_UART_GET_FLAG(huart, UART_FLAG_IDLE) == SET)
{
/* Clear IDLE Flag */
__HAL_UART_CLEAR_FLAG(huart, UART_CLEAR_IDLEF);
}
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx Event callback*/
huart->RxEventCallback(huart, huart->RxXferSize);
#else
/*Call legacy weak Rx Event callback*/
HAL_UARTEx_RxEventCallback(huart, huart->RxXferSize);
#endif /* (USE_HAL_UART_REGISTER_CALLBACKS) */
}
else
{
/* Standard reception API called */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/*Call registered Rx complete callback*/
huart->RxCpltCallback(huart);
#else
/*Call legacy weak Rx complete callback*/
HAL_UART_RxCpltCallback(huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
}
}
}
/* When remaining number of bytes to receive is less than the RX FIFO
threshold, next incoming frames are processed as if FIFO mode was
disabled (i.e. one interrupt per received frame).
*/
rxdatacount = huart->RxXferCount;
if ((rxdatacount != 0U) && (rxdatacount < huart->NbRxDataToProcess))
{
/* Disable the UART RXFT interrupt*/
ATOMIC_CLEAR_BIT(huart->Instance->CR3, USART_CR3_RXFTIE);
/* Update the RxISR function pointer */
huart->RxISR = UART_RxISR_16BIT;
/* Enable the UART Data Register Not Empty interrupt */
ATOMIC_SET_BIT(huart->Instance->CR1, USART_CR1_RXNEIE_RXFNEIE);
}
}
else
{
/* Clear RXNE interrupt flag */
__HAL_UART_SEND_REQ(huart, UART_RXDATA_FLUSH_REQUEST);
}
}
/**
* @}
*/
#endif /* HAL_UART_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 158,960 | C | 33.016906 | 147 | 0.630769 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_tim_ex.c | /**
******************************************************************************
* @file stm32g4xx_hal_tim_ex.c
* @author MCD Application Team
* @brief TIM HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Timer Extended peripheral:
* + Time Hall Sensor Interface Initialization
* + Time Hall Sensor Interface Start
* + Time Complementary signal break and dead time configuration
* + Time Master and Slave synchronization configuration
* + Time Output Compare/PWM Channel Configuration (for channels 5 and 6)
* + Time OCRef clear configuration
* + Timer remapping capabilities configuration
* + Timer encoder index configuration
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### TIMER Extended features #####
==============================================================================
[..]
The Timer Extended features include:
(#) Complementary outputs with programmable dead-time for :
(++) Output Compare
(++) PWM generation (Edge and Center-aligned Mode)
(++) One-pulse mode output
(#) Synchronization circuit to control the timer with external signals and to
interconnect several timers together.
(#) Break input to put the timer output signals in reset state or in a known state.
(#) Supports incremental (quadrature) encoder and hall-sensor circuitry for
positioning purposes
(#) In case of Pulse on compare, configure pulse length and delay
(#) Encoder index configuration
##### How to use this driver #####
==============================================================================
[..]
(#) Initialize the TIM low level resources by implementing the following functions
depending on the selected feature:
(++) Hall Sensor output : HAL_TIMEx_HallSensor_MspInit()
(#) Initialize the TIM low level resources :
(##) Enable the TIM interface clock using __HAL_RCC_TIMx_CLK_ENABLE();
(##) TIM pins configuration
(+++) Enable the clock for the TIM GPIOs using the following function:
__HAL_RCC_GPIOx_CLK_ENABLE();
(+++) Configure these TIM pins in Alternate function mode using HAL_GPIO_Init();
(#) The external Clock can be configured, if needed (the default clock is the
internal clock from the APBx), using the following function:
HAL_TIM_ConfigClockSource, the clock configuration should be done before
any start function.
(#) Configure the TIM in the desired functioning mode using one of the
initialization function of this driver:
(++) HAL_TIMEx_HallSensor_Init() and HAL_TIMEx_ConfigCommutEvent(): to use the
Timer Hall Sensor Interface and the commutation event with the corresponding
Interrupt and DMA request if needed (Note that One Timer is used to interface
with the Hall sensor Interface and another Timer should be used to use
the commutation event).
(#) In case of Pulse On Compare:
(++) HAL_TIMEx_OC_ConfigPulseOnCompare(): to configure pulse width and prescaler
(#) Activate the TIM peripheral using one of the start functions:
(++) Complementary Output Compare : HAL_TIMEx_OCN_Start(), HAL_TIMEx_OCN_Start_DMA(),
HAL_TIMEx_OCN_Start_IT()
(++) Complementary PWM generation : HAL_TIMEx_PWMN_Start(), HAL_TIMEx_PWMN_Start_DMA(),
HAL_TIMEx_PWMN_Start_IT()
(++) Complementary One-pulse mode output : HAL_TIMEx_OnePulseN_Start(), HAL_TIMEx_OnePulseN_Start_IT()
(++) Hall Sensor output : HAL_TIMEx_HallSensor_Start(), HAL_TIMEx_HallSensor_Start_DMA(),
HAL_TIMEx_HallSensor_Start_IT().
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup TIMEx TIMEx
* @brief TIM Extended HAL module driver
* @{
*/
#ifdef HAL_TIM_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup TIMEx_Private_Constants TIM Extended Private Constants
* @{
*/
/* Timeout for break input rearm */
#define TIM_BREAKINPUT_REARM_TIMEOUT 5UL /* 5 milliseconds */
/**
* @}
*/
/* End of private constants --------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
static void TIM_DMADelayPulseNCplt(DMA_HandleTypeDef *hdma);
static void TIM_DMAErrorCCxN(DMA_HandleTypeDef *hdma);
static void TIM_CCxNChannelCmd(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ChannelNState);
/* Exported functions --------------------------------------------------------*/
/** @defgroup TIMEx_Exported_Functions TIM Extended Exported Functions
* @{
*/
/** @defgroup TIMEx_Exported_Functions_Group1 Extended Timer Hall Sensor functions
* @brief Timer Hall Sensor functions
*
@verbatim
==============================================================================
##### Timer Hall Sensor functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Initialize and configure TIM HAL Sensor.
(+) De-initialize TIM HAL Sensor.
(+) Start the Hall Sensor Interface.
(+) Stop the Hall Sensor Interface.
(+) Start the Hall Sensor Interface and enable interrupts.
(+) Stop the Hall Sensor Interface and disable interrupts.
(+) Start the Hall Sensor Interface and enable DMA transfers.
(+) Stop the Hall Sensor Interface and disable DMA transfers.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM Hall Sensor Interface and initialize the associated handle.
* @note When the timer instance is initialized in Hall Sensor Interface mode,
* timer channels 1 and channel 2 are reserved and cannot be used for
* other purpose.
* @param htim TIM Hall Sensor Interface handle
* @param sConfig TIM Hall Sensor configuration structure
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Init(TIM_HandleTypeDef *htim, const TIM_HallSensor_InitTypeDef *sConfig)
{
TIM_OC_InitTypeDef OC_Config;
/* Check the TIM handle allocation */
if (htim == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(htim->Instance));
assert_param(IS_TIM_COUNTER_MODE(htim->Init.CounterMode));
assert_param(IS_TIM_CLOCKDIVISION_DIV(htim->Init.ClockDivision));
assert_param(IS_TIM_AUTORELOAD_PRELOAD(htim->Init.AutoReloadPreload));
assert_param(IS_TIM_IC_POLARITY(sConfig->IC1Polarity));
assert_param(IS_TIM_PERIOD(htim, htim->Init.Period));
assert_param(IS_TIM_IC_PRESCALER(sConfig->IC1Prescaler));
assert_param(IS_TIM_IC_FILTER(sConfig->IC1Filter));
if (htim->State == HAL_TIM_STATE_RESET)
{
/* Allocate lock resource and initialize it */
htim->Lock = HAL_UNLOCKED;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/* Reset interrupt callbacks to legacy week callbacks */
TIM_ResetCallback(htim);
if (htim->HallSensor_MspInitCallback == NULL)
{
htim->HallSensor_MspInitCallback = HAL_TIMEx_HallSensor_MspInit;
}
/* Init the low level hardware : GPIO, CLOCK, NVIC */
htim->HallSensor_MspInitCallback(htim);
#else
/* Init the low level hardware : GPIO, CLOCK, NVIC and DMA */
HAL_TIMEx_HallSensor_MspInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Configure the Time base in the Encoder Mode */
TIM_Base_SetConfig(htim->Instance, &htim->Init);
/* Configure the Channel 1 as Input Channel to interface with the three Outputs of the Hall sensor */
TIM_TI1_SetConfig(htim->Instance, sConfig->IC1Polarity, TIM_ICSELECTION_TRC, sConfig->IC1Filter);
/* Reset the IC1PSC Bits */
htim->Instance->CCMR1 &= ~TIM_CCMR1_IC1PSC;
/* Set the IC1PSC value */
htim->Instance->CCMR1 |= sConfig->IC1Prescaler;
/* Enable the Hall sensor interface (XOR function of the three inputs) */
htim->Instance->CR2 |= TIM_CR2_TI1S;
/* Select the TIM_TS_TI1F_ED signal as Input trigger for the TIM */
htim->Instance->SMCR &= ~TIM_SMCR_TS;
htim->Instance->SMCR |= TIM_TS_TI1F_ED;
/* Use the TIM_TS_TI1F_ED signal to reset the TIM counter each edge detection */
htim->Instance->SMCR &= ~TIM_SMCR_SMS;
htim->Instance->SMCR |= TIM_SLAVEMODE_RESET;
/* Program channel 2 in PWM 2 mode with the desired Commutation_Delay*/
OC_Config.OCFastMode = TIM_OCFAST_DISABLE;
OC_Config.OCIdleState = TIM_OCIDLESTATE_RESET;
OC_Config.OCMode = TIM_OCMODE_PWM2;
OC_Config.OCNIdleState = TIM_OCNIDLESTATE_RESET;
OC_Config.OCNPolarity = TIM_OCNPOLARITY_HIGH;
OC_Config.OCPolarity = TIM_OCPOLARITY_HIGH;
OC_Config.Pulse = sConfig->Commutation_Delay;
TIM_OC2_SetConfig(htim->Instance, &OC_Config);
/* Select OC2REF as trigger output on TRGO: write the MMS bits in the TIMx_CR2
register to 101 */
htim->Instance->CR2 &= ~TIM_CR2_MMS;
htim->Instance->CR2 |= TIM_TRGO_OC2REF;
/* Initialize the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
/* Initialize the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Initialize the TIM state*/
htim->State = HAL_TIM_STATE_READY;
return HAL_OK;
}
/**
* @brief DeInitializes the TIM Hall Sensor interface
* @param htim TIM Hall Sensor Interface handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_DeInit(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
htim->State = HAL_TIM_STATE_BUSY;
/* Disable the TIM Peripheral Clock */
__HAL_TIM_DISABLE(htim);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
if (htim->HallSensor_MspDeInitCallback == NULL)
{
htim->HallSensor_MspDeInitCallback = HAL_TIMEx_HallSensor_MspDeInit;
}
/* DeInit the low level hardware */
htim->HallSensor_MspDeInitCallback(htim);
#else
/* DeInit the low level hardware: GPIO, CLOCK, NVIC */
HAL_TIMEx_HallSensor_MspDeInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_RESET;
/* Change the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_RESET);
/* Change TIM state */
htim->State = HAL_TIM_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Initializes the TIM Hall Sensor MSP.
* @param htim TIM Hall Sensor Interface handle
* @retval None
*/
__weak void HAL_TIMEx_HallSensor_MspInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_HallSensor_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes TIM Hall Sensor MSP.
* @param htim TIM Hall Sensor Interface handle
* @retval None
*/
__weak void HAL_TIMEx_HallSensor_MspDeInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_HallSensor_MspDeInit could be implemented in the user file
*/
}
/**
* @brief Starts the TIM Hall Sensor Interface.
* @param htim TIM Hall Sensor Interface handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start(TIM_HandleTypeDef *htim)
{
uint32_t tmpsmcr;
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Check the parameters */
assert_param(IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(htim->Instance));
/* Check the TIM channels state */
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the Input Capture channel 1
(in the Hall Sensor Interface the three possible channels that can be used are TIM_CHANNEL_1,
TIM_CHANNEL_2 and TIM_CHANNEL_3) */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Hall sensor Interface.
* @param htim TIM Hall Sensor Interface handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(htim->Instance));
/* Disable the Input Capture channels 1, 2 and 3
(in the Hall Sensor Interface the three possible channels that can be used are TIM_CHANNEL_1,
TIM_CHANNEL_2 and TIM_CHANNEL_3) */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Hall Sensor Interface in interrupt mode.
* @param htim TIM Hall Sensor Interface handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start_IT(TIM_HandleTypeDef *htim)
{
uint32_t tmpsmcr;
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Check the parameters */
assert_param(IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(htim->Instance));
/* Check the TIM channels state */
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the capture compare Interrupts 1 event */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
/* Enable the Input Capture channel 1
(in the Hall Sensor Interface the three possible channels that can be used are TIM_CHANNEL_1,
TIM_CHANNEL_2 and TIM_CHANNEL_3) */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Hall Sensor Interface in interrupt mode.
* @param htim TIM Hall Sensor Interface handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop_IT(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(htim->Instance));
/* Disable the Input Capture channel 1
(in the Hall Sensor Interface the three possible channels that can be used are TIM_CHANNEL_1,
TIM_CHANNEL_2 and TIM_CHANNEL_3) */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
/* Disable the capture compare Interrupts event */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Hall Sensor Interface in DMA mode.
* @param htim TIM Hall Sensor Interface handle
* @param pData The destination Buffer address.
* @param Length The length of data to be transferred from TIM peripheral to memory.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start_DMA(TIM_HandleTypeDef *htim, uint32_t *pData, uint16_t Length)
{
uint32_t tmpsmcr;
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
/* Check the parameters */
assert_param(IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(htim->Instance));
/* Set the TIM channel state */
if ((channel_1_state == HAL_TIM_CHANNEL_STATE_BUSY)
|| (complementary_channel_1_state == HAL_TIM_CHANNEL_STATE_BUSY))
{
return HAL_BUSY;
}
else if ((channel_1_state == HAL_TIM_CHANNEL_STATE_READY)
&& (complementary_channel_1_state == HAL_TIM_CHANNEL_STATE_READY))
{
if ((pData == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
/* Enable the Input Capture channel 1
(in the Hall Sensor Interface the three possible channels that can be used are TIM_CHANNEL_1,
TIM_CHANNEL_2 and TIM_CHANNEL_3) */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
/* Set the DMA Input Capture 1 Callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel for Capture 1*/
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)&htim->Instance->CCR1, (uint32_t)pData, Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the capture compare 1 Interrupt */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Hall Sensor Interface in DMA mode.
* @param htim TIM Hall Sensor Interface handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop_DMA(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(htim->Instance));
/* Disable the Input Capture channel 1
(in the Hall Sensor Interface the three possible channels that can be used are TIM_CHANNEL_1,
TIM_CHANNEL_2 and TIM_CHANNEL_3) */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
/* Disable the capture compare Interrupts 1 event */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @}
*/
/** @defgroup TIMEx_Exported_Functions_Group2 Extended Timer Complementary Output Compare functions
* @brief Timer Complementary Output Compare functions
*
@verbatim
==============================================================================
##### Timer Complementary Output Compare functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Start the Complementary Output Compare/PWM.
(+) Stop the Complementary Output Compare/PWM.
(+) Start the Complementary Output Compare/PWM and enable interrupts.
(+) Stop the Complementary Output Compare/PWM and disable interrupts.
(+) Start the Complementary Output Compare/PWM and enable DMA transfers.
(+) Stop the Complementary Output Compare/PWM and disable DMA transfers.
@endverbatim
* @{
*/
/**
* @brief Starts the TIM Output Compare signal generation on the complementary
* output.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OCN_Start(TIM_HandleTypeDef *htim, uint32_t Channel)
{
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Check the TIM complementary channel state */
if (TIM_CHANNEL_N_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the Capture compare channel N */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Output Compare signal generation on the complementary
* output.
* @param htim TIM handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Disable the Capture compare channel N */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_DISABLE);
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Output Compare signal generation in interrupt mode
* on the complementary output.
* @param htim TIM OC handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OCN_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Check the TIM complementary channel state */
if (TIM_CHANNEL_N_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Enable the TIM Output Compare interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Enable the TIM Output Compare interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Enable the TIM Output Compare interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Enable the TIM Output Compare interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the TIM Break interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_BREAK);
/* Enable the Capture compare channel N */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM Output Compare signal generation in interrupt mode
* on the complementary output.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpccer;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Output Compare interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Output Compare interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Output Compare interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Output Compare interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Capture compare channel N */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_DISABLE);
/* Disable the TIM Break interrupt (only if no more channel is active) */
tmpccer = htim->Instance->CCER;
if ((tmpccer & TIM_CCER_CCxNE_MASK) == (uint32_t)RESET)
{
__HAL_TIM_DISABLE_IT(htim, TIM_IT_BREAK);
}
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @brief Starts the TIM Output Compare signal generation in DMA mode
* on the complementary output.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @param pData The source Buffer address.
* @param Length The length of data to be transferred from memory to TIM peripheral
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OCN_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Set the TIM complementary channel state */
if (TIM_CHANNEL_N_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_BUSY)
{
return HAL_BUSY;
}
else if (TIM_CHANNEL_N_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_READY)
{
if ((pData == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)pData, (uint32_t)&htim->Instance->CCR1,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Output Compare DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)pData, (uint32_t)&htim->Instance->CCR2,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Output Compare DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC3]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC3]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC3]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC3], (uint32_t)pData, (uint32_t)&htim->Instance->CCR3,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Output Compare DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC4]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC4]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC4]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC4], (uint32_t)pData, (uint32_t)&htim->Instance->CCR4,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Output Compare DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the Capture compare channel N */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM Output Compare signal generation in DMA mode
* on the complementary output.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Output Compare DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Output Compare DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC2);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Output Compare DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC3);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC3]);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Output Compare interrupt */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC4);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC4]);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Capture compare channel N */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_DISABLE);
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @}
*/
/** @defgroup TIMEx_Exported_Functions_Group3 Extended Timer Complementary PWM functions
* @brief Timer Complementary PWM functions
*
@verbatim
==============================================================================
##### Timer Complementary PWM functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Start the Complementary PWM.
(+) Stop the Complementary PWM.
(+) Start the Complementary PWM and enable interrupts.
(+) Stop the Complementary PWM and disable interrupts.
(+) Start the Complementary PWM and enable DMA transfers.
(+) Stop the Complementary PWM and disable DMA transfers.
@endverbatim
* @{
*/
/**
* @brief Starts the PWM signal generation on the complementary output.
* @param htim TIM handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start(TIM_HandleTypeDef *htim, uint32_t Channel)
{
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Check the TIM complementary channel state */
if (TIM_CHANNEL_N_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the complementary PWM output */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the PWM signal generation on the complementary output.
* @param htim TIM handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Disable the complementary PWM output */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_DISABLE);
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the PWM signal generation in interrupt mode on the
* complementary output.
* @param htim TIM handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Check the TIM complementary channel state */
if (TIM_CHANNEL_N_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Enable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Enable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Enable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Enable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the TIM Break interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_BREAK);
/* Enable the complementary PWM output */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the PWM signal generation in interrupt mode on the
* complementary output.
* @param htim TIM handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpccer;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the complementary PWM output */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_DISABLE);
/* Disable the TIM Break interrupt (only if no more channel is active) */
tmpccer = htim->Instance->CCER;
if ((tmpccer & TIM_CCER_CCxNE_MASK) == (uint32_t)RESET)
{
__HAL_TIM_DISABLE_IT(htim, TIM_IT_BREAK);
}
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @brief Starts the TIM PWM signal generation in DMA mode on the
* complementary output
* @param htim TIM handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @param pData The source Buffer address.
* @param Length The length of data to be transferred from memory to TIM peripheral
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
/* Set the TIM complementary channel state */
if (TIM_CHANNEL_N_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_BUSY)
{
return HAL_BUSY;
}
else if (TIM_CHANNEL_N_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_READY)
{
if ((pData == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)pData, (uint32_t)&htim->Instance->CCR1,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)pData, (uint32_t)&htim->Instance->CCR2,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC3]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC3]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC3]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC3], (uint32_t)pData, (uint32_t)&htim->Instance->CCR3,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 3 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC4]->XferCpltCallback = TIM_DMADelayPulseNCplt;
htim->hdma[TIM_DMA_ID_CC4]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC4]->XferErrorCallback = TIM_DMAErrorCCxN ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC4], (uint32_t)pData, (uint32_t)&htim->Instance->CCR4,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 4 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the complementary PWM output */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM PWM signal generation in DMA mode on the complementary
* output
* @param htim TIM handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC2);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC3);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC3]);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC4);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC4]);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the complementary PWM output */
TIM_CCxNChannelCmd(htim->Instance, Channel, TIM_CCxN_DISABLE);
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM complementary channel state */
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @}
*/
/** @defgroup TIMEx_Exported_Functions_Group4 Extended Timer Complementary One Pulse functions
* @brief Timer Complementary One Pulse functions
*
@verbatim
==============================================================================
##### Timer Complementary One Pulse functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Start the Complementary One Pulse generation.
(+) Stop the Complementary One Pulse.
(+) Start the Complementary One Pulse and enable interrupts.
(+) Stop the Complementary One Pulse and disable interrupts.
@endverbatim
* @{
*/
/**
* @brief Starts the TIM One Pulse signal generation on the complementary
* output.
* @note OutputChannel must match the pulse output channel chosen when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel pulse output channel to enable
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Start(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
uint32_t input_channel = (OutputChannel == TIM_CHANNEL_1) ? TIM_CHANNEL_2 : TIM_CHANNEL_1;
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, OutputChannel));
/* Check the TIM channels state */
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the complementary One Pulse output channel and the Input Capture channel */
TIM_CCxNChannelCmd(htim->Instance, OutputChannel, TIM_CCxN_ENABLE);
TIM_CCxChannelCmd(htim->Instance, input_channel, TIM_CCx_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM One Pulse signal generation on the complementary
* output.
* @note OutputChannel must match the pulse output channel chosen when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel pulse output channel to disable
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Stop(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
uint32_t input_channel = (OutputChannel == TIM_CHANNEL_1) ? TIM_CHANNEL_2 : TIM_CHANNEL_1;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, OutputChannel));
/* Disable the complementary One Pulse output channel and the Input Capture channel */
TIM_CCxNChannelCmd(htim->Instance, OutputChannel, TIM_CCxN_DISABLE);
TIM_CCxChannelCmd(htim->Instance, input_channel, TIM_CCx_DISABLE);
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM One Pulse signal generation in interrupt mode on the
* complementary channel.
* @note OutputChannel must match the pulse output channel chosen when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel pulse output channel to enable
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Start_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
uint32_t input_channel = (OutputChannel == TIM_CHANNEL_1) ? TIM_CHANNEL_2 : TIM_CHANNEL_1;
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, OutputChannel));
/* Check the TIM channels state */
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
/* Enable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
/* Enable the complementary One Pulse output channel and the Input Capture channel */
TIM_CCxNChannelCmd(htim->Instance, OutputChannel, TIM_CCxN_ENABLE);
TIM_CCxChannelCmd(htim->Instance, input_channel, TIM_CCx_ENABLE);
/* Enable the Main Output */
__HAL_TIM_MOE_ENABLE(htim);
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM One Pulse signal generation in interrupt mode on the
* complementary channel.
* @note OutputChannel must match the pulse output channel chosen when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel pulse output channel to disable
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
uint32_t input_channel = (OutputChannel == TIM_CHANNEL_1) ? TIM_CHANNEL_2 : TIM_CHANNEL_1;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, OutputChannel));
/* Disable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
/* Disable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
/* Disable the complementary One Pulse output channel and the Input Capture channel */
TIM_CCxNChannelCmd(htim->Instance, OutputChannel, TIM_CCxN_DISABLE);
TIM_CCxChannelCmd(htim->Instance, input_channel, TIM_CCx_DISABLE);
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @}
*/
/** @defgroup TIMEx_Exported_Functions_Group5 Extended Peripheral Control functions
* @brief Peripheral Control functions
*
@verbatim
==============================================================================
##### Peripheral Control functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Configure the commutation event in case of use of the Hall sensor interface.
(+) Configure Output channels for OC and PWM mode.
(+) Configure Complementary channels, break features and dead time.
(+) Configure Master synchronization.
(+) Configure timer remapping capabilities.
(+) Select timer input source.
(+) Enable or disable channel grouping.
(+) Configure Pulse on compare.
(+) Configure Encoder index.
@endverbatim
* @{
*/
/**
* @brief Configure the TIM commutation event sequence.
* @note This function is mandatory to use the commutation event in order to
* update the configuration at each commutation detection on the TRGI input of the Timer,
* the typical use of this feature is with the use of another Timer(interface Timer)
* configured in Hall sensor interface, this interface Timer will generate the
* commutation at its TRGO output (connected to Timer used in this function) each time
* the TI1 of the Interface Timer detect a commutation at its input TI1.
* @param htim TIM handle
* @param InputTrigger the Internal trigger corresponding to the Timer Interfacing with the Hall sensor
* This parameter can be one of the following values:
* @arg TIM_TS_ITR0: Internal trigger 0 selected
* @arg TIM_TS_ITR1: Internal trigger 1 selected
* @arg TIM_TS_ITR2: Internal trigger 2 selected
* @arg TIM_TS_ITR3: Internal trigger 3 selected
* @arg TIM_TS_ITR4: Internal trigger 4 selected (*)
* @arg TIM_TS_ITR5: Internal trigger 5 selected
* @arg TIM_TS_ITR6: Internal trigger 6 selected
* @arg TIM_TS_ITR7: Internal trigger 7 selected
* @arg TIM_TS_ITR8: Internal trigger 8 selected
* @arg TIM_TS_ITR9: Internal trigger 9 selected (*)
* @arg TIM_TS_ITR10: Internal trigger 10 selected
* @arg TIM_TS_ITR11: Internal trigger 11 selected
* @arg TIM_TS_NONE: No trigger is needed
*
* (*) Value not defined in all devices.
*
* @param CommutationSource the Commutation Event source
* This parameter can be one of the following values:
* @arg TIM_COMMUTATION_TRGI: Commutation source is the TRGI of the Interface Timer
* @arg TIM_COMMUTATION_SOFTWARE: Commutation source is set by software using the COMG bit
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource)
{
/* Check the parameters */
assert_param(IS_TIM_COMMUTATION_EVENT_INSTANCE(htim->Instance));
assert_param(IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE(htim->Instance, InputTrigger));
__HAL_LOCK(htim);
#if defined(TIM5) && defined(TIM20)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR4) || (InputTrigger == TIM_TS_ITR5) ||
(InputTrigger == TIM_TS_ITR6) || (InputTrigger == TIM_TS_ITR7) ||
(InputTrigger == TIM_TS_ITR8) || (InputTrigger == TIM_TS_ITR9) ||
(InputTrigger == TIM_TS_ITR10) || (InputTrigger == TIM_TS_ITR11))
#elif defined(TIM5)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR4) || (InputTrigger == TIM_TS_ITR5) ||
(InputTrigger == TIM_TS_ITR6) || (InputTrigger == TIM_TS_ITR7) ||
(InputTrigger == TIM_TS_ITR8) || (InputTrigger == TIM_TS_ITR11))
#elif defined(TIM20)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR5) || (InputTrigger == TIM_TS_ITR6) ||
(InputTrigger == TIM_TS_ITR7) || (InputTrigger == TIM_TS_ITR8) ||
(InputTrigger == TIM_TS_ITR9) || (InputTrigger == TIM_TS_ITR11))
#else
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR5) || (InputTrigger == TIM_TS_ITR6) ||
(InputTrigger == TIM_TS_ITR7) || (InputTrigger == TIM_TS_ITR8) ||
(InputTrigger == TIM_TS_ITR11))
#endif /* TIM5 && TIM20 */
{
/* Select the Input trigger */
htim->Instance->SMCR &= ~TIM_SMCR_TS;
htim->Instance->SMCR |= InputTrigger;
}
/* Select the Capture Compare preload feature */
htim->Instance->CR2 |= TIM_CR2_CCPC;
/* Select the Commutation event source */
htim->Instance->CR2 &= ~TIM_CR2_CCUS;
htim->Instance->CR2 |= CommutationSource;
/* Disable Commutation Interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_COM);
/* Disable Commutation DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_COM);
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Configure the TIM commutation event sequence with interrupt.
* @note This function is mandatory to use the commutation event in order to
* update the configuration at each commutation detection on the TRGI input of the Timer,
* the typical use of this feature is with the use of another Timer(interface Timer)
* configured in Hall sensor interface, this interface Timer will generate the
* commutation at its TRGO output (connected to Timer used in this function) each time
* the TI1 of the Interface Timer detect a commutation at its input TI1.
* @param htim TIM handle
* @param InputTrigger the Internal trigger corresponding to the Timer Interfacing with the Hall sensor
* This parameter can be one of the following values:
* @arg TIM_TS_ITR0: Internal trigger 0 selected
* @arg TIM_TS_ITR1: Internal trigger 1 selected
* @arg TIM_TS_ITR2: Internal trigger 2 selected
* @arg TIM_TS_ITR3: Internal trigger 3 selected
* @arg TIM_TS_ITR4: Internal trigger 4 selected (*)
* @arg TIM_TS_ITR5: Internal trigger 5 selected
* @arg TIM_TS_ITR6: Internal trigger 6 selected
* @arg TIM_TS_ITR7: Internal trigger 7 selected
* @arg TIM_TS_ITR8: Internal trigger 8 selected
* @arg TIM_TS_ITR9: Internal trigger 9 selected (*)
* @arg TIM_TS_ITR10: Internal trigger 10 selected
* @arg TIM_TS_ITR11: Internal trigger 11 selected
* @arg TIM_TS_NONE: No trigger is needed
*
* (*) Value not defined in all devices.
*
* @param CommutationSource the Commutation Event source
* This parameter can be one of the following values:
* @arg TIM_COMMUTATION_TRGI: Commutation source is the TRGI of the Interface Timer
* @arg TIM_COMMUTATION_SOFTWARE: Commutation source is set by software using the COMG bit
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent_IT(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource)
{
/* Check the parameters */
assert_param(IS_TIM_COMMUTATION_EVENT_INSTANCE(htim->Instance));
assert_param(IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE(htim->Instance, InputTrigger));
__HAL_LOCK(htim);
#if defined(TIM5) && defined(TIM20)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR4) || (InputTrigger == TIM_TS_ITR5) ||
(InputTrigger == TIM_TS_ITR6) || (InputTrigger == TIM_TS_ITR7) ||
(InputTrigger == TIM_TS_ITR8) || (InputTrigger == TIM_TS_ITR9) ||
(InputTrigger == TIM_TS_ITR10) || (InputTrigger == TIM_TS_ITR11))
#elif defined(TIM5)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR4) || (InputTrigger == TIM_TS_ITR5) ||
(InputTrigger == TIM_TS_ITR6) || (InputTrigger == TIM_TS_ITR7) ||
(InputTrigger == TIM_TS_ITR8) || (InputTrigger == TIM_TS_ITR11))
#elif defined(TIM20)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR5) || (InputTrigger == TIM_TS_ITR6) ||
(InputTrigger == TIM_TS_ITR7) || (InputTrigger == TIM_TS_ITR8) ||
(InputTrigger == TIM_TS_ITR9) || (InputTrigger == TIM_TS_ITR11))
#else
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR5) || (InputTrigger == TIM_TS_ITR6) ||
(InputTrigger == TIM_TS_ITR7) || (InputTrigger == TIM_TS_ITR8) ||
(InputTrigger == TIM_TS_ITR11))
#endif /* TIM5 && TIM20 */
{
/* Select the Input trigger */
htim->Instance->SMCR &= ~TIM_SMCR_TS;
htim->Instance->SMCR |= InputTrigger;
}
/* Select the Capture Compare preload feature */
htim->Instance->CR2 |= TIM_CR2_CCPC;
/* Select the Commutation event source */
htim->Instance->CR2 &= ~TIM_CR2_CCUS;
htim->Instance->CR2 |= CommutationSource;
/* Disable Commutation DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_COM);
/* Enable the Commutation Interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_COM);
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Configure the TIM commutation event sequence with DMA.
* @note This function is mandatory to use the commutation event in order to
* update the configuration at each commutation detection on the TRGI input of the Timer,
* the typical use of this feature is with the use of another Timer(interface Timer)
* configured in Hall sensor interface, this interface Timer will generate the
* commutation at its TRGO output (connected to Timer used in this function) each time
* the TI1 of the Interface Timer detect a commutation at its input TI1.
* @note The user should configure the DMA in his own software, in This function only the COMDE bit is set
* @param htim TIM handle
* @param InputTrigger the Internal trigger corresponding to the Timer Interfacing with the Hall sensor
* This parameter can be one of the following values:
* @arg TIM_TS_ITR0: Internal trigger 0 selected
* @arg TIM_TS_ITR1: Internal trigger 1 selected
* @arg TIM_TS_ITR2: Internal trigger 2 selected
* @arg TIM_TS_ITR3: Internal trigger 3 selected
* @arg TIM_TS_ITR4: Internal trigger 4 selected (*)
* @arg TIM_TS_ITR5: Internal trigger 5 selected
* @arg TIM_TS_ITR6: Internal trigger 6 selected
* @arg TIM_TS_ITR7: Internal trigger 7 selected
* @arg TIM_TS_ITR8: Internal trigger 8 selected
* @arg TIM_TS_ITR9: Internal trigger 9 selected (*)
* @arg TIM_TS_ITR10: Internal trigger 10 selected
* @arg TIM_TS_ITR11: Internal trigger 11 selected
* @arg TIM_TS_NONE: No trigger is needed
*
* (*) Value not defined in all devices.
*
* @param CommutationSource the Commutation Event source
* This parameter can be one of the following values:
* @arg TIM_COMMUTATION_TRGI: Commutation source is the TRGI of the Interface Timer
* @arg TIM_COMMUTATION_SOFTWARE: Commutation source is set by software using the COMG bit
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent_DMA(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource)
{
/* Check the parameters */
assert_param(IS_TIM_COMMUTATION_EVENT_INSTANCE(htim->Instance));
assert_param(IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE(htim->Instance, InputTrigger));
__HAL_LOCK(htim);
#if defined(TIM5) && defined(TIM20)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR4) || (InputTrigger == TIM_TS_ITR5) ||
(InputTrigger == TIM_TS_ITR6) || (InputTrigger == TIM_TS_ITR7) ||
(InputTrigger == TIM_TS_ITR8) || (InputTrigger == TIM_TS_ITR9) ||
(InputTrigger == TIM_TS_ITR10) || (InputTrigger == TIM_TS_ITR11))
#elif defined(TIM5)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR4) || (InputTrigger == TIM_TS_ITR5) ||
(InputTrigger == TIM_TS_ITR6) || (InputTrigger == TIM_TS_ITR7) ||
(InputTrigger == TIM_TS_ITR8) || (InputTrigger == TIM_TS_ITR11))
#elif defined(TIM20)
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR5) || (InputTrigger == TIM_TS_ITR6) ||
(InputTrigger == TIM_TS_ITR7) || (InputTrigger == TIM_TS_ITR8) ||
(InputTrigger == TIM_TS_ITR9) || (InputTrigger == TIM_TS_ITR11))
#else
if ((InputTrigger == TIM_TS_ITR0) || (InputTrigger == TIM_TS_ITR1) ||
(InputTrigger == TIM_TS_ITR2) || (InputTrigger == TIM_TS_ITR3) ||
(InputTrigger == TIM_TS_ITR5) || (InputTrigger == TIM_TS_ITR6) ||
(InputTrigger == TIM_TS_ITR7) || (InputTrigger == TIM_TS_ITR8) ||
(InputTrigger == TIM_TS_ITR11))
#endif /* TIM5 && TIM20 */
{
/* Select the Input trigger */
htim->Instance->SMCR &= ~TIM_SMCR_TS;
htim->Instance->SMCR |= InputTrigger;
}
/* Select the Capture Compare preload feature */
htim->Instance->CR2 |= TIM_CR2_CCPC;
/* Select the Commutation event source */
htim->Instance->CR2 &= ~TIM_CR2_CCUS;
htim->Instance->CR2 |= CommutationSource;
/* Enable the Commutation DMA Request */
/* Set the DMA Commutation Callback */
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferCpltCallback = TIMEx_DMACommutationCplt;
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferHalfCpltCallback = TIMEx_DMACommutationHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferErrorCallback = TIM_DMAError;
/* Disable Commutation Interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_COM);
/* Enable the Commutation DMA Request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_COM);
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Configures the TIM in master mode.
* @param htim TIM handle.
* @param sMasterConfig pointer to a TIM_MasterConfigTypeDef structure that
* contains the selected trigger output (TRGO) and the Master/Slave
* mode.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_MasterConfigSynchronization(TIM_HandleTypeDef *htim,
const TIM_MasterConfigTypeDef *sMasterConfig)
{
uint32_t tmpcr2;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_MASTER_INSTANCE(htim->Instance));
assert_param(IS_TIM_TRGO_SOURCE(sMasterConfig->MasterOutputTrigger));
assert_param(IS_TIM_MSM_STATE(sMasterConfig->MasterSlaveMode));
/* Check input state */
__HAL_LOCK(htim);
/* Change the handler state */
htim->State = HAL_TIM_STATE_BUSY;
/* Get the TIMx CR2 register value */
tmpcr2 = htim->Instance->CR2;
/* Get the TIMx SMCR register value */
tmpsmcr = htim->Instance->SMCR;
/* If the timer supports ADC synchronization through TRGO2, set the master mode selection 2 */
if (IS_TIM_TRGO2_INSTANCE(htim->Instance))
{
/* Check the parameters */
assert_param(IS_TIM_TRGO2_SOURCE(sMasterConfig->MasterOutputTrigger2));
/* Clear the MMS2 bits */
tmpcr2 &= ~TIM_CR2_MMS2;
/* Select the TRGO2 source*/
tmpcr2 |= sMasterConfig->MasterOutputTrigger2;
}
/* Reset the MMS Bits */
tmpcr2 &= ~TIM_CR2_MMS;
/* Select the TRGO source */
tmpcr2 |= sMasterConfig->MasterOutputTrigger;
/* Update TIMx CR2 */
htim->Instance->CR2 = tmpcr2;
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
/* Reset the MSM Bit */
tmpsmcr &= ~TIM_SMCR_MSM;
/* Set master mode */
tmpsmcr |= sMasterConfig->MasterSlaveMode;
/* Update TIMx SMCR */
htim->Instance->SMCR = tmpsmcr;
}
/* Change the htim state */
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Configures the Break feature, dead time, Lock level, OSSI/OSSR State
* and the AOE(automatic output enable).
* @param htim TIM handle
* @param sBreakDeadTimeConfig pointer to a TIM_ConfigBreakDeadConfigTypeDef structure that
* contains the BDTR Register configuration information for the TIM peripheral.
* @note Interrupts can be generated when an active level is detected on the
* break input, the break 2 input or the system break input. Break
* interrupt can be enabled by calling the @ref __HAL_TIM_ENABLE_IT macro.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigBreakDeadTime(TIM_HandleTypeDef *htim,
const TIM_BreakDeadTimeConfigTypeDef *sBreakDeadTimeConfig)
{
/* Keep this variable initialized to 0 as it is used to configure BDTR register */
uint32_t tmpbdtr = 0U;
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
assert_param(IS_TIM_OSSR_STATE(sBreakDeadTimeConfig->OffStateRunMode));
assert_param(IS_TIM_OSSI_STATE(sBreakDeadTimeConfig->OffStateIDLEMode));
assert_param(IS_TIM_LOCK_LEVEL(sBreakDeadTimeConfig->LockLevel));
assert_param(IS_TIM_DEADTIME(sBreakDeadTimeConfig->DeadTime));
assert_param(IS_TIM_BREAK_STATE(sBreakDeadTimeConfig->BreakState));
assert_param(IS_TIM_BREAK_POLARITY(sBreakDeadTimeConfig->BreakPolarity));
assert_param(IS_TIM_BREAK_FILTER(sBreakDeadTimeConfig->BreakFilter));
assert_param(IS_TIM_AUTOMATIC_OUTPUT_STATE(sBreakDeadTimeConfig->AutomaticOutput));
assert_param(IS_TIM_BREAK_AFMODE(sBreakDeadTimeConfig->BreakAFMode));
/* Check input state */
__HAL_LOCK(htim);
/* Set the Lock level, the Break enable Bit and the Polarity, the OSSR State,
the OSSI State, the dead time value and the Automatic Output Enable Bit */
/* Set the BDTR bits */
MODIFY_REG(tmpbdtr, TIM_BDTR_DTG, sBreakDeadTimeConfig->DeadTime);
MODIFY_REG(tmpbdtr, TIM_BDTR_LOCK, sBreakDeadTimeConfig->LockLevel);
MODIFY_REG(tmpbdtr, TIM_BDTR_OSSI, sBreakDeadTimeConfig->OffStateIDLEMode);
MODIFY_REG(tmpbdtr, TIM_BDTR_OSSR, sBreakDeadTimeConfig->OffStateRunMode);
MODIFY_REG(tmpbdtr, TIM_BDTR_BKE, sBreakDeadTimeConfig->BreakState);
MODIFY_REG(tmpbdtr, TIM_BDTR_BKP, sBreakDeadTimeConfig->BreakPolarity);
MODIFY_REG(tmpbdtr, TIM_BDTR_AOE, sBreakDeadTimeConfig->AutomaticOutput);
MODIFY_REG(tmpbdtr, TIM_BDTR_BKF, (sBreakDeadTimeConfig->BreakFilter << TIM_BDTR_BKF_Pos));
MODIFY_REG(tmpbdtr, TIM_BDTR_BKBID, sBreakDeadTimeConfig->BreakAFMode);
if (IS_TIM_BKIN2_INSTANCE(htim->Instance))
{
/* Check the parameters */
assert_param(IS_TIM_BREAK2_STATE(sBreakDeadTimeConfig->Break2State));
assert_param(IS_TIM_BREAK2_POLARITY(sBreakDeadTimeConfig->Break2Polarity));
assert_param(IS_TIM_BREAK_FILTER(sBreakDeadTimeConfig->Break2Filter));
assert_param(IS_TIM_BREAK2_AFMODE(sBreakDeadTimeConfig->Break2AFMode));
/* Set the BREAK2 input related BDTR bits */
MODIFY_REG(tmpbdtr, TIM_BDTR_BK2F, (sBreakDeadTimeConfig->Break2Filter << TIM_BDTR_BK2F_Pos));
MODIFY_REG(tmpbdtr, TIM_BDTR_BK2E, sBreakDeadTimeConfig->Break2State);
MODIFY_REG(tmpbdtr, TIM_BDTR_BK2P, sBreakDeadTimeConfig->Break2Polarity);
MODIFY_REG(tmpbdtr, TIM_BDTR_BK2BID, sBreakDeadTimeConfig->Break2AFMode);
}
/* Set TIMx_BDTR */
htim->Instance->BDTR = tmpbdtr;
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Configures the break input source.
* @param htim TIM handle.
* @param BreakInput Break input to configure
* This parameter can be one of the following values:
* @arg TIM_BREAKINPUT_BRK: Timer break input
* @arg TIM_BREAKINPUT_BRK2: Timer break 2 input
* @param sBreakInputConfig Break input source configuration
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigBreakInput(TIM_HandleTypeDef *htim,
uint32_t BreakInput,
const TIMEx_BreakInputConfigTypeDef *sBreakInputConfig)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmporx;
uint32_t bkin_enable_mask;
uint32_t bkin_polarity_mask;
uint32_t bkin_enable_bitpos;
uint32_t bkin_polarity_bitpos;
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
assert_param(IS_TIM_BREAKINPUT(BreakInput));
assert_param(IS_TIM_BREAKINPUTSOURCE(sBreakInputConfig->Source));
assert_param(IS_TIM_BREAKINPUTSOURCE_STATE(sBreakInputConfig->Enable));
assert_param(IS_TIM_BREAKINPUTSOURCE_POLARITY(sBreakInputConfig->Polarity));
/* Check input state */
__HAL_LOCK(htim);
switch (sBreakInputConfig->Source)
{
case TIM_BREAKINPUTSOURCE_BKIN:
{
bkin_enable_mask = TIM1_AF1_BKINE;
bkin_enable_bitpos = TIM1_AF1_BKINE_Pos;
bkin_polarity_mask = TIM1_AF1_BKINP;
bkin_polarity_bitpos = TIM1_AF1_BKINP_Pos;
break;
}
case TIM_BREAKINPUTSOURCE_COMP1:
{
bkin_enable_mask = TIM1_AF1_BKCMP1E;
bkin_enable_bitpos = TIM1_AF1_BKCMP1E_Pos;
bkin_polarity_mask = TIM1_AF1_BKCMP1P;
bkin_polarity_bitpos = TIM1_AF1_BKCMP1P_Pos;
break;
}
case TIM_BREAKINPUTSOURCE_COMP2:
{
bkin_enable_mask = TIM1_AF1_BKCMP2E;
bkin_enable_bitpos = TIM1_AF1_BKCMP2E_Pos;
bkin_polarity_mask = TIM1_AF1_BKCMP2P;
bkin_polarity_bitpos = TIM1_AF1_BKCMP2P_Pos;
break;
}
case TIM_BREAKINPUTSOURCE_COMP3:
{
bkin_enable_mask = TIM1_AF1_BKCMP3E;
bkin_enable_bitpos = TIM1_AF1_BKCMP3E_Pos;
bkin_polarity_mask = TIM1_AF1_BKCMP3P;
bkin_polarity_bitpos = TIM1_AF1_BKCMP3P_Pos;
break;
}
case TIM_BREAKINPUTSOURCE_COMP4:
{
bkin_enable_mask = TIM1_AF1_BKCMP4E;
bkin_enable_bitpos = TIM1_AF1_BKCMP4E_Pos;
bkin_polarity_mask = TIM1_AF1_BKCMP4P;
bkin_polarity_bitpos = TIM1_AF1_BKCMP4P_Pos;
break;
}
#if defined (COMP5)
case TIM_BREAKINPUTSOURCE_COMP5:
{
bkin_enable_mask = TIM1_AF1_BKCMP5E;
bkin_enable_bitpos = TIM1_AF1_BKCMP5E_Pos;
/* No palarity bit for this COMP. Variable bkin_polarity_mask keeps its default value 0 */
bkin_polarity_mask = 0U;
bkin_polarity_bitpos = 0U;
break;
}
#endif /* COMP5 */
#if defined (COMP6)
case TIM_BREAKINPUTSOURCE_COMP6:
{
bkin_enable_mask = TIM1_AF1_BKCMP6E;
bkin_enable_bitpos = TIM1_AF1_BKCMP6E_Pos;
/* No palarity bit for this COMP. Variable bkin_polarity_mask keeps its default value 0 */
bkin_polarity_mask = 0U;
bkin_polarity_bitpos = 0U;
break;
}
#endif /* COMP7 */
#if defined (COMP7)
case TIM_BREAKINPUTSOURCE_COMP7:
{
bkin_enable_mask = TIM1_AF1_BKCMP7E;
bkin_enable_bitpos = TIM1_AF1_BKCMP7E_Pos;
/* No palarity bit for this COMP. Variable bkin_polarity_mask keeps its default value 0 */
bkin_polarity_mask = 0U;
bkin_polarity_bitpos = 0U;
break;
}
#endif /* COMP7 */
default:
{
bkin_enable_mask = 0U;
bkin_polarity_mask = 0U;
bkin_enable_bitpos = 0U;
bkin_polarity_bitpos = 0U;
break;
}
}
switch (BreakInput)
{
case TIM_BREAKINPUT_BRK:
{
/* Get the TIMx_AF1 register value */
tmporx = htim->Instance->AF1;
/* Enable the break input */
tmporx &= ~bkin_enable_mask;
tmporx |= (sBreakInputConfig->Enable << bkin_enable_bitpos) & bkin_enable_mask;
/* Set the break input polarity */
tmporx &= ~bkin_polarity_mask;
tmporx |= (sBreakInputConfig->Polarity << bkin_polarity_bitpos) & bkin_polarity_mask;
/* Set TIMx_AF1 */
htim->Instance->AF1 = tmporx;
break;
}
case TIM_BREAKINPUT_BRK2:
{
/* Get the TIMx_AF2 register value */
tmporx = htim->Instance->AF2;
/* Enable the break input */
tmporx &= ~bkin_enable_mask;
tmporx |= (sBreakInputConfig->Enable << bkin_enable_bitpos) & bkin_enable_mask;
/* Set the break input polarity */
tmporx &= ~bkin_polarity_mask;
tmporx |= (sBreakInputConfig->Polarity << bkin_polarity_bitpos) & bkin_polarity_mask;
/* Set TIMx_AF2 */
htim->Instance->AF2 = tmporx;
break;
}
default:
status = HAL_ERROR;
break;
}
__HAL_UNLOCK(htim);
return status;
}
/**
* @brief Configures the TIMx Remapping input capabilities.
* @param htim TIM handle.
* @param Remap specifies the TIM remapping source.
* For TIM1, the parameter can take one of the following values:
* @arg TIM_TIM1_ETR_GPIO TIM1 ETR is connected to GPIO
* @arg TIM_TIM1_ETR_COMP1 TIM1 ETR is connected to COMP1 output
* @arg TIM_TIM1_ETR_COMP2 TIM1 ETR is connected to COMP2 output
* @arg TIM_TIM1_ETR_COMP3 TIM1 ETR is connected to COMP3 output
* @arg TIM_TIM1_ETR_COMP4 TIM1 ETR is connected to COMP4 output
* @arg TIM_TIM1_ETR_COMP5 TIM1 ETR is connected to COMP5 output (*)
* @arg TIM_TIM1_ETR_COMP6 TIM1 ETR is connected to COMP6 output (*)
* @arg TIM_TIM1_ETR_COMP7 TIM1 ETR is connected to COMP7 output (*)
* @arg TIM_TIM1_ETR_ADC1_AWD1 TIM1 ETR is connected to ADC1 AWD1
* @arg TIM_TIM1_ETR_ADC1_AWD2 TIM1 ETR is connected to ADC1 AWD2
* @arg TIM_TIM1_ETR_ADC1_AWD3 TIM1 ETR is connected to ADC1 AWD3
* @arg TIM_TIM1_ETR_ADC4_AWD1 TIM1 ETR is connected to ADC4 AWD1 (*)
* @arg TIM_TIM1_ETR_ADC4_AWD2 TIM1 ETR is connected to ADC4 AWD2 (*)
* @arg TIM_TIM1_ETR_ADC4_AWD3 TIM1 ETR is connected to ADC4 AWD3 (*)
*
* For TIM2, the parameter can take one of the following values:
* @arg TIM_TIM2_ETR_GPIO TIM2 ETR is connected to GPIO
* @arg TIM_TIM2_ETR_COMP1 TIM2 ETR is connected to COMP1 output
* @arg TIM_TIM2_ETR_COMP2 TIM2 ETR is connected to COMP2 output
* @arg TIM_TIM2_ETR_COMP3 TIM2 ETR is connected to COMP3 output
* @arg TIM_TIM2_ETR_COMP4 TIM2 ETR is connected to COMP4 output
* @arg TIM_TIM2_ETR_COMP5 TIM2 ETR is connected to COMP5 output (*)
* @arg TIM_TIM2_ETR_COMP6 TIM2 ETR is connected to COMP6 output (*)
* @arg TIM_TIM2_ETR_COMP7 TIM2 ETR is connected to COMP7 output (*)
* @arg TIM_TIM2_ETR_TIM3_ETR TIM2 ETR is connected to TIM3 ETR pin
* @arg TIM_TIM2_ETR_TIM4_ETR TIM2 ETR is connected to TIM4 ETR pin
* @arg TIM_TIM2_ETR_TIM5_ETR TIM2 ETR is connected to TIM5 ETR pin (*)
* @arg TIM_TIM2_ETR_LSE
*
* For TIM3, the parameter can take one of the following values:
* @arg TIM_TIM3_ETR_GPIO TIM3 ETR is connected to GPIO
* @arg TIM_TIM3_ETR_COMP1 TIM3 ETR is connected to COMP1 output
* @arg TIM_TIM3_ETR_COMP2 TIM3 ETR is connected to COMP2 output
* @arg TIM_TIM3_ETR_COMP3 TIM3 ETR is connected to COMP3 output
* @arg TIM_TIM3_ETR_COMP4 TIM3 ETR is connected to COMP4 output
* @arg TIM_TIM3_ETR_COMP5 TIM3 ETR is connected to COMP5 output (*)
* @arg TIM_TIM3_ETR_COMP6 TIM3 ETR is connected to COMP6 output (*)
* @arg TIM_TIM3_ETR_COMP7 TIM3 ETR is connected to COMP7 output (*)
* @arg TIM_TIM3_ETR_TIM2_ETR TIM3 ETR is connected to TIM2 ETR pin
* @arg TIM_TIM3_ETR_TIM4_ETR TIM3 ETR is connected to TIM4 ETR pin
* @arg TIM_TIM3_ETR_ADC2_AWD1 TIM3 ETR is connected to ADC2 AWD1
* @arg TIM_TIM3_ETR_ADC2_AWD2 TIM3 ETR is connected to ADC2 AWD2
* @arg TIM_TIM3_ETR_ADC2_AWD3 TIM3 ETR is connected to ADC2 AWD3
*
* For TIM4, the parameter can take one of the following values:
* @arg TIM_TIM4_ETR_GPIO TIM4 ETR is connected to GPIO
* @arg TIM_TIM4_ETR_COMP1 TIM4 ETR is connected to COMP1 output
* @arg TIM_TIM4_ETR_COMP2 TIM4 ETR is connected to COMP2 output
* @arg TIM_TIM4_ETR_COMP3 TIM4 ETR is connected to COMP3 output
* @arg TIM_TIM4_ETR_COMP4 TIM4 ETR is connected to COMP4 output
* @arg TIM_TIM4_ETR_COMP5 TIM4 ETR is connected to COMP5 output (*)
* @arg TIM_TIM4_ETR_COMP6 TIM4 ETR is connected to COMP6 output (*)
* @arg TIM_TIM4_ETR_COMP7 TIM4 ETR is connected to COMP7 output (*)
* @arg TIM_TIM4_ETR_TIM3_ETR TIM4 ETR is connected to TIM3 ETR pin
* @arg TIM_TIM4_ETR_TIM5_ETR TIM4 ETR is connected to TIM5 ETR pin (*)
*
* For TIM5, the parameter can take one of the following values: (**)
* @arg TIM_TIM5_ETR_GPIO TIM5 ETR is connected to GPIO (*)
* @arg TIM_TIM5_ETR_COMP1 TIM5 ETR is connected to COMP1 output (*)
* @arg TIM_TIM5_ETR_COMP2 TIM5 ETR is connected to COMP2 output (*)
* @arg TIM_TIM5_ETR_COMP3 TIM5 ETR is connected to COMP3 output (*)
* @arg TIM_TIM5_ETR_COMP4 TIM5 ETR is connected to COMP4 output (*)
* @arg TIM_TIM5_ETR_COMP5 TIM5 ETR is connected to COMP5 output (*)
* @arg TIM_TIM5_ETR_COMP6 TIM5 ETR is connected to COMP6 output (*)
* @arg TIM_TIM5_ETR_COMP7 TIM5 ETR is connected to COMP7 output (*)
* @arg TIM_TIM5_ETR_TIM2_ETR TIM5 ETR is connected to TIM2 ETR pin (*)
* @arg TIM_TIM5_ETR_TIM3_ETR TIM5 ETR is connected to TIM3 ETR pin (*)
*
* For TIM8, the parameter can take one of the following values:
* @arg TIM_TIM8_ETR_GPIO TIM8 ETR is connected to GPIO
* @arg TIM_TIM8_ETR_COMP1 TIM8 ETR is connected to COMP1 output
* @arg TIM_TIM8_ETR_COMP2 TIM8 ETR is connected to COMP2 output
* @arg TIM_TIM8_ETR_COMP3 TIM8 ETR is connected to COMP3 output
* @arg TIM_TIM8_ETR_COMP4 TIM8 ETR is connected to COMP4 output
* @arg TIM_TIM8_ETR_COMP5 TIM8 ETR is connected to COMP5 output (*)
* @arg TIM_TIM8_ETR_COMP6 TIM8 ETR is connected to COMP6 output (*)
* @arg TIM_TIM8_ETR_COMP7 TIM8 ETR is connected to COMP7 output (*)
* @arg TIM_TIM8_ETR_ADC2_AWD1 TIM8 ETR is connected to ADC2 AWD1
* @arg TIM_TIM8_ETR_ADC2_AWD2 TIM8 ETR is connected to ADC2 AWD2
* @arg TIM_TIM8_ETR_ADC2_AWD3 TIM8 ETR is connected to ADC2 AWD3
* @arg TIM_TIM8_ETR_ADC3_AWD1 TIM8 ETR is connected to ADC3 AWD1 (*)
* @arg TIM_TIM8_ETR_ADC3_AWD2 TIM8 ETR is connected to ADC3 AWD2 (*)
* @arg TIM_TIM8_ETR_ADC3_AWD3 TIM8 ETR is connected to ADC3 AWD3 (*)
*
* For TIM20, the parameter can take one of the following values: (**)
* @arg TIM_TIM20_ETR_GPIO TIM20 ETR is connected to GPIO
* @arg TIM_TIM20_ETR_COMP1 TIM20 ETR is connected to COMP1 output (*)
* @arg TIM_TIM20_ETR_COMP2 TIM20 ETR is connected to COMP2 output (*)
* @arg TIM_TIM20_ETR_COMP3 TIM20 ETR is connected to COMP3 output (*)
* @arg TIM_TIM20_ETR_COMP4 TIM20 ETR is connected to COMP4 output (*)
* @arg TIM_TIM20_ETR_COMP5 TIM20 ETR is connected to COMP5 output (*)
* @arg TIM_TIM20_ETR_COMP6 TIM20 ETR is connected to COMP6 output (*)
* @arg TIM_TIM20_ETR_COMP7 TIM20 ETR is connected to COMP7 output (*)
* @arg TIM_TIM20_ETR_ADC3_AWD1 TIM20 ETR is connected to ADC3 AWD1 (*)
* @arg TIM_TIM20_ETR_ADC3_AWD2 TIM20 ETR is connected to ADC3 AWD2 (*)
* @arg TIM_TIM20_ETR_ADC3_AWD3 TIM20 ETR is connected to ADC3 AWD3 (*)
* @arg TIM_TIM20_ETR_ADC5_AWD1 TIM20 ETR is connected to ADC5 AWD1 (*)
* @arg TIM_TIM20_ETR_ADC5_AWD2 TIM20 ETR is connected to ADC5 AWD2 (*)
* @arg TIM_TIM20_ETR_ADC5_AWD3 TIM20 ETR is connected to ADC5 AWD3 (*)
*
* (*) Value not defined in all devices. \n
* (**) Register not available in all devices.
*
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_RemapConfig(TIM_HandleTypeDef *htim, uint32_t Remap)
{
/* Check parameters */
assert_param(IS_TIM_REMAP_INSTANCE(htim->Instance));
assert_param(IS_TIM_REMAP(Remap));
__HAL_LOCK(htim);
MODIFY_REG(htim->Instance->AF1, TIM1_AF1_ETRSEL_Msk, Remap);
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Select the timer input source
* @param htim TIM handle.
* @param Channel specifies the TIM Channel
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TI1 input channel
* @arg TIM_CHANNEL_2: TI2 input channel
* @arg TIM_CHANNEL_3: TI3 input channel
* @arg TIM_CHANNEL_4: TI4 input channel
* @param TISelection specifies the timer input source
* For TIM1 this parameter can be one of the following values:
* @arg TIM_TIM1_TI1_GPIO: TIM1 TI1 is connected to GPIO
* @arg TIM_TIM1_TI1_COMP1: TIM1 TI1 is connected to COMP1 output
* @arg TIM_TIM1_TI1_COMP2: TIM1 TI1 is connected to COMP2 output
* @arg TIM_TIM1_TI1_COMP3: TIM1 TI1 is connected to COMP3 output
* @arg TIM_TIM1_TI1_COMP4: TIM1 TI1 is connected to COMP4 output
*
* For TIM2 this parameter can be one of the following values:
* @arg TIM_TIM2_TI1_GPIO: TIM2 TI1 is connected to GPIO
* @arg TIM_TIM2_TI1_COMP1: TIM2 TI1 is connected to COMP1 output
* @arg TIM_TIM2_TI1_COMP2: TIM2 TI1 is connected to COMP2 output
* @arg TIM_TIM2_TI1_COMP3: TIM2 TI1 is connected to COMP3 output
* @arg TIM_TIM2_TI1_COMP4: TIM2 TI1 is connected to COMP4 output
* @arg TIM_TIM2_TI1_COMP5: TIM2 TI1 is connected to COMP5 output (*)
*
* @arg TIM_TIM2_TI2_GPIO: TIM1 TI2 is connected to GPIO
* @arg TIM_TIM2_TI2_COMP1: TIM2 TI2 is connected to COMP1 output
* @arg TIM_TIM2_TI2_COMP2: TIM2 TI2 is connected to COMP2 output
* @arg TIM_TIM2_TI2_COMP3: TIM2 TI2 is connected to COMP3 output
* @arg TIM_TIM2_TI2_COMP4: TIM2 TI2 is connected to COMP4 output
* @arg TIM_TIM2_TI2_COMP6: TIM2 TI2 is connected to COMP6 output (*)
*
* @arg TIM_TIM2_TI3_GPIO: TIM2 TI3 is connected to GPIO
* @arg TIM_TIM2_TI3_COMP4: TIM2 TI3 is connected to COMP4 output
*
* @arg TIM_TIM2_TI4_GPIO: TIM2 TI4 is connected to GPIO
* @arg TIM_TIM2_TI4_COMP1: TIM2 TI4 is connected to COMP1 output
* @arg TIM_TIM2_TI4_COMP2: TIM2 TI4 is connected to COMP2 output
*
* For TIM3 this parameter can be one of the following values:
* @arg TIM_TIM3_TI1_GPIO: TIM3 TI1 is connected to GPIO
* @arg TIM_TIM3_TI1_COMP1: TIM3 TI1 is connected to COMP1 output
* @arg TIM_TIM3_TI1_COMP2: TIM3 TI1 is connected to COMP2 output
* @arg TIM_TIM3_TI1_COMP3: TIM3 TI1 is connected to COMP3 output
* @arg TIM_TIM3_TI1_COMP4: TIM3 TI1 is connected to COMP4 output
* @arg TIM_TIM3_TI1_COMP5: TIM3 TI1 is connected to COMP5 output (*)
* @arg TIM_TIM3_TI1_COMP6: TIM3 TI1 is connected to COMP6 output (*)
* @arg TIM_TIM3_TI1_COMP7: TIM3 TI1 is connected to COMP7 output (*)
*
* @arg TIM_TIM3_TI2_GPIO: TIM3 TI2 is connected to GPIO
* @arg TIM_TIM3_TI2_COMP1: TIM3 TI2 is connected to COMP1 output
* @arg TIM_TIM3_TI2_COMP2: TIM3 TI2 is connected to COMP2 output
* @arg TIM_TIM3_TI2_COMP3: TIM3 TI2 is connected to COMP3 output
* @arg TIM_TIM3_TI2_COMP4: TIM3 TI2 is connected to COMP4 output
* @arg TIM_TIM3_TI2_COMP5: TIM3 TI2 is connected to COMP5 output (*)
* @arg TIM_TIM3_TI2_COMP6: TIM3 TI2 is connected to COMP6 output (*)
* @arg TIM_TIM3_TI2_COMP7: TIM3 TI2 is connected to COMP7 output (*)
*
* @arg TIM_TIM3_TI3_GPIO: TIM3 TI3 is connected to GPIO
* @arg TIM_TIM3_TI3_COMP3: TIM3 TI3 is connected to COMP3 output
*
* For TIM4 this parameter can be one of the following values:
* @arg TIM_TIM4_TI1_GPIO: TIM4 TI1 is connected to GPIO
* @arg TIM_TIM4_TI1_COMP1: TIM4 TI1 is connected to COMP1 output
* @arg TIM_TIM4_TI1_COMP2: TIM4 TI1 is connected to COMP2 output
* @arg TIM_TIM4_TI1_COMP3: TIM4 TI1 is connected to COMP3 output
* @arg TIM_TIM4_TI1_COMP4: TIM4 TI1 is connected to COMP4 output
* @arg TIM_TIM4_TI1_COMP5: TIM4 TI1 is connected to COMP5 output (*)
* @arg TIM_TIM4_TI1_COMP6: TIM4 TI1 is connected to COMP6 output (*)
* @arg TIM_TIM4_TI1_COMP7: TIM4 TI1 is connected to COMP7 output (*)
*
* @arg TIM_TIM4_TI2_GPIO: TIM4 TI2 is connected to GPIO
* @arg TIM_TIM4_TI2_COMP1: TIM4 TI2 is connected to COMP1 output
* @arg TIM_TIM4_TI2_COMP2: TIM4 TI2 is connected to COMP2 output
* @arg TIM_TIM4_TI2_COMP3: TIM4 TI2 is connected to COMP3 output
* @arg TIM_TIM4_TI2_COMP4: TIM4 TI2 is connected to COMP4 output
* @arg TIM_TIM4_TI2_COMP5: TIM4 TI2 is connected to COMP5 output (*)
* @arg TIM_TIM4_TI2_COMP6: TIM4 TI2 is connected to COMP6 output (*)
* @arg TIM_TIM4_TI2_COMP7: TIM4 TI2 is connected to COMP7 output (*)
*
* @arg TIM_TIM4_TI3_GPIO: TIM4 TI3 is connected to GPIO
* @arg TIM_TIM4_TI3_COMP5: TIM4 TI3 is connected to COMP5 output (*)
*
* @arg TIM_TIM4_TI4_GPIO: TIM4 TI4 is connected to GPIO
* @arg TIM_TIM4_TI4_COMP6: TIM4 TI4 is connected to COMP6 output (*)
*
* For TIM5 this parameter can be one of the following values: (**)
* @arg TIM_TIM5_TI1_GPIO: TIM5 TI1 is connected to GPIO
* @arg TIM_TIM5_TI1_LSI: TIM5 TI1 is connected to LSI clock (*)
* @arg TIM_TIM5_TI1_LSE: TIM5 TI1 is connected to LSE clock (*)
* @arg TIM_TIM5_TI1_RTC_WK: TIM5 TI1 is connected to RTC Wakeup (*)
* @arg TIM_TIM5_TI1_COMP1: TIM5 TI1 is connected to COMP1 output (*)
* @arg TIM_TIM5_TI1_COMP2: TIM5 TI1 is connected to COMP2 output (*)
* @arg TIM_TIM5_TI1_COMP3: TIM5 TI1 is connected to COMP3 output (*)
* @arg TIM_TIM5_TI1_COMP4: TIM5 TI1 is connected to COMP4 output (*)
* @arg TIM_TIM5_TI1_COMP5: TIM5 TI1 is connected to COMP5 output (*)
* @arg TIM_TIM5_TI1_COMP6: TIM5 TI1 is connected to COMP6 output (*)
* @arg TIM_TIM5_TI1_COMP7: TIM5 TI1 is connected to COMP7 output (*)
*
* @arg TIM_TIM5_TI2_GPIO: TIM5 TI2 is connected to GPIO
* @arg TIM_TIM5_TI2_COMP1: TIM5 TI2 is connected to COMP1 output
* @arg TIM_TIM5_TI2_COMP2: TIM5 TI2 is connected to COMP2 output
* @arg TIM_TIM5_TI2_COMP3: TIM5 TI2 is connected to COMP3 output
* @arg TIM_TIM5_TI2_COMP4: TIM5 TI2 is connected to COMP4 output
* @arg TIM_TIM5_TI2_COMP5: TIM5 TI2 is connected to COMP5 output (*)
* @arg TIM_TIM5_TI2_COMP6: TIM5 TI2 is connected to COMP6 output (*)
* @arg TIM_TIM5_TI2_COMP7: TIM5 TI2 is connected to COMP7 output (*)
*
* For TIM8 this parameter can be one of the following values:
* @arg TIM_TIM8_TI1_GPIO: TIM8 TI1 is connected to GPIO
* @arg TIM_TIM8_TI1_COMP1: TIM8 TI1 is connected to COMP1 output
* @arg TIM_TIM8_TI1_COMP2: TIM8 TI1 is connected to COMP2 output
* @arg TIM_TIM8_TI1_COMP3: TIM8 TI1 is connected to COMP3 output
* @arg TIM_TIM8_TI1_COMP4: TIM8 TI1 is connected to COMP4 output
*
* For TIM15 this parameter can be one of the following values:
* @arg TIM_TIM15_TI1_GPIO: TIM15 TI1 is connected to GPIO
* @arg TIM_TIM15_TI1_LSE: TIM15 TI1 is connected to LSE clock
* @arg TIM_TIM15_TI1_COMP1: TIM15 TI1 is connected to COMP1 output
* @arg TIM_TIM15_TI1_COMP2: TIM15 TI1 is connected to COMP2 output
* @arg TIM_TIM15_TI1_COMP5: TIM15 TI1 is connected to COMP5 output (*)
* @arg TIM_TIM15_TI1_COMP7: TIM15 TI1 is connected to COMP7 output (*)
*
* @arg TIM_TIM15_TI2_GPIO: TIM15 TI2 is connected to GPIO
* @arg TIM_TIM15_TI2_COMP2: TIM15 TI2 is connected to COMP2 output
* @arg TIM_TIM15_TI2_COMP3: TIM15 TI2 is connected to COMP3 output
* @arg TIM_TIM15_TI2_COMP6: TIM15 TI2 is connected to COMP6 output (*)
* @arg TIM_TIM15_TI2_COMP7: TIM15 TI2 is connected to COMP7 output (*)
*
* For TIM16 this parameter can be one of the following values:
* @arg TIM_TIM16_TI1_GPIO: TIM16 TI1 is connected to GPIO
* @arg TIM_TIM16_TI1_COMP6: TIM16 TI1 is connected to COMP6 output (*)
* @arg TIM_TIM16_TI1_MCO: TIM15 TI1 is connected to MCO output
* @arg TIM_TIM16_TI1_HSE_32: TIM15 TI1 is connected to HSE div 32
* @arg TIM_TIM16_TI1_RTC_WK: TIM15 TI1 is connected to RTC wakeup
* @arg TIM_TIM16_TI1_LSE: TIM15 TI1 is connected to LSE clock
* @arg TIM_TIM16_TI1_LSI: TIM15 TI1 is connected to LSI clock
*
* For TIM17 this parameter can be one of the following values:
* @arg TIM_TIM17_TI1_GPIO: TIM17 TI1 is connected to GPIO
* @arg TIM_TIM17_TI1_COMP5: TIM17 TI1 is connected to COMP5 output (*)
* @arg TIM_TIM17_TI1_MCO: TIM17 TI1 is connected to MCO output
* @arg TIM_TIM17_TI1_HSE_32: TIM17 TI1 is connected to HSE div 32
* @arg TIM_TIM17_TI1_RTC_WK: TIM17 TI1 is connected to RTC wakeup
* @arg TIM_TIM17_TI1_LSE: TIM17 TI1 is connected to LSE clock
* @arg TIM_TIM17_TI1_LSI: TIM17 TI1 is connected to LSI clock
* For TIM20 this parameter can be one of the following values: (**)
* @arg TIM_TIM20_TI1_GPIO: TIM20 TI1 is connected to GPIO
* @arg TIM_TIM20_TI1_COMP1: TIM20 TI1 is connected to COMP1 output (*)
* @arg TIM_TIM20_TI1_COMP2: TIM20 TI1 is connected to COMP2 output (*)
* @arg TIM_TIM20_TI1_COMP3: TIM20 TI1 is connected to COMP3 output (*)
* @arg TIM_TIM20_TI1_COMP4: TIM20 TI1 is connected to COMP4 output (*)
*
* (*) Value not defined in all devices. \n
* (**) Register not available in all devices.
*
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_TISelection(TIM_HandleTypeDef *htim, uint32_t TISelection, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check parameters */
assert_param(IS_TIM_TISEL_TIX_INSTANCE(htim->Instance, Channel));
assert_param(IS_TIM_TISEL(TISelection));
__HAL_LOCK(htim);
switch (Channel)
{
case TIM_CHANNEL_1:
MODIFY_REG(htim->Instance->TISEL, TIM_TISEL_TI1SEL, TISelection);
/* If required, set OR bit to request HSE/32 clock */
if (IS_TIM_HSE32_INSTANCE(htim->Instance))
{
SET_BIT(htim->Instance->OR, TIM_OR_HSE32EN);
}
else
{
CLEAR_BIT(htim->Instance->OR, TIM_OR_HSE32EN);
}
break;
case TIM_CHANNEL_2:
MODIFY_REG(htim->Instance->TISEL, TIM_TISEL_TI2SEL, TISelection);
break;
case TIM_CHANNEL_3:
MODIFY_REG(htim->Instance->TISEL, TIM_TISEL_TI3SEL, TISelection);
break;
case TIM_CHANNEL_4:
MODIFY_REG(htim->Instance->TISEL, TIM_TISEL_TI4SEL, TISelection);
break;
default:
status = HAL_ERROR;
break;
}
__HAL_UNLOCK(htim);
return status;
}
/**
* @brief Group channel 5 and channel 1, 2 or 3
* @param htim TIM handle.
* @param Channels specifies the reference signal(s) the OC5REF is combined with.
* This parameter can be any combination of the following values:
* TIM_GROUPCH5_NONE: No effect of OC5REF on OC1REFC, OC2REFC and OC3REFC
* TIM_GROUPCH5_OC1REFC: OC1REFC is the logical AND of OC1REFC and OC5REF
* TIM_GROUPCH5_OC2REFC: OC2REFC is the logical AND of OC2REFC and OC5REF
* TIM_GROUPCH5_OC3REFC: OC3REFC is the logical AND of OC3REFC and OC5REF
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_GroupChannel5(TIM_HandleTypeDef *htim, uint32_t Channels)
{
/* Check parameters */
assert_param(IS_TIM_COMBINED3PHASEPWM_INSTANCE(htim->Instance));
assert_param(IS_TIM_GROUPCH5(Channels));
/* Process Locked */
__HAL_LOCK(htim);
htim->State = HAL_TIM_STATE_BUSY;
/* Clear GC5Cx bit fields */
htim->Instance->CCR5 &= ~(TIM_CCR5_GC5C3 | TIM_CCR5_GC5C2 | TIM_CCR5_GC5C1);
/* Set GC5Cx bit fields */
htim->Instance->CCR5 |= Channels;
/* Change the htim state */
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Disarm the designated break input (when it operates in bidirectional mode).
* @param htim TIM handle.
* @param BreakInput Break input to disarm
* This parameter can be one of the following values:
* @arg TIM_BREAKINPUT_BRK: Timer break input
* @arg TIM_BREAKINPUT_BRK2: Timer break 2 input
* @note The break input can be disarmed only when it is configured in
* bidirectional mode and when when MOE is reset.
* @note Purpose is to be able to have the input voltage back to high-state,
* whatever the time constant on the output .
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DisarmBreakInput(TIM_HandleTypeDef *htim, uint32_t BreakInput)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpbdtr;
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
assert_param(IS_TIM_BREAKINPUT(BreakInput));
switch (BreakInput)
{
case TIM_BREAKINPUT_BRK:
{
/* Check initial conditions */
tmpbdtr = READ_REG(htim->Instance->BDTR);
if ((READ_BIT(tmpbdtr, TIM_BDTR_BKBID) == TIM_BDTR_BKBID) &&
(READ_BIT(tmpbdtr, TIM_BDTR_MOE) == 0U))
{
/* Break input BRK is disarmed */
SET_BIT(htim->Instance->BDTR, TIM_BDTR_BKDSRM);
}
break;
}
case TIM_BREAKINPUT_BRK2:
{
/* Check initial conditions */
tmpbdtr = READ_REG(htim->Instance->BDTR);
if ((READ_BIT(tmpbdtr, TIM_BDTR_BK2BID) == TIM_BDTR_BK2BID) &&
(READ_BIT(tmpbdtr, TIM_BDTR_MOE) == 0U))
{
/* Break input BRK is disarmed */
SET_BIT(htim->Instance->BDTR, TIM_BDTR_BK2DSRM);
}
break;
}
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Arm the designated break input (when it operates in bidirectional mode).
* @param htim TIM handle.
* @param BreakInput Break input to arm
* This parameter can be one of the following values:
* @arg TIM_BREAKINPUT_BRK: Timer break input
* @arg TIM_BREAKINPUT_BRK2: Timer break 2 input
* @note Arming is possible at anytime, even if fault is present.
* @note Break input is automatically armed as soon as MOE bit is set.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ReArmBreakInput(const TIM_HandleTypeDef *htim, uint32_t BreakInput)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tickstart;
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
assert_param(IS_TIM_BREAKINPUT(BreakInput));
switch (BreakInput)
{
case TIM_BREAKINPUT_BRK:
{
/* Check initial conditions */
if (READ_BIT(htim->Instance->BDTR, TIM_BDTR_BKBID) == TIM_BDTR_BKBID)
{
/* Break input BRK is re-armed automatically by hardware. Poll to check whether fault condition disappeared */
/* Init tickstart for timeout management */
tickstart = HAL_GetTick();
while (READ_BIT(htim->Instance->BDTR, TIM_BDTR_BKDSRM) != 0UL)
{
if ((HAL_GetTick() - tickstart) > TIM_BREAKINPUT_REARM_TIMEOUT)
{
/* New check to avoid false timeout detection in case of preemption */
if (READ_BIT(htim->Instance->BDTR, TIM_BDTR_BKDSRM) != 0UL)
{
return HAL_TIMEOUT;
}
}
}
}
break;
}
case TIM_BREAKINPUT_BRK2:
{
/* Check initial conditions */
if (READ_BIT(htim->Instance->BDTR, TIM_BDTR_BK2BID) == TIM_BDTR_BK2BID)
{
/* Break input BRK2 is re-armed automatically by hardware. Poll to check whether fault condition disappeared */
/* Init tickstart for timeout management */
tickstart = HAL_GetTick();
while (READ_BIT(htim->Instance->BDTR, TIM_BDTR_BK2DSRM) != 0UL)
{
if ((HAL_GetTick() - tickstart) > TIM_BREAKINPUT_REARM_TIMEOUT)
{
/* New check to avoid false timeout detection in case of preemption */
if (READ_BIT(htim->Instance->BDTR, TIM_BDTR_BK2DSRM) != 0UL)
{
return HAL_TIMEOUT;
}
}
}
}
break;
}
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Enable dithering
* @param htim TIM handle
* @note Main usage is PWM mode
* @note This function must be called when timer is stopped or disabled (CEN =0)
* @note If dithering is activated, pay attention to ARR, CCRx, CNT interpretation:
* - CNT: only CNT[11:0] holds the non-dithered part for 16b timers (or CNT[26:0] for 32b timers)
* - ARR: ARR[15:4] holds the non-dithered part, and ARR[3:0] the dither part for 16b timers
* - CCRx: CCRx[15:4] holds the non-dithered part, and CCRx[3:0] the dither part for 16b timers
* - ARR and CCRx values are limited to 0xFFEF in dithering mode for 16b timers
* (corresponds to 4094 for the integer part and 15 for the dithered part).
* @note Macros @ref __HAL_TIM_CALC_PERIOD_DITHER() __HAL_TIM_CALC_DELAY_DITHER() __HAL_TIM_CALC_PULSE_DITHER()
* can be used to calculate period (ARR) and delay (CCRx) value.
* @note Enabling dithering, modifies automatically values of registers ARR/CCRx to keep the same integer part.
* @note Enabling dithering, modifies automatically values of registers ARR/CCRx to keep the same integer part.
* So it may be necessary to read ARR value or CCRx value with macros @ref __HAL_TIM_GET_AUTORELOAD()
* __HAL_TIM_GET_COMPARE() and if necessary update Init structure field htim->Init.Period .
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DitheringEnable(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
SET_BIT(htim->Instance->CR1, TIM_CR1_DITHEN);
return HAL_OK;
}
/**
* @brief Disable dithering
* @param htim TIM handle
* @note This function must be called when timer is stopped or disabled (CEN =0)
* @note If dithering is activated, pay attention to ARR, CCRx, CNT interpretation:
* - CNT: only CNT[11:0] holds the non-dithered part for 16b timers (or CNT[26:0] for 32b timers)
* - ARR: ARR[15:4] holds the non-dithered part, and ARR[3:0] the dither part for 16b timers
* - CCRx: CCRx[15:4] holds the non-dithered part, and CCRx[3:0] the dither part for 16b timers
* - ARR and CCRx values are limited to 0xFFEF in dithering mode
* (corresponds to 4094 for the integer part and 15 for the dithered part).
* @note Disabling dithering, modifies automatically values of registers ARR/CCRx to keep the same integer part.
* So it may be necessary to read ARR value or CCRx value with macros @ref __HAL_TIM_GET_AUTORELOAD()
* __HAL_TIM_GET_COMPARE() and if necessary update Init structure field htim->Init.Period .
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DitheringDisable(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
CLEAR_BIT(htim->Instance->CR1, TIM_CR1_DITHEN);
return HAL_OK;
}
/**
* @brief Initializes the pulse on compare pulse width and pulse prescaler
* @param htim TIM Output Compare handle
* @param PulseWidthPrescaler Pulse width prescaler
* This parameter can be a number between Min_Data = 0x0 and Max_Data = 0x7
* @param PulseWidth Pulse width
* This parameter can be a number between Min_Data = 0x00 and Max_Data = 0xFF
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_OC_ConfigPulseOnCompare(TIM_HandleTypeDef *htim,
uint32_t PulseWidthPrescaler,
uint32_t PulseWidth)
{
uint32_t tmpecr;
/* Check the parameters */
assert_param(IS_TIM_PULSEONCOMPARE_INSTANCE(htim->Instance));
assert_param(IS_TIM_PULSEONCOMPARE_WIDTH(PulseWidth));
assert_param(IS_TIM_PULSEONCOMPARE_WIDTHPRESCALER(PulseWidthPrescaler));
/* Process Locked */
__HAL_LOCK(htim);
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Get the TIMx ECR register value */
tmpecr = htim->Instance->ECR;
/* Reset the Pulse width prescaler and the Pulse width */
tmpecr &= ~(TIM_ECR_PWPRSC | TIM_ECR_PW);
/* Set the Pulse width prescaler and Pulse width*/
tmpecr |= PulseWidthPrescaler << TIM_ECR_PWPRSC_Pos;
tmpecr |= PulseWidth << TIM_ECR_PW_Pos;
/* Write to TIMx ECR */
htim->Instance->ECR = tmpecr;
/* Change the TIM state */
htim->State = HAL_TIM_STATE_READY;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Configure preload source of Slave Mode Selection bitfield (SMS in SMCR register)
* @param htim TIM handle
* @param Source Source of slave mode selection preload
* This parameter can be one of the following values:
* @arg TIM_SMS_PRELOAD_SOURCE_UPDATE: Timer update event is used as source of Slave Mode Selection preload
* @arg TIM_SMS_PRELOAD_SOURCE_INDEX: Timer index event is used as source of Slave Mode Selection preload
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigSlaveModePreload(TIM_HandleTypeDef *htim, uint32_t Source)
{
/* Check the parameters */
assert_param(IS_TIM_SLAVE_INSTANCE(htim->Instance));
assert_param(IS_TIM_SLAVE_PRELOAD_SOURCE(Source));
MODIFY_REG(htim->Instance->SMCR, TIM_SMCR_SMSPS, Source);
return HAL_OK;
}
/**
* @brief Enable preload of Slave Mode Selection bitfield (SMS in SMCR register)
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_EnableSlaveModePreload(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_SLAVE_INSTANCE(htim->Instance));
SET_BIT(htim->Instance->SMCR, TIM_SMCR_SMSPE);
return HAL_OK;
}
/**
* @brief Disable preload of Slave Mode Selection bitfield (SMS in SMCR register)
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DisableSlaveModePreload(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_SLAVE_INSTANCE(htim->Instance));
CLEAR_BIT(htim->Instance->SMCR, TIM_SMCR_SMSPE);
return HAL_OK;
}
/**
* @brief Enable deadtime preload
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_EnableDeadTimePreload(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
SET_BIT(htim->Instance->DTR2, TIM_DTR2_DTPE);
return HAL_OK;
}
/**
* @brief Disable deadtime preload
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DisableDeadTimePreload(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
CLEAR_BIT(htim->Instance->DTR2, TIM_DTR2_DTPE);
return HAL_OK;
}
/**
* @brief Configure deadtime
* @param htim TIM handle
* @param Deadtime Deadtime value
* @note This parameter can be a number between Min_Data = 0x00 and Max_Data = 0xFF
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigDeadTime(TIM_HandleTypeDef *htim, uint32_t Deadtime)
{
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
assert_param(IS_TIM_DEADTIME(Deadtime));
MODIFY_REG(htim->Instance->BDTR, TIM_BDTR_DTG, Deadtime);
return HAL_OK;
}
/**
* @brief Configure asymmetrical deadtime
* @param htim TIM handle
* @param FallingDeadtime Falling edge deadtime value
* @note This parameter can be a number between Min_Data = 0x00 and Max_Data = 0xFF
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigAsymmetricalDeadTime(TIM_HandleTypeDef *htim, uint32_t FallingDeadtime)
{
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
assert_param(IS_TIM_DEADTIME(FallingDeadtime));
MODIFY_REG(htim->Instance->DTR2, TIM_DTR2_DTGF, FallingDeadtime);
return HAL_OK;
}
/**
* @brief Enable asymmetrical deadtime
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_EnableAsymmetricalDeadTime(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
SET_BIT(htim->Instance->DTR2, TIM_DTR2_DTAE);
return HAL_OK;
}
/**
* @brief Disable asymmetrical deadtime
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DisableAsymmetricalDeadTime(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_BREAK_INSTANCE(htim->Instance));
CLEAR_BIT(htim->Instance->DTR2, TIM_DTR2_DTAE);
return HAL_OK;
}
/**
* @brief Configures the encoder index.
* @note warning in case of encoder mode clock plus direction
* @ref TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X1 or @ref TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X2
* Direction must be set to @ref TIM_ENCODERINDEX_DIRECTION_UP_DOWN
* @param htim TIM handle.
* @param sEncoderIndexConfig Encoder index configuration
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_ConfigEncoderIndex(TIM_HandleTypeDef *htim,
TIMEx_EncoderIndexConfigTypeDef *sEncoderIndexConfig)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
assert_param(IS_TIM_ENCODERINDEX_POLARITY(sEncoderIndexConfig->Polarity));
assert_param(IS_TIM_ENCODERINDEX_PRESCALER(sEncoderIndexConfig->Prescaler));
assert_param(IS_TIM_ENCODERINDEX_FILTER(sEncoderIndexConfig->Filter));
assert_param(IS_FUNCTIONAL_STATE(sEncoderIndexConfig->FirstIndexEnable));
assert_param(IS_TIM_ENCODERINDEX_POSITION(sEncoderIndexConfig->Position));
assert_param(IS_TIM_ENCODERINDEX_DIRECTION(sEncoderIndexConfig->Direction));
/* Process Locked */
__HAL_LOCK(htim);
/* Configures the TIMx External Trigger (ETR) which is used as Index input */
TIM_ETR_SetConfig(htim->Instance,
sEncoderIndexConfig->Prescaler,
sEncoderIndexConfig->Polarity,
sEncoderIndexConfig->Filter);
/* Configures the encoder index */
MODIFY_REG(htim->Instance->ECR,
TIM_ECR_IDIR_Msk | TIM_ECR_FIDX_Msk | TIM_ECR_IPOS_Msk,
(sEncoderIndexConfig->Direction |
((sEncoderIndexConfig->FirstIndexEnable == ENABLE) ? (0x1U << TIM_ECR_FIDX_Pos) : 0U) |
sEncoderIndexConfig->Position |
TIM_ECR_IE));
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Enable encoder index
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_EnableEncoderIndex(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
SET_BIT(htim->Instance->ECR, TIM_ECR_IE);
return HAL_OK;
}
/**
* @brief Disable encoder index
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DisableEncoderIndex(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
CLEAR_BIT(htim->Instance->ECR, TIM_ECR_IE);
return HAL_OK;
}
/**
* @brief Enable encoder first index
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_EnableEncoderFirstIndex(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
SET_BIT(htim->Instance->ECR, TIM_ECR_FIDX);
return HAL_OK;
}
/**
* @brief Disable encoder first index
* @param htim TIM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIMEx_DisableEncoderFirstIndex(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
CLEAR_BIT(htim->Instance->ECR, TIM_ECR_FIDX);
return HAL_OK;
}
/**
* @}
*/
/** @defgroup TIMEx_Exported_Functions_Group6 Extended Callbacks functions
* @brief Extended Callbacks functions
*
@verbatim
==============================================================================
##### Extended Callbacks functions #####
==============================================================================
[..]
This section provides Extended TIM callback functions:
(+) Timer Commutation callback
(+) Timer Break callback
@endverbatim
* @{
*/
/**
* @brief Commutation callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIMEx_CommutCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_CommutCallback could be implemented in the user file
*/
}
/**
* @brief Commutation half complete callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIMEx_CommutHalfCpltCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_CommutHalfCpltCallback could be implemented in the user file
*/
}
/**
* @brief Break detection callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIMEx_BreakCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_BreakCallback could be implemented in the user file
*/
}
/**
* @brief Break2 detection callback in non blocking mode
* @param htim: TIM handle
* @retval None
*/
__weak void HAL_TIMEx_Break2Callback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_TIMEx_Break2Callback could be implemented in the user file
*/
}
/**
* @brief Encoder index callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIMEx_EncoderIndexCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_EncoderIndexCallback could be implemented in the user file
*/
}
/**
* @brief Direction change callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIMEx_DirectionChangeCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_DirectionChangeCallback could be implemented in the user file
*/
}
/**
* @brief Index error callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIMEx_IndexErrorCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_IndexErrorCallback could be implemented in the user file
*/
}
/**
* @brief Transition error callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIMEx_TransitionErrorCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIMEx_TransitionErrorCallback could be implemented in the user file
*/
}
/**
* @}
*/
/** @defgroup TIMEx_Exported_Functions_Group7 Extended Peripheral State functions
* @brief Extended Peripheral State functions
*
@verbatim
==============================================================================
##### Extended Peripheral State functions #####
==============================================================================
[..]
This subsection permits to get in run-time the status of the peripheral
and the data flow.
@endverbatim
* @{
*/
/**
* @brief Return the TIM Hall Sensor interface handle state.
* @param htim TIM Hall Sensor handle
* @retval HAL state
*/
HAL_TIM_StateTypeDef HAL_TIMEx_HallSensor_GetState(const TIM_HandleTypeDef *htim)
{
return htim->State;
}
/**
* @brief Return actual state of the TIM complementary channel.
* @param htim TIM handle
* @param ChannelN TIM Complementary channel
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1
* @arg TIM_CHANNEL_2: TIM Channel 2
* @arg TIM_CHANNEL_3: TIM Channel 3
* @arg TIM_CHANNEL_4: TIM Channel 4
* @retval TIM Complementary channel state
*/
HAL_TIM_ChannelStateTypeDef HAL_TIMEx_GetChannelNState(const TIM_HandleTypeDef *htim, uint32_t ChannelN)
{
HAL_TIM_ChannelStateTypeDef channel_state;
/* Check the parameters */
assert_param(IS_TIM_CCXN_INSTANCE(htim->Instance, ChannelN));
channel_state = TIM_CHANNEL_N_STATE_GET(htim, ChannelN);
return channel_state;
}
/**
* @}
*/
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/** @defgroup TIMEx_Private_Functions TIM Extended Private Functions
* @{
*/
/**
* @brief TIM DMA Commutation callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
void TIMEx_DMACommutationCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
/* Change the htim state */
htim->State = HAL_TIM_STATE_READY;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->CommutationCallback(htim);
#else
HAL_TIMEx_CommutCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/**
* @brief TIM DMA Commutation half complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
void TIMEx_DMACommutationHalfCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
/* Change the htim state */
htim->State = HAL_TIM_STATE_READY;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->CommutationHalfCpltCallback(htim);
#else
HAL_TIMEx_CommutHalfCpltCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/**
* @brief TIM DMA Delay Pulse complete callback (complementary channel).
* @param hdma pointer to DMA handle.
* @retval None
*/
static void TIM_DMADelayPulseNCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (hdma == htim->hdma[TIM_DMA_ID_CC1])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC2])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC3])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_3, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC4])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_4, HAL_TIM_CHANNEL_STATE_READY);
}
}
else
{
/* nothing to do */
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->PWM_PulseFinishedCallback(htim);
#else
HAL_TIM_PWM_PulseFinishedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
/**
* @brief TIM DMA error callback (complementary channel)
* @param hdma pointer to DMA handle.
* @retval None
*/
static void TIM_DMAErrorCCxN(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (hdma == htim->hdma[TIM_DMA_ID_CC1])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC2])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC3])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_3, HAL_TIM_CHANNEL_STATE_READY);
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC4])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_4, HAL_TIM_CHANNEL_STATE_READY);
}
else
{
/* nothing to do */
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->ErrorCallback(htim);
#else
HAL_TIM_ErrorCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
/**
* @brief Enables or disables the TIM Capture Compare Channel xN.
* @param TIMx to select the TIM peripheral
* @param Channel specifies the TIM Channel
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1
* @arg TIM_CHANNEL_2: TIM Channel 2
* @arg TIM_CHANNEL_3: TIM Channel 3
* @arg TIM_CHANNEL_4: TIM Channel 4
* @param ChannelNState specifies the TIM Channel CCxNE bit new state.
* This parameter can be: TIM_CCxN_ENABLE or TIM_CCxN_Disable.
* @retval None
*/
static void TIM_CCxNChannelCmd(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ChannelNState)
{
uint32_t tmp;
tmp = TIM_CCER_CC1NE << (Channel & 0xFU); /* 0xFU = 15 bits max shift */
/* Reset the CCxNE Bit */
TIMx->CCER &= ~tmp;
/* Set or reset the CCxNE Bit */
TIMx->CCER |= (uint32_t)(ChannelNState << (Channel & 0xFU)); /* 0xFU = 15 bits max shift */
}
/**
* @}
*/
#endif /* HAL_TIM_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 137,122 | C | 36.231333 | 119 | 0.627974 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_cortex.c | /**
******************************************************************************
* @file stm32g4xx_hal_cortex.c
* @author MCD Application Team
* @brief CORTEX HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the CORTEX:
* + Initialization and Configuration functions
* + Peripheral Control functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
*** How to configure Interrupts using CORTEX HAL driver ***
===========================================================
[..]
This section provides functions allowing to configure the NVIC interrupts (IRQ).
The Cortex-M4 exceptions are managed by CMSIS functions.
(#) Configure the NVIC Priority Grouping using HAL_NVIC_SetPriorityGrouping() function.
(#) Configure the priority of the selected IRQ Channels using HAL_NVIC_SetPriority().
(#) Enable the selected IRQ Channels using HAL_NVIC_EnableIRQ().
-@- When the NVIC_PRIORITYGROUP_0 is selected, IRQ pre-emption is no more possible.
The pending IRQ priority will be managed only by the sub priority.
-@- IRQ priority order (sorted by highest to lowest priority):
(+@) Lowest pre-emption priority
(+@) Lowest sub priority
(+@) Lowest hardware priority (IRQ number)
[..]
*** How to configure SysTick using CORTEX HAL driver ***
========================================================
[..]
Setup SysTick Timer for time base.
(+) The HAL_SYSTICK_Config() function calls the SysTick_Config() function which
is a CMSIS function that:
(++) Configures the SysTick Reload register with value passed as function parameter.
(++) Configures the SysTick IRQ priority to the lowest value (0x0F).
(++) Resets the SysTick Counter register.
(++) Configures the SysTick Counter clock source to be Core Clock Source (HCLK).
(++) Enables the SysTick Interrupt.
(++) Starts the SysTick Counter.
(+) You can change the SysTick Clock source to be HCLK_Div8 by calling the macro
__HAL_CORTEX_SYSTICKCLK_CONFIG(SYSTICK_CLKSOURCE_HCLK_DIV8) just after the
HAL_SYSTICK_Config() function call. The __HAL_CORTEX_SYSTICKCLK_CONFIG() macro is defined
inside the stm32g4xx_hal_cortex.h file.
(+) You can change the SysTick IRQ priority by calling the
HAL_NVIC_SetPriority(SysTick_IRQn,...) function just after the HAL_SYSTICK_Config() function
call. The HAL_NVIC_SetPriority() call the NVIC_SetPriority() function which is a CMSIS function.
(+) To adjust the SysTick time base, use the following formula:
Reload Value = SysTick Counter Clock (Hz) x Desired Time base (s)
(++) Reload Value is the parameter to be passed for HAL_SYSTICK_Config() function
(++) Reload Value should not exceed 0xFFFFFF
@endverbatim
******************************************************************************
The table below gives the allowed values of the pre-emption priority and subpriority according
to the Priority Grouping configuration performed by HAL_NVIC_SetPriorityGrouping() function.
==========================================================================================================================
NVIC_PriorityGroup | NVIC_IRQChannelPreemptionPriority | NVIC_IRQChannelSubPriority | Description
==========================================================================================================================
NVIC_PRIORITYGROUP_0 | 0 | 0-15 | 0 bit for pre-emption priority
| | | 4 bits for subpriority
--------------------------------------------------------------------------------------------------------------------------
NVIC_PRIORITYGROUP_1 | 0-1 | 0-7 | 1 bit for pre-emption priority
| | | 3 bits for subpriority
--------------------------------------------------------------------------------------------------------------------------
NVIC_PRIORITYGROUP_2 | 0-3 | 0-3 | 2 bits for pre-emption priority
| | | 2 bits for subpriority
--------------------------------------------------------------------------------------------------------------------------
NVIC_PRIORITYGROUP_3 | 0-7 | 0-1 | 3 bits for pre-emption priority
| | | 1 bit for subpriority
--------------------------------------------------------------------------------------------------------------------------
NVIC_PRIORITYGROUP_4 | 0-15 | 0 | 4 bits for pre-emption priority
| | | 0 bit for subpriority
==========================================================================================================================
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup CORTEX
* @{
*/
#ifdef HAL_CORTEX_MODULE_ENABLED
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Private functions ---------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup CORTEX_Exported_Functions
* @{
*/
/** @addtogroup CORTEX_Exported_Functions_Group1
* @brief Initialization and Configuration functions
*
@verbatim
==============================================================================
##### Initialization and Configuration functions #####
==============================================================================
[..]
This section provides the CORTEX HAL driver functions allowing to configure Interrupts
SysTick functionalities
@endverbatim
* @{
*/
/**
* @brief Set the priority grouping field (pre-emption priority and subpriority)
* using the required unlock sequence.
* @param PriorityGroup: The priority grouping bits length.
* This parameter can be one of the following values:
* @arg NVIC_PRIORITYGROUP_0: 0 bit for pre-emption priority,
* 4 bits for subpriority
* @arg NVIC_PRIORITYGROUP_1: 1 bit for pre-emption priority,
* 3 bits for subpriority
* @arg NVIC_PRIORITYGROUP_2: 2 bits for pre-emption priority,
* 2 bits for subpriority
* @arg NVIC_PRIORITYGROUP_3: 3 bits for pre-emption priority,
* 1 bit for subpriority
* @arg NVIC_PRIORITYGROUP_4: 4 bits for pre-emption priority,
* 0 bit for subpriority
* @note When the NVIC_PriorityGroup_0 is selected, IRQ pre-emption is no more possible.
* The pending IRQ priority will be managed only by the subpriority.
* @retval None
*/
void HAL_NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
/* Check the parameters */
assert_param(IS_NVIC_PRIORITY_GROUP(PriorityGroup));
/* Set the PRIGROUP[10:8] bits according to the PriorityGroup parameter value */
NVIC_SetPriorityGrouping(PriorityGroup);
}
/**
* @brief Set the priority of an interrupt.
* @param IRQn: External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @param PreemptPriority: The pre-emption priority for the IRQn channel.
* This parameter can be a value between 0 and 15
* A lower priority value indicates a higher priority
* @param SubPriority: the subpriority level for the IRQ channel.
* This parameter can be a value between 0 and 15
* A lower priority value indicates a higher priority.
* @retval None
*/
void HAL_NVIC_SetPriority(IRQn_Type IRQn, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t prioritygroup;
/* Check the parameters */
assert_param(IS_NVIC_SUB_PRIORITY(SubPriority));
assert_param(IS_NVIC_PREEMPTION_PRIORITY(PreemptPriority));
prioritygroup = NVIC_GetPriorityGrouping();
NVIC_SetPriority(IRQn, NVIC_EncodePriority(prioritygroup, PreemptPriority, SubPriority));
}
/**
* @brief Enable a device specific interrupt in the NVIC interrupt controller.
* @note To configure interrupts priority correctly, the NVIC_PriorityGroupConfig()
* function should be called before.
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @retval None
*/
void HAL_NVIC_EnableIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Enable interrupt */
NVIC_EnableIRQ(IRQn);
}
/**
* @brief Disable a device specific interrupt in the NVIC interrupt controller.
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @retval None
*/
void HAL_NVIC_DisableIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Disable interrupt */
NVIC_DisableIRQ(IRQn);
}
/**
* @brief Initiate a system reset request to reset the MCU.
* @retval None
*/
void HAL_NVIC_SystemReset(void)
{
/* System Reset */
NVIC_SystemReset();
}
/**
* @brief Initialize the System Timer with interrupt enabled and start the System Tick Timer (SysTick):
* Counter is in free running mode to generate periodic interrupts.
* @param TicksNumb: Specifies the ticks Number of ticks between two interrupts.
* @retval status: - 0 Function succeeded.
* - 1 Function failed.
*/
uint32_t HAL_SYSTICK_Config(uint32_t TicksNumb)
{
return SysTick_Config(TicksNumb);
}
/**
* @}
*/
/** @addtogroup CORTEX_Exported_Functions_Group2
* @brief Cortex control functions
*
@verbatim
==============================================================================
##### Peripheral Control functions #####
==============================================================================
[..]
This subsection provides a set of functions allowing to control the CORTEX
(NVIC, SYSTICK, MPU) functionalities.
@endverbatim
* @{
*/
/**
* @brief Get the priority grouping field from the NVIC Interrupt Controller.
* @retval Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field)
*/
uint32_t HAL_NVIC_GetPriorityGrouping(void)
{
/* Get the PRIGROUP[10:8] field value */
return NVIC_GetPriorityGrouping();
}
/**
* @brief Get the priority of an interrupt.
* @param IRQn: External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @param PriorityGroup: the priority grouping bits length.
* This parameter can be one of the following values:
* @arg NVIC_PRIORITYGROUP_0: 0 bit for pre-emption priority,
* 4 bits for subpriority
* @arg NVIC_PRIORITYGROUP_1: 1 bit for pre-emption priority,
* 3 bits for subpriority
* @arg NVIC_PRIORITYGROUP_2: 2 bits for pre-emption priority,
* 2 bits for subpriority
* @arg NVIC_PRIORITYGROUP_3: 3 bits for pre-emption priority,
* 1 bit for subpriority
* @arg NVIC_PRIORITYGROUP_4: 4 bits for pre-emption priority,
* 0 bit for subpriority
* @param pPreemptPriority: Pointer on the Preemptive priority value (starting from 0).
* @param pSubPriority: Pointer on the Subpriority value (starting from 0).
* @retval None
*/
void HAL_NVIC_GetPriority(IRQn_Type IRQn, uint32_t PriorityGroup, uint32_t *pPreemptPriority, uint32_t *pSubPriority)
{
/* Check the parameters */
assert_param(IS_NVIC_PRIORITY_GROUP(PriorityGroup));
/* Get priority for Cortex-M system or device specific interrupts */
NVIC_DecodePriority(NVIC_GetPriority(IRQn), PriorityGroup, pPreemptPriority, pSubPriority);
}
/**
* @brief Set Pending bit of an external interrupt.
* @param IRQn External interrupt number
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @retval None
*/
void HAL_NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Set interrupt pending */
NVIC_SetPendingIRQ(IRQn);
}
/**
* @brief Get Pending Interrupt (read the pending register in the NVIC
* and return the pending bit for the specified interrupt).
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @retval status: - 0 Interrupt status is not pending.
* - 1 Interrupt status is pending.
*/
uint32_t HAL_NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Return 1 if pending else 0 */
return NVIC_GetPendingIRQ(IRQn);
}
/**
* @brief Clear the pending bit of an external interrupt.
* @param IRQn External interrupt number.
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @retval None
*/
void HAL_NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
/* Check the parameters */
assert_param(IS_NVIC_DEVICE_IRQ(IRQn));
/* Clear pending interrupt */
NVIC_ClearPendingIRQ(IRQn);
}
/**
* @brief Get active interrupt (read the active register in NVIC and return the active bit).
* @param IRQn External interrupt number
* This parameter can be an enumerator of IRQn_Type enumeration
* (For the complete STM32 Devices IRQ Channels list, please refer to the appropriate CMSIS device file (stm32g4xxxx.h))
* @retval status: - 0 Interrupt status is not pending.
* - 1 Interrupt status is pending.
*/
uint32_t HAL_NVIC_GetActive(IRQn_Type IRQn)
{
/* Return 1 if active else 0 */
return NVIC_GetActive(IRQn);
}
/**
* @brief Configure the SysTick clock source.
* @param CLKSource: specifies the SysTick clock source.
* This parameter can be one of the following values:
* @arg SYSTICK_CLKSOURCE_HCLK_DIV8: AHB clock divided by 8 selected as SysTick clock source.
* @arg SYSTICK_CLKSOURCE_HCLK: AHB clock selected as SysTick clock source.
* @retval None
*/
void HAL_SYSTICK_CLKSourceConfig(uint32_t CLKSource)
{
/* Check the parameters */
assert_param(IS_SYSTICK_CLK_SOURCE(CLKSource));
if (CLKSource == SYSTICK_CLKSOURCE_HCLK)
{
SysTick->CTRL |= SYSTICK_CLKSOURCE_HCLK;
}
else
{
SysTick->CTRL &= ~SYSTICK_CLKSOURCE_HCLK;
}
}
/**
* @brief Handle SYSTICK interrupt request.
* @retval None
*/
void HAL_SYSTICK_IRQHandler(void)
{
HAL_SYSTICK_Callback();
}
/**
* @brief SYSTICK callback.
* @retval None
*/
__weak void HAL_SYSTICK_Callback(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_SYSTICK_Callback could be implemented in the user file
*/
}
#if (__MPU_PRESENT == 1)
/**
* @brief Enable the MPU.
* @param MPU_Control: Specifies the control mode of the MPU during hard fault,
* NMI, FAULTMASK and privileged accessto the default memory
* This parameter can be one of the following values:
* @arg MPU_HFNMI_PRIVDEF_NONE
* @arg MPU_HARDFAULT_NMI
* @arg MPU_PRIVILEGED_DEFAULT
* @arg MPU_HFNMI_PRIVDEF
* @retval None
*/
void HAL_MPU_Enable(uint32_t MPU_Control)
{
/* Enable the MPU */
MPU->CTRL = (MPU_Control | MPU_CTRL_ENABLE_Msk);
/* Ensure MPU setting take effects */
__DSB();
__ISB();
}
/**
* @brief Disable the MPU.
* @retval None
*/
void HAL_MPU_Disable(void)
{
/* Make sure outstanding transfers are done */
__DMB();
/* Disable the MPU and clear the control register*/
MPU->CTRL = 0;
}
/**
* @brief Initialize and configure the Region and the memory to be protected.
* @param MPU_Init: Pointer to a MPU_Region_InitTypeDef structure that contains
* the initialization and configuration information.
* @retval None
*/
void HAL_MPU_ConfigRegion(MPU_Region_InitTypeDef *MPU_Init)
{
/* Check the parameters */
assert_param(IS_MPU_REGION_NUMBER(MPU_Init->Number));
assert_param(IS_MPU_REGION_ENABLE(MPU_Init->Enable));
/* Set the Region number */
MPU->RNR = MPU_Init->Number;
if ((MPU_Init->Enable) != 0U)
{
/* Check the parameters */
assert_param(IS_MPU_INSTRUCTION_ACCESS(MPU_Init->DisableExec));
assert_param(IS_MPU_REGION_PERMISSION_ATTRIBUTE(MPU_Init->AccessPermission));
assert_param(IS_MPU_TEX_LEVEL(MPU_Init->TypeExtField));
assert_param(IS_MPU_ACCESS_SHAREABLE(MPU_Init->IsShareable));
assert_param(IS_MPU_ACCESS_CACHEABLE(MPU_Init->IsCacheable));
assert_param(IS_MPU_ACCESS_BUFFERABLE(MPU_Init->IsBufferable));
assert_param(IS_MPU_SUB_REGION_DISABLE(MPU_Init->SubRegionDisable));
assert_param(IS_MPU_REGION_SIZE(MPU_Init->Size));
MPU->RBAR = MPU_Init->BaseAddress;
MPU->RASR = ((uint32_t)MPU_Init->DisableExec << MPU_RASR_XN_Pos) |
((uint32_t)MPU_Init->AccessPermission << MPU_RASR_AP_Pos) |
((uint32_t)MPU_Init->TypeExtField << MPU_RASR_TEX_Pos) |
((uint32_t)MPU_Init->IsShareable << MPU_RASR_S_Pos) |
((uint32_t)MPU_Init->IsCacheable << MPU_RASR_C_Pos) |
((uint32_t)MPU_Init->IsBufferable << MPU_RASR_B_Pos) |
((uint32_t)MPU_Init->SubRegionDisable << MPU_RASR_SRD_Pos) |
((uint32_t)MPU_Init->Size << MPU_RASR_SIZE_Pos) |
((uint32_t)MPU_Init->Enable << MPU_RASR_ENABLE_Pos);
}
else
{
MPU->RBAR = 0x00;
MPU->RASR = 0x00;
}
}
#endif /* __MPU_PRESENT */
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_CORTEX_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 20,537 | C | 38.648649 | 139 | 0.560793 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_tim.c | /**
******************************************************************************
* @file stm32g4xx_hal_tim.c
* @author MCD Application Team
* @brief TIM HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Timer (TIM) peripheral:
* + TIM Time Base Initialization
* + TIM Time Base Start
* + TIM Time Base Start Interruption
* + TIM Time Base Start DMA
* + TIM Output Compare/PWM Initialization
* + TIM Output Compare/PWM Channel Configuration
* + TIM Output Compare/PWM Start
* + TIM Output Compare/PWM Start Interruption
* + TIM Output Compare/PWM Start DMA
* + TIM Input Capture Initialization
* + TIM Input Capture Channel Configuration
* + TIM Input Capture Start
* + TIM Input Capture Start Interruption
* + TIM Input Capture Start DMA
* + TIM One Pulse Initialization
* + TIM One Pulse Channel Configuration
* + TIM One Pulse Start
* + TIM Encoder Interface Initialization
* + TIM Encoder Interface Start
* + TIM Encoder Interface Start Interruption
* + TIM Encoder Interface Start DMA
* + Commutation Event configuration with Interruption and DMA
* + TIM OCRef clear configuration
* + TIM External Clock configuration
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### TIMER Generic features #####
==============================================================================
[..] The Timer features include:
(#) 16-bit up, down, up/down auto-reload counter.
(#) 16-bit programmable prescaler allowing dividing (also on the fly) the
counter clock frequency either by any factor between 1 and 65536.
(#) Up to 4 independent channels for:
(++) Input Capture
(++) Output Compare
(++) PWM generation (Edge and Center-aligned Mode)
(++) One-pulse mode output
(#) Synchronization circuit to control the timer with external signals and to interconnect
several timers together.
(#) Supports incremental encoder for positioning purposes
##### How to use this driver #####
==============================================================================
[..]
(#) Initialize the TIM low level resources by implementing the following functions
depending on the selected feature:
(++) Time Base : HAL_TIM_Base_MspInit()
(++) Input Capture : HAL_TIM_IC_MspInit()
(++) Output Compare : HAL_TIM_OC_MspInit()
(++) PWM generation : HAL_TIM_PWM_MspInit()
(++) One-pulse mode output : HAL_TIM_OnePulse_MspInit()
(++) Encoder mode output : HAL_TIM_Encoder_MspInit()
(#) Initialize the TIM low level resources :
(##) Enable the TIM interface clock using __HAL_RCC_TIMx_CLK_ENABLE();
(##) TIM pins configuration
(+++) Enable the clock for the TIM GPIOs using the following function:
__HAL_RCC_GPIOx_CLK_ENABLE();
(+++) Configure these TIM pins in Alternate function mode using HAL_GPIO_Init();
(#) The external Clock can be configured, if needed (the default clock is the
internal clock from the APBx), using the following function:
HAL_TIM_ConfigClockSource, the clock configuration should be done before
any start function.
(#) Configure the TIM in the desired functioning mode using one of the
Initialization function of this driver:
(++) HAL_TIM_Base_Init: to use the Timer to generate a simple time base
(++) HAL_TIM_OC_Init, HAL_TIM_OC_ConfigChannel and optionally HAL_TIMEx_OC_ConfigPulseOnCompare:
to use the Timer to generate an Output Compare signal.
(++) HAL_TIM_PWM_Init and HAL_TIM_PWM_ConfigChannel: to use the Timer to generate a
PWM signal.
(++) HAL_TIM_IC_Init and HAL_TIM_IC_ConfigChannel: to use the Timer to measure an
external signal.
(++) HAL_TIM_OnePulse_Init and HAL_TIM_OnePulse_ConfigChannel: to use the Timer
in One Pulse Mode.
(++) HAL_TIM_Encoder_Init: to use the Timer Encoder Interface.
(#) Activate the TIM peripheral using one of the start functions depending from the feature used:
(++) Time Base : HAL_TIM_Base_Start(), HAL_TIM_Base_Start_DMA(), HAL_TIM_Base_Start_IT()
(++) Input Capture : HAL_TIM_IC_Start(), HAL_TIM_IC_Start_DMA(), HAL_TIM_IC_Start_IT()
(++) Output Compare : HAL_TIM_OC_Start(), HAL_TIM_OC_Start_DMA(), HAL_TIM_OC_Start_IT()
(++) PWM generation : HAL_TIM_PWM_Start(), HAL_TIM_PWM_Start_DMA(), HAL_TIM_PWM_Start_IT()
(++) One-pulse mode output : HAL_TIM_OnePulse_Start(), HAL_TIM_OnePulse_Start_IT()
(++) Encoder mode output : HAL_TIM_Encoder_Start(), HAL_TIM_Encoder_Start_DMA(), HAL_TIM_Encoder_Start_IT().
(#) The DMA Burst is managed with the two following functions:
HAL_TIM_DMABurst_WriteStart()
HAL_TIM_DMABurst_ReadStart()
*** Callback registration ***
=============================================
[..]
The compilation define USE_HAL_TIM_REGISTER_CALLBACKS when set to 1
allows the user to configure dynamically the driver callbacks.
[..]
Use Function HAL_TIM_RegisterCallback() to register a callback.
HAL_TIM_RegisterCallback() takes as parameters the HAL peripheral handle,
the Callback ID and a pointer to the user callback function.
[..]
Use function HAL_TIM_UnRegisterCallback() to reset a callback to the default
weak function.
HAL_TIM_UnRegisterCallback takes as parameters the HAL peripheral handle,
and the Callback ID.
[..]
These functions allow to register/unregister following callbacks:
(+) Base_MspInitCallback : TIM Base Msp Init Callback.
(+) Base_MspDeInitCallback : TIM Base Msp DeInit Callback.
(+) IC_MspInitCallback : TIM IC Msp Init Callback.
(+) IC_MspDeInitCallback : TIM IC Msp DeInit Callback.
(+) OC_MspInitCallback : TIM OC Msp Init Callback.
(+) OC_MspDeInitCallback : TIM OC Msp DeInit Callback.
(+) PWM_MspInitCallback : TIM PWM Msp Init Callback.
(+) PWM_MspDeInitCallback : TIM PWM Msp DeInit Callback.
(+) OnePulse_MspInitCallback : TIM One Pulse Msp Init Callback.
(+) OnePulse_MspDeInitCallback : TIM One Pulse Msp DeInit Callback.
(+) Encoder_MspInitCallback : TIM Encoder Msp Init Callback.
(+) Encoder_MspDeInitCallback : TIM Encoder Msp DeInit Callback.
(+) HallSensor_MspInitCallback : TIM Hall Sensor Msp Init Callback.
(+) HallSensor_MspDeInitCallback : TIM Hall Sensor Msp DeInit Callback.
(+) PeriodElapsedCallback : TIM Period Elapsed Callback.
(+) PeriodElapsedHalfCpltCallback : TIM Period Elapsed half complete Callback.
(+) TriggerCallback : TIM Trigger Callback.
(+) TriggerHalfCpltCallback : TIM Trigger half complete Callback.
(+) IC_CaptureCallback : TIM Input Capture Callback.
(+) IC_CaptureHalfCpltCallback : TIM Input Capture half complete Callback.
(+) OC_DelayElapsedCallback : TIM Output Compare Delay Elapsed Callback.
(+) PWM_PulseFinishedCallback : TIM PWM Pulse Finished Callback.
(+) PWM_PulseFinishedHalfCpltCallback : TIM PWM Pulse Finished half complete Callback.
(+) ErrorCallback : TIM Error Callback.
(+) CommutationCallback : TIM Commutation Callback.
(+) CommutationHalfCpltCallback : TIM Commutation half complete Callback.
(+) BreakCallback : TIM Break Callback.
(+) Break2Callback : TIM Break2 Callback.
(+) EncoderIndexCallback : TIM Encoder Index Callback.
(+) DirectionChangeCallback : TIM Direction Change Callback
(+) IndexErrorCallback : TIM Index Error Callback.
(+) TransitionErrorCallback : TIM Transition Error Callback
[..]
By default, after the Init and when the state is HAL_TIM_STATE_RESET
all interrupt callbacks are set to the corresponding weak functions:
examples HAL_TIM_TriggerCallback(), HAL_TIM_ErrorCallback().
[..]
Exception done for MspInit and MspDeInit functions that are reset to the legacy weak
functionalities in the Init / DeInit only when these callbacks are null
(not registered beforehand). If not, MspInit or MspDeInit are not null, the Init / DeInit
keep and use the user MspInit / MspDeInit callbacks(registered beforehand)
[..]
Callbacks can be registered / unregistered in HAL_TIM_STATE_READY state only.
Exception done MspInit / MspDeInit that can be registered / unregistered
in HAL_TIM_STATE_READY or HAL_TIM_STATE_RESET state,
thus registered(user) MspInit / DeInit callbacks can be used during the Init / DeInit.
In that case first register the MspInit/MspDeInit user callbacks
using HAL_TIM_RegisterCallback() before calling DeInit or Init function.
[..]
When The compilation define USE_HAL_TIM_REGISTER_CALLBACKS is set to 0 or
not defined, the callback registration feature is not available and all callbacks
are set to the corresponding weak functions.
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup TIM TIM
* @brief TIM HAL module driver
* @{
*/
#ifdef HAL_TIM_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @addtogroup TIM_Private_Constants
* @{
*/
#define TIMx_AF2_OCRSEL TIM1_AF2_OCRSEL
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @addtogroup TIM_Private_Functions
* @{
*/
static void TIM_OC1_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config);
static void TIM_OC3_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config);
static void TIM_OC4_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config);
static void TIM_OC5_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config);
static void TIM_OC6_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config);
static void TIM_TI1_ConfigInputStage(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICFilter);
static void TIM_TI2_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection,
uint32_t TIM_ICFilter);
static void TIM_TI2_ConfigInputStage(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICFilter);
static void TIM_TI3_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection,
uint32_t TIM_ICFilter);
static void TIM_TI4_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection,
uint32_t TIM_ICFilter);
static void TIM_ITRx_SetConfig(TIM_TypeDef *TIMx, uint32_t InputTriggerSource);
static void TIM_DMAPeriodElapsedCplt(DMA_HandleTypeDef *hdma);
static void TIM_DMAPeriodElapsedHalfCplt(DMA_HandleTypeDef *hdma);
static void TIM_DMADelayPulseCplt(DMA_HandleTypeDef *hdma);
static void TIM_DMATriggerCplt(DMA_HandleTypeDef *hdma);
static void TIM_DMATriggerHalfCplt(DMA_HandleTypeDef *hdma);
static HAL_StatusTypeDef TIM_SlaveTimer_SetConfig(TIM_HandleTypeDef *htim,
const TIM_SlaveConfigTypeDef *sSlaveConfig);
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup TIM_Exported_Functions TIM Exported Functions
* @{
*/
/** @defgroup TIM_Exported_Functions_Group1 TIM Time Base functions
* @brief Time Base functions
*
@verbatim
==============================================================================
##### Time Base functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Initialize and configure the TIM base.
(+) De-initialize the TIM base.
(+) Start the Time Base.
(+) Stop the Time Base.
(+) Start the Time Base and enable interrupt.
(+) Stop the Time Base and disable interrupt.
(+) Start the Time Base and enable DMA transfer.
(+) Stop the Time Base and disable DMA transfer.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM Time base Unit according to the specified
* parameters in the TIM_HandleTypeDef and initialize the associated handle.
* @note Switching from Center Aligned counter mode to Edge counter mode (or reverse)
* requires a timer reset to avoid unexpected direction
* due to DIR bit readonly in center aligned mode.
* Ex: call @ref HAL_TIM_Base_DeInit() before HAL_TIM_Base_Init()
* @param htim TIM Base handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_Init(TIM_HandleTypeDef *htim)
{
/* Check the TIM handle allocation */
if (htim == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
assert_param(IS_TIM_COUNTER_MODE(htim->Init.CounterMode));
assert_param(IS_TIM_CLOCKDIVISION_DIV(htim->Init.ClockDivision));
assert_param(IS_TIM_PERIOD(htim, htim->Init.Period));
assert_param(IS_TIM_AUTORELOAD_PRELOAD(htim->Init.AutoReloadPreload));
if (htim->State == HAL_TIM_STATE_RESET)
{
/* Allocate lock resource and initialize it */
htim->Lock = HAL_UNLOCKED;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/* Reset interrupt callbacks to legacy weak callbacks */
TIM_ResetCallback(htim);
if (htim->Base_MspInitCallback == NULL)
{
htim->Base_MspInitCallback = HAL_TIM_Base_MspInit;
}
/* Init the low level hardware : GPIO, CLOCK, NVIC */
htim->Base_MspInitCallback(htim);
#else
/* Init the low level hardware : GPIO, CLOCK, NVIC */
HAL_TIM_Base_MspInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Set the Time Base configuration */
TIM_Base_SetConfig(htim->Instance, &htim->Init);
/* Initialize the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
/* Initialize the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
/* Initialize the TIM state*/
htim->State = HAL_TIM_STATE_READY;
return HAL_OK;
}
/**
* @brief DeInitializes the TIM Base peripheral
* @param htim TIM Base handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_DeInit(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
htim->State = HAL_TIM_STATE_BUSY;
/* Disable the TIM Peripheral Clock */
__HAL_TIM_DISABLE(htim);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
if (htim->Base_MspDeInitCallback == NULL)
{
htim->Base_MspDeInitCallback = HAL_TIM_Base_MspDeInit;
}
/* DeInit the low level hardware */
htim->Base_MspDeInitCallback(htim);
#else
/* DeInit the low level hardware: GPIO, CLOCK, NVIC */
HAL_TIM_Base_MspDeInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_RESET;
/* Change the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
/* Change TIM state */
htim->State = HAL_TIM_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Initializes the TIM Base MSP.
* @param htim TIM Base handle
* @retval None
*/
__weak void HAL_TIM_Base_MspInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_Base_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes TIM Base MSP.
* @param htim TIM Base handle
* @retval None
*/
__weak void HAL_TIM_Base_MspDeInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_Base_MspDeInit could be implemented in the user file
*/
}
/**
* @brief Starts the TIM Base generation.
* @param htim TIM Base handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_Start(TIM_HandleTypeDef *htim)
{
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
/* Check the TIM state */
if (htim->State != HAL_TIM_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Base generation.
* @param htim TIM Base handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_Stop(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM state */
htim->State = HAL_TIM_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Base generation in interrupt mode.
* @param htim TIM Base handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_Start_IT(TIM_HandleTypeDef *htim)
{
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
/* Check the TIM state */
if (htim->State != HAL_TIM_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Enable the TIM Update interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_UPDATE);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Base generation in interrupt mode.
* @param htim TIM Base handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_Stop_IT(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
/* Disable the TIM Update interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_UPDATE);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM state */
htim->State = HAL_TIM_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Base generation in DMA mode.
* @param htim TIM Base handle
* @param pData The source Buffer address.
* @param Length The length of data to be transferred from memory to peripheral.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_Start_DMA(TIM_HandleTypeDef *htim, const uint32_t *pData, uint16_t Length)
{
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_DMA_INSTANCE(htim->Instance));
/* Set the TIM state */
if (htim->State == HAL_TIM_STATE_BUSY)
{
return HAL_BUSY;
}
else if (htim->State == HAL_TIM_STATE_READY)
{
if ((pData == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
htim->State = HAL_TIM_STATE_BUSY;
}
}
else
{
return HAL_ERROR;
}
/* Set the DMA Period elapsed callbacks */
htim->hdma[TIM_DMA_ID_UPDATE]->XferCpltCallback = TIM_DMAPeriodElapsedCplt;
htim->hdma[TIM_DMA_ID_UPDATE]->XferHalfCpltCallback = TIM_DMAPeriodElapsedHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_UPDATE]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_UPDATE], (uint32_t)pData, (uint32_t)&htim->Instance->ARR,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Update DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_UPDATE);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Base generation in DMA mode.
* @param htim TIM Base handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Base_Stop_DMA(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_DMA_INSTANCE(htim->Instance));
/* Disable the TIM Update DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_UPDATE);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_UPDATE]);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM state */
htim->State = HAL_TIM_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group2 TIM Output Compare functions
* @brief TIM Output Compare functions
*
@verbatim
==============================================================================
##### TIM Output Compare functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Initialize and configure the TIM Output Compare.
(+) De-initialize the TIM Output Compare.
(+) Start the TIM Output Compare.
(+) Stop the TIM Output Compare.
(+) Start the TIM Output Compare and enable interrupt.
(+) Stop the TIM Output Compare and disable interrupt.
(+) Start the TIM Output Compare and enable DMA transfer.
(+) Stop the TIM Output Compare and disable DMA transfer.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM Output Compare according to the specified
* parameters in the TIM_HandleTypeDef and initializes the associated handle.
* @note Switching from Center Aligned counter mode to Edge counter mode (or reverse)
* requires a timer reset to avoid unexpected direction
* due to DIR bit readonly in center aligned mode.
* Ex: call @ref HAL_TIM_OC_DeInit() before HAL_TIM_OC_Init()
* @param htim TIM Output Compare handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_Init(TIM_HandleTypeDef *htim)
{
/* Check the TIM handle allocation */
if (htim == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
assert_param(IS_TIM_COUNTER_MODE(htim->Init.CounterMode));
assert_param(IS_TIM_CLOCKDIVISION_DIV(htim->Init.ClockDivision));
assert_param(IS_TIM_PERIOD(htim, htim->Init.Period));
assert_param(IS_TIM_AUTORELOAD_PRELOAD(htim->Init.AutoReloadPreload));
if (htim->State == HAL_TIM_STATE_RESET)
{
/* Allocate lock resource and initialize it */
htim->Lock = HAL_UNLOCKED;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/* Reset interrupt callbacks to legacy weak callbacks */
TIM_ResetCallback(htim);
if (htim->OC_MspInitCallback == NULL)
{
htim->OC_MspInitCallback = HAL_TIM_OC_MspInit;
}
/* Init the low level hardware : GPIO, CLOCK, NVIC */
htim->OC_MspInitCallback(htim);
#else
/* Init the low level hardware : GPIO, CLOCK, NVIC and DMA */
HAL_TIM_OC_MspInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Init the base time for the Output Compare */
TIM_Base_SetConfig(htim->Instance, &htim->Init);
/* Initialize the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
/* Initialize the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
/* Initialize the TIM state*/
htim->State = HAL_TIM_STATE_READY;
return HAL_OK;
}
/**
* @brief DeInitializes the TIM peripheral
* @param htim TIM Output Compare handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_DeInit(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
htim->State = HAL_TIM_STATE_BUSY;
/* Disable the TIM Peripheral Clock */
__HAL_TIM_DISABLE(htim);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
if (htim->OC_MspDeInitCallback == NULL)
{
htim->OC_MspDeInitCallback = HAL_TIM_OC_MspDeInit;
}
/* DeInit the low level hardware */
htim->OC_MspDeInitCallback(htim);
#else
/* DeInit the low level hardware: GPIO, CLOCK, NVIC and DMA */
HAL_TIM_OC_MspDeInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_RESET;
/* Change the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
/* Change TIM state */
htim->State = HAL_TIM_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Initializes the TIM Output Compare MSP.
* @param htim TIM Output Compare handle
* @retval None
*/
__weak void HAL_TIM_OC_MspInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_OC_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes TIM Output Compare MSP.
* @param htim TIM Output Compare handle
* @retval None
*/
__weak void HAL_TIM_OC_MspDeInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_OC_MspDeInit could be implemented in the user file
*/
}
/**
* @brief Starts the TIM Output Compare signal generation.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_Start(TIM_HandleTypeDef *htim, uint32_t Channel)
{
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCX_INSTANCE(htim->Instance, Channel));
/* Check the TIM channel state */
if (TIM_CHANNEL_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the Output compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Output Compare signal generation.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_Stop(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_CCX_INSTANCE(htim->Instance, Channel));
/* Disable the Output compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Output Compare signal generation in interrupt mode.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
/* Check the TIM channel state */
if (TIM_CHANNEL_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Enable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Enable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Enable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Enable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the Output compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM Output Compare signal generation in interrupt mode.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Output compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @brief Starts the TIM Output Compare signal generation in DMA mode.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @param pData The source Buffer address.
* @param Length The length of data to be transferred from memory to TIM peripheral
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
/* Set the TIM channel state */
if (TIM_CHANNEL_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_BUSY)
{
return HAL_BUSY;
}
else if (TIM_CHANNEL_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_READY)
{
if ((pData == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)pData, (uint32_t)&htim->Instance->CCR1,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)pData, (uint32_t)&htim->Instance->CCR2,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC3]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC3]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC3]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC3], (uint32_t)pData, (uint32_t)&htim->Instance->CCR3,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 3 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC4]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC4]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC4]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC4], (uint32_t)pData, (uint32_t)&htim->Instance->CCR4,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 4 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the Output compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM Output Compare signal generation in DMA mode.
* @param htim TIM Output Compare handle
* @param Channel TIM Channel to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC2);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC3);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC3]);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC4);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC4]);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Output compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group3 TIM PWM functions
* @brief TIM PWM functions
*
@verbatim
==============================================================================
##### TIM PWM functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Initialize and configure the TIM PWM.
(+) De-initialize the TIM PWM.
(+) Start the TIM PWM.
(+) Stop the TIM PWM.
(+) Start the TIM PWM and enable interrupt.
(+) Stop the TIM PWM and disable interrupt.
(+) Start the TIM PWM and enable DMA transfer.
(+) Stop the TIM PWM and disable DMA transfer.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM PWM Time Base according to the specified
* parameters in the TIM_HandleTypeDef and initializes the associated handle.
* @note Switching from Center Aligned counter mode to Edge counter mode (or reverse)
* requires a timer reset to avoid unexpected direction
* due to DIR bit readonly in center aligned mode.
* Ex: call @ref HAL_TIM_PWM_DeInit() before HAL_TIM_PWM_Init()
* @param htim TIM PWM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_Init(TIM_HandleTypeDef *htim)
{
/* Check the TIM handle allocation */
if (htim == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
assert_param(IS_TIM_COUNTER_MODE(htim->Init.CounterMode));
assert_param(IS_TIM_CLOCKDIVISION_DIV(htim->Init.ClockDivision));
assert_param(IS_TIM_PERIOD(htim, htim->Init.Period));
assert_param(IS_TIM_AUTORELOAD_PRELOAD(htim->Init.AutoReloadPreload));
if (htim->State == HAL_TIM_STATE_RESET)
{
/* Allocate lock resource and initialize it */
htim->Lock = HAL_UNLOCKED;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/* Reset interrupt callbacks to legacy weak callbacks */
TIM_ResetCallback(htim);
if (htim->PWM_MspInitCallback == NULL)
{
htim->PWM_MspInitCallback = HAL_TIM_PWM_MspInit;
}
/* Init the low level hardware : GPIO, CLOCK, NVIC */
htim->PWM_MspInitCallback(htim);
#else
/* Init the low level hardware : GPIO, CLOCK, NVIC and DMA */
HAL_TIM_PWM_MspInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Init the base time for the PWM */
TIM_Base_SetConfig(htim->Instance, &htim->Init);
/* Initialize the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
/* Initialize the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
/* Initialize the TIM state*/
htim->State = HAL_TIM_STATE_READY;
return HAL_OK;
}
/**
* @brief DeInitializes the TIM peripheral
* @param htim TIM PWM handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_DeInit(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
htim->State = HAL_TIM_STATE_BUSY;
/* Disable the TIM Peripheral Clock */
__HAL_TIM_DISABLE(htim);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
if (htim->PWM_MspDeInitCallback == NULL)
{
htim->PWM_MspDeInitCallback = HAL_TIM_PWM_MspDeInit;
}
/* DeInit the low level hardware */
htim->PWM_MspDeInitCallback(htim);
#else
/* DeInit the low level hardware: GPIO, CLOCK, NVIC and DMA */
HAL_TIM_PWM_MspDeInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_RESET;
/* Change the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
/* Change TIM state */
htim->State = HAL_TIM_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Initializes the TIM PWM MSP.
* @param htim TIM PWM handle
* @retval None
*/
__weak void HAL_TIM_PWM_MspInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_PWM_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes TIM PWM MSP.
* @param htim TIM PWM handle
* @retval None
*/
__weak void HAL_TIM_PWM_MspDeInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_PWM_MspDeInit could be implemented in the user file
*/
}
/**
* @brief Starts the PWM signal generation.
* @param htim TIM handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_Start(TIM_HandleTypeDef *htim, uint32_t Channel)
{
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCX_INSTANCE(htim->Instance, Channel));
/* Check the TIM channel state */
if (TIM_CHANNEL_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the PWM signal generation.
* @param htim TIM PWM handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_Stop(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_CCX_INSTANCE(htim->Instance, Channel));
/* Disable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the PWM signal generation in interrupt mode.
* @param htim TIM PWM handle
* @param Channel TIM Channel to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
/* Check the TIM channel state */
if (TIM_CHANNEL_STATE_GET(htim, Channel) != HAL_TIM_CHANNEL_STATE_READY)
{
return HAL_ERROR;
}
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Enable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Enable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Enable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Enable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the PWM signal generation in interrupt mode.
* @param htim TIM PWM handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @brief Starts the TIM PWM signal generation in DMA mode.
* @param htim TIM PWM handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @param pData The source Buffer address.
* @param Length The length of data to be transferred from memory to TIM peripheral
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
/* Set the TIM channel state */
if (TIM_CHANNEL_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_BUSY)
{
return HAL_BUSY;
}
else if (TIM_CHANNEL_STATE_GET(htim, Channel) == HAL_TIM_CHANNEL_STATE_READY)
{
if ((pData == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)pData, (uint32_t)&htim->Instance->CCR1,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)pData, (uint32_t)&htim->Instance->CCR2,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC3]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC3]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC3]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC3], (uint32_t)pData, (uint32_t)&htim->Instance->CCR3,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Output Capture/Compare 3 request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC4]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC4]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC4]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC4], (uint32_t)pData, (uint32_t)&htim->Instance->CCR4,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 4 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM PWM signal generation in DMA mode.
* @param htim TIM PWM handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC2);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC3);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC3]);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC4);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC4]);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group4 TIM Input Capture functions
* @brief TIM Input Capture functions
*
@verbatim
==============================================================================
##### TIM Input Capture functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Initialize and configure the TIM Input Capture.
(+) De-initialize the TIM Input Capture.
(+) Start the TIM Input Capture.
(+) Stop the TIM Input Capture.
(+) Start the TIM Input Capture and enable interrupt.
(+) Stop the TIM Input Capture and disable interrupt.
(+) Start the TIM Input Capture and enable DMA transfer.
(+) Stop the TIM Input Capture and disable DMA transfer.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM Input Capture Time base according to the specified
* parameters in the TIM_HandleTypeDef and initializes the associated handle.
* @note Switching from Center Aligned counter mode to Edge counter mode (or reverse)
* requires a timer reset to avoid unexpected direction
* due to DIR bit readonly in center aligned mode.
* Ex: call @ref HAL_TIM_IC_DeInit() before HAL_TIM_IC_Init()
* @param htim TIM Input Capture handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_Init(TIM_HandleTypeDef *htim)
{
/* Check the TIM handle allocation */
if (htim == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
assert_param(IS_TIM_COUNTER_MODE(htim->Init.CounterMode));
assert_param(IS_TIM_CLOCKDIVISION_DIV(htim->Init.ClockDivision));
assert_param(IS_TIM_PERIOD(htim, htim->Init.Period));
assert_param(IS_TIM_AUTORELOAD_PRELOAD(htim->Init.AutoReloadPreload));
if (htim->State == HAL_TIM_STATE_RESET)
{
/* Allocate lock resource and initialize it */
htim->Lock = HAL_UNLOCKED;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/* Reset interrupt callbacks to legacy weak callbacks */
TIM_ResetCallback(htim);
if (htim->IC_MspInitCallback == NULL)
{
htim->IC_MspInitCallback = HAL_TIM_IC_MspInit;
}
/* Init the low level hardware : GPIO, CLOCK, NVIC */
htim->IC_MspInitCallback(htim);
#else
/* Init the low level hardware : GPIO, CLOCK, NVIC and DMA */
HAL_TIM_IC_MspInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Init the base time for the input capture */
TIM_Base_SetConfig(htim->Instance, &htim->Init);
/* Initialize the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
/* Initialize the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_READY);
/* Initialize the TIM state*/
htim->State = HAL_TIM_STATE_READY;
return HAL_OK;
}
/**
* @brief DeInitializes the TIM peripheral
* @param htim TIM Input Capture handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_DeInit(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
htim->State = HAL_TIM_STATE_BUSY;
/* Disable the TIM Peripheral Clock */
__HAL_TIM_DISABLE(htim);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
if (htim->IC_MspDeInitCallback == NULL)
{
htim->IC_MspDeInitCallback = HAL_TIM_IC_MspDeInit;
}
/* DeInit the low level hardware */
htim->IC_MspDeInitCallback(htim);
#else
/* DeInit the low level hardware: GPIO, CLOCK, NVIC and DMA */
HAL_TIM_IC_MspDeInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_RESET;
/* Change the TIM channels state */
TIM_CHANNEL_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET_ALL(htim, HAL_TIM_CHANNEL_STATE_RESET);
/* Change TIM state */
htim->State = HAL_TIM_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Initializes the TIM Input Capture MSP.
* @param htim TIM Input Capture handle
* @retval None
*/
__weak void HAL_TIM_IC_MspInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_IC_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes TIM Input Capture MSP.
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_IC_MspDeInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_IC_MspDeInit could be implemented in the user file
*/
}
/**
* @brief Starts the TIM Input Capture measurement.
* @param htim TIM Input Capture handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_Start(TIM_HandleTypeDef *htim, uint32_t Channel)
{
uint32_t tmpsmcr;
HAL_TIM_ChannelStateTypeDef channel_state = TIM_CHANNEL_STATE_GET(htim, Channel);
HAL_TIM_ChannelStateTypeDef complementary_channel_state = TIM_CHANNEL_N_STATE_GET(htim, Channel);
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
/* Check the TIM channel state */
if ((channel_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the Input Capture channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Input Capture measurement.
* @param htim TIM Input Capture handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_Stop(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
/* Disable the Input Capture channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Input Capture measurement in interrupt mode.
* @param htim TIM Input Capture handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
HAL_TIM_ChannelStateTypeDef channel_state = TIM_CHANNEL_STATE_GET(htim, Channel);
HAL_TIM_ChannelStateTypeDef complementary_channel_state = TIM_CHANNEL_N_STATE_GET(htim, Channel);
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
/* Check the TIM channel state */
if ((channel_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Enable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Enable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Enable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Enable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Enable the Input Capture channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM Input Capture measurement in interrupt mode.
* @param htim TIM Input Capture handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Input Capture channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @brief Starts the TIM Input Capture measurement in DMA mode.
* @param htim TIM Input Capture handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @param pData The destination Buffer address.
* @param Length The length of data to be transferred from TIM peripheral to memory.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, uint32_t *pData, uint16_t Length)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
HAL_TIM_ChannelStateTypeDef channel_state = TIM_CHANNEL_STATE_GET(htim, Channel);
HAL_TIM_ChannelStateTypeDef complementary_channel_state = TIM_CHANNEL_N_STATE_GET(htim, Channel);
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
assert_param(IS_TIM_DMA_CC_INSTANCE(htim->Instance));
/* Set the TIM channel state */
if ((channel_state == HAL_TIM_CHANNEL_STATE_BUSY)
|| (complementary_channel_state == HAL_TIM_CHANNEL_STATE_BUSY))
{
return HAL_BUSY;
}
else if ((channel_state == HAL_TIM_CHANNEL_STATE_READY)
&& (complementary_channel_state == HAL_TIM_CHANNEL_STATE_READY))
{
if ((pData == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
/* Enable the Input Capture channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_ENABLE);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)&htim->Instance->CCR1, (uint32_t)pData,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
break;
}
case TIM_CHANNEL_2:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)&htim->Instance->CCR2, (uint32_t)pData,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC2);
break;
}
case TIM_CHANNEL_3:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC3]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC3]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC3]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC3], (uint32_t)&htim->Instance->CCR3, (uint32_t)pData,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 3 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC3);
break;
}
case TIM_CHANNEL_4:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC4]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC4]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC4]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC4], (uint32_t)&htim->Instance->CCR4, (uint32_t)pData,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Capture/Compare 4 DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC4);
break;
}
default:
status = HAL_ERROR;
break;
}
/* Enable the Peripheral, except in trigger mode where enable is automatically done with trigger */
if (IS_TIM_SLAVE_INSTANCE(htim->Instance))
{
tmpsmcr = htim->Instance->SMCR & TIM_SMCR_SMS;
if (!IS_TIM_SLAVEMODE_TRIGGER_ENABLED(tmpsmcr))
{
__HAL_TIM_ENABLE(htim);
}
}
else
{
__HAL_TIM_ENABLE(htim);
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM Input Capture measurement in DMA mode.
* @param htim TIM Input Capture handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CCX_CHANNEL(htim->Instance, Channel));
assert_param(IS_TIM_DMA_CC_INSTANCE(htim->Instance));
/* Disable the Input Capture channel */
TIM_CCxChannelCmd(htim->Instance, Channel, TIM_CCx_DISABLE);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Disable the TIM Capture/Compare 1 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
break;
}
case TIM_CHANNEL_2:
{
/* Disable the TIM Capture/Compare 2 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC2);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
break;
}
case TIM_CHANNEL_3:
{
/* Disable the TIM Capture/Compare 3 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC3);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC3]);
break;
}
case TIM_CHANNEL_4:
{
/* Disable the TIM Capture/Compare 4 DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC4);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC4]);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return status;
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group5 TIM One Pulse functions
* @brief TIM One Pulse functions
*
@verbatim
==============================================================================
##### TIM One Pulse functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Initialize and configure the TIM One Pulse.
(+) De-initialize the TIM One Pulse.
(+) Start the TIM One Pulse.
(+) Stop the TIM One Pulse.
(+) Start the TIM One Pulse and enable interrupt.
(+) Stop the TIM One Pulse and disable interrupt.
(+) Start the TIM One Pulse and enable DMA transfer.
(+) Stop the TIM One Pulse and disable DMA transfer.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM One Pulse Time Base according to the specified
* parameters in the TIM_HandleTypeDef and initializes the associated handle.
* @note Switching from Center Aligned counter mode to Edge counter mode (or reverse)
* requires a timer reset to avoid unexpected direction
* due to DIR bit readonly in center aligned mode.
* Ex: call @ref HAL_TIM_OnePulse_DeInit() before HAL_TIM_OnePulse_Init()
* @note When the timer instance is initialized in One Pulse mode, timer
* channels 1 and channel 2 are reserved and cannot be used for other
* purpose.
* @param htim TIM One Pulse handle
* @param OnePulseMode Select the One pulse mode.
* This parameter can be one of the following values:
* @arg TIM_OPMODE_SINGLE: Only one pulse will be generated.
* @arg TIM_OPMODE_REPETITIVE: Repetitive pulses will be generated.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OnePulse_Init(TIM_HandleTypeDef *htim, uint32_t OnePulseMode)
{
/* Check the TIM handle allocation */
if (htim == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
assert_param(IS_TIM_COUNTER_MODE(htim->Init.CounterMode));
assert_param(IS_TIM_CLOCKDIVISION_DIV(htim->Init.ClockDivision));
assert_param(IS_TIM_OPM_MODE(OnePulseMode));
assert_param(IS_TIM_PERIOD(htim, htim->Init.Period));
assert_param(IS_TIM_AUTORELOAD_PRELOAD(htim->Init.AutoReloadPreload));
if (htim->State == HAL_TIM_STATE_RESET)
{
/* Allocate lock resource and initialize it */
htim->Lock = HAL_UNLOCKED;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/* Reset interrupt callbacks to legacy weak callbacks */
TIM_ResetCallback(htim);
if (htim->OnePulse_MspInitCallback == NULL)
{
htim->OnePulse_MspInitCallback = HAL_TIM_OnePulse_MspInit;
}
/* Init the low level hardware : GPIO, CLOCK, NVIC */
htim->OnePulse_MspInitCallback(htim);
#else
/* Init the low level hardware : GPIO, CLOCK, NVIC and DMA */
HAL_TIM_OnePulse_MspInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Configure the Time base in the One Pulse Mode */
TIM_Base_SetConfig(htim->Instance, &htim->Init);
/* Reset the OPM Bit */
htim->Instance->CR1 &= ~TIM_CR1_OPM;
/* Configure the OPM Mode */
htim->Instance->CR1 |= OnePulseMode;
/* Initialize the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
/* Initialize the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Initialize the TIM state*/
htim->State = HAL_TIM_STATE_READY;
return HAL_OK;
}
/**
* @brief DeInitializes the TIM One Pulse
* @param htim TIM One Pulse handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OnePulse_DeInit(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
htim->State = HAL_TIM_STATE_BUSY;
/* Disable the TIM Peripheral Clock */
__HAL_TIM_DISABLE(htim);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
if (htim->OnePulse_MspDeInitCallback == NULL)
{
htim->OnePulse_MspDeInitCallback = HAL_TIM_OnePulse_MspDeInit;
}
/* DeInit the low level hardware */
htim->OnePulse_MspDeInitCallback(htim);
#else
/* DeInit the low level hardware: GPIO, CLOCK, NVIC */
HAL_TIM_OnePulse_MspDeInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_RESET;
/* Set the TIM channel state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_RESET);
/* Change TIM state */
htim->State = HAL_TIM_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Initializes the TIM One Pulse MSP.
* @param htim TIM One Pulse handle
* @retval None
*/
__weak void HAL_TIM_OnePulse_MspInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_OnePulse_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes TIM One Pulse MSP.
* @param htim TIM One Pulse handle
* @retval None
*/
__weak void HAL_TIM_OnePulse_MspDeInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_OnePulse_MspDeInit could be implemented in the user file
*/
}
/**
* @brief Starts the TIM One Pulse signal generation.
* @note Though OutputChannel parameter is deprecated and ignored by the function
* it has been kept to avoid HAL_TIM API compatibility break.
* @note The pulse output channel is determined when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel See note above
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OnePulse_Start(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Prevent unused argument(s) compilation warning */
UNUSED(OutputChannel);
/* Check the TIM channels state */
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the Capture compare and the Input Capture channels
(in the OPM Mode the two possible channels that can be used are TIM_CHANNEL_1 and TIM_CHANNEL_2)
if TIM_CHANNEL_1 is used as output, the TIM_CHANNEL_2 will be used as input and
if TIM_CHANNEL_1 is used as input, the TIM_CHANNEL_2 will be used as output
whatever the combination, the TIM_CHANNEL_1 and TIM_CHANNEL_2 should be enabled together
No need to enable the counter, it's enabled automatically by hardware
(the counter starts in response to a stimulus and generate a pulse */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM One Pulse signal generation.
* @note Though OutputChannel parameter is deprecated and ignored by the function
* it has been kept to avoid HAL_TIM API compatibility break.
* @note The pulse output channel is determined when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel See note above
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OnePulse_Stop(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(OutputChannel);
/* Disable the Capture compare and the Input Capture channels
(in the OPM Mode the two possible channels that can be used are TIM_CHANNEL_1 and TIM_CHANNEL_2)
if TIM_CHANNEL_1 is used as output, the TIM_CHANNEL_2 will be used as input and
if TIM_CHANNEL_1 is used as input, the TIM_CHANNEL_2 will be used as output
whatever the combination, the TIM_CHANNEL_1 and TIM_CHANNEL_2 should be disabled together */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM One Pulse signal generation in interrupt mode.
* @note Though OutputChannel parameter is deprecated and ignored by the function
* it has been kept to avoid HAL_TIM API compatibility break.
* @note The pulse output channel is determined when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel See note above
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OnePulse_Start_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Prevent unused argument(s) compilation warning */
UNUSED(OutputChannel);
/* Check the TIM channels state */
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
/* Enable the Capture compare and the Input Capture channels
(in the OPM Mode the two possible channels that can be used are TIM_CHANNEL_1 and TIM_CHANNEL_2)
if TIM_CHANNEL_1 is used as output, the TIM_CHANNEL_2 will be used as input and
if TIM_CHANNEL_1 is used as input, the TIM_CHANNEL_2 will be used as output
whatever the combination, the TIM_CHANNEL_1 and TIM_CHANNEL_2 should be enabled together
No need to enable the counter, it's enabled automatically by hardware
(the counter starts in response to a stimulus and generate a pulse */
/* Enable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
/* Enable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Enable the main output */
__HAL_TIM_MOE_ENABLE(htim);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM One Pulse signal generation in interrupt mode.
* @note Though OutputChannel parameter is deprecated and ignored by the function
* it has been kept to avoid HAL_TIM API compatibility break.
* @note The pulse output channel is determined when calling
* @ref HAL_TIM_OnePulse_ConfigChannel().
* @param htim TIM One Pulse handle
* @param OutputChannel See note above
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OnePulse_Stop_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(OutputChannel);
/* Disable the TIM Capture/Compare 1 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
/* Disable the TIM Capture/Compare 2 interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
/* Disable the Capture compare and the Input Capture channels
(in the OPM Mode the two possible channels that can be used are TIM_CHANNEL_1 and TIM_CHANNEL_2)
if TIM_CHANNEL_1 is used as output, the TIM_CHANNEL_2 will be used as input and
if TIM_CHANNEL_1 is used as input, the TIM_CHANNEL_2 will be used as output
whatever the combination, the TIM_CHANNEL_1 and TIM_CHANNEL_2 should be disabled together */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
if (IS_TIM_BREAK_INSTANCE(htim->Instance) != RESET)
{
/* Disable the Main Output */
__HAL_TIM_MOE_DISABLE(htim);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Return function status */
return HAL_OK;
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group6 TIM Encoder functions
* @brief TIM Encoder functions
*
@verbatim
==============================================================================
##### TIM Encoder functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Initialize and configure the TIM Encoder.
(+) De-initialize the TIM Encoder.
(+) Start the TIM Encoder.
(+) Stop the TIM Encoder.
(+) Start the TIM Encoder and enable interrupt.
(+) Stop the TIM Encoder and disable interrupt.
(+) Start the TIM Encoder and enable DMA transfer.
(+) Stop the TIM Encoder and disable DMA transfer.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM Encoder Interface and initialize the associated handle.
* @note Switching from Center Aligned counter mode to Edge counter mode (or reverse)
* requires a timer reset to avoid unexpected direction
* due to DIR bit readonly in center aligned mode.
* Ex: call @ref HAL_TIM_Encoder_DeInit() before HAL_TIM_Encoder_Init()
* @note Encoder mode and External clock mode 2 are not compatible and must not be selected together
* Ex: A call for @ref HAL_TIM_Encoder_Init will erase the settings of @ref HAL_TIM_ConfigClockSource
* using TIM_CLOCKSOURCE_ETRMODE2 and vice versa
* @note When the timer instance is initialized in Encoder mode, timer
* channels 1 and channel 2 are reserved and cannot be used for other
* purpose.
* @param htim TIM Encoder Interface handle
* @param sConfig TIM Encoder Interface configuration structure
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_Init(TIM_HandleTypeDef *htim, const TIM_Encoder_InitTypeDef *sConfig)
{
uint32_t tmpsmcr;
uint32_t tmpccmr1;
uint32_t tmpccer;
/* Check the TIM handle allocation */
if (htim == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
assert_param(IS_TIM_COUNTER_MODE(htim->Init.CounterMode));
assert_param(IS_TIM_CLOCKDIVISION_DIV(htim->Init.ClockDivision));
assert_param(IS_TIM_AUTORELOAD_PRELOAD(htim->Init.AutoReloadPreload));
assert_param(IS_TIM_ENCODER_MODE(sConfig->EncoderMode));
assert_param(IS_TIM_IC_SELECTION(sConfig->IC1Selection));
assert_param(IS_TIM_IC_SELECTION(sConfig->IC2Selection));
assert_param(IS_TIM_ENCODERINPUT_POLARITY(sConfig->IC1Polarity));
assert_param(IS_TIM_ENCODERINPUT_POLARITY(sConfig->IC2Polarity));
assert_param(IS_TIM_IC_PRESCALER(sConfig->IC1Prescaler));
assert_param(IS_TIM_IC_PRESCALER(sConfig->IC2Prescaler));
assert_param(IS_TIM_IC_FILTER(sConfig->IC1Filter));
assert_param(IS_TIM_IC_FILTER(sConfig->IC2Filter));
assert_param(IS_TIM_PERIOD(htim, htim->Init.Period));
if (htim->State == HAL_TIM_STATE_RESET)
{
/* Allocate lock resource and initialize it */
htim->Lock = HAL_UNLOCKED;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/* Reset interrupt callbacks to legacy weak callbacks */
TIM_ResetCallback(htim);
if (htim->Encoder_MspInitCallback == NULL)
{
htim->Encoder_MspInitCallback = HAL_TIM_Encoder_MspInit;
}
/* Init the low level hardware : GPIO, CLOCK, NVIC */
htim->Encoder_MspInitCallback(htim);
#else
/* Init the low level hardware : GPIO, CLOCK, NVIC and DMA */
HAL_TIM_Encoder_MspInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Set the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Reset the SMS and ECE bits */
htim->Instance->SMCR &= ~(TIM_SMCR_SMS | TIM_SMCR_ECE);
/* Configure the Time base in the Encoder Mode */
TIM_Base_SetConfig(htim->Instance, &htim->Init);
/* Get the TIMx SMCR register value */
tmpsmcr = htim->Instance->SMCR;
/* Get the TIMx CCMR1 register value */
tmpccmr1 = htim->Instance->CCMR1;
/* Get the TIMx CCER register value */
tmpccer = htim->Instance->CCER;
/* Set the encoder Mode */
tmpsmcr |= sConfig->EncoderMode;
/* Select the Capture Compare 1 and the Capture Compare 2 as input */
tmpccmr1 &= ~(TIM_CCMR1_CC1S | TIM_CCMR1_CC2S);
tmpccmr1 |= (sConfig->IC1Selection | (sConfig->IC2Selection << 8U));
/* Set the Capture Compare 1 and the Capture Compare 2 prescalers and filters */
tmpccmr1 &= ~(TIM_CCMR1_IC1PSC | TIM_CCMR1_IC2PSC);
tmpccmr1 &= ~(TIM_CCMR1_IC1F | TIM_CCMR1_IC2F);
tmpccmr1 |= sConfig->IC1Prescaler | (sConfig->IC2Prescaler << 8U);
tmpccmr1 |= (sConfig->IC1Filter << 4U) | (sConfig->IC2Filter << 12U);
/* Set the TI1 and the TI2 Polarities */
tmpccer &= ~(TIM_CCER_CC1P | TIM_CCER_CC2P);
tmpccer &= ~(TIM_CCER_CC1NP | TIM_CCER_CC2NP);
tmpccer |= sConfig->IC1Polarity | (sConfig->IC2Polarity << 4U);
/* Write to TIMx SMCR */
htim->Instance->SMCR = tmpsmcr;
/* Write to TIMx CCMR1 */
htim->Instance->CCMR1 = tmpccmr1;
/* Write to TIMx CCER */
htim->Instance->CCER = tmpccer;
/* Initialize the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
/* Initialize the TIM state*/
htim->State = HAL_TIM_STATE_READY;
return HAL_OK;
}
/**
* @brief DeInitializes the TIM Encoder interface
* @param htim TIM Encoder Interface handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_DeInit(TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
htim->State = HAL_TIM_STATE_BUSY;
/* Disable the TIM Peripheral Clock */
__HAL_TIM_DISABLE(htim);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
if (htim->Encoder_MspDeInitCallback == NULL)
{
htim->Encoder_MspDeInitCallback = HAL_TIM_Encoder_MspDeInit;
}
/* DeInit the low level hardware */
htim->Encoder_MspDeInitCallback(htim);
#else
/* DeInit the low level hardware: GPIO, CLOCK, NVIC */
HAL_TIM_Encoder_MspDeInit(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_RESET;
/* Set the TIM channels state */
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_RESET);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_RESET);
/* Change TIM state */
htim->State = HAL_TIM_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Initializes the TIM Encoder Interface MSP.
* @param htim TIM Encoder Interface handle
* @retval None
*/
__weak void HAL_TIM_Encoder_MspInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_Encoder_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes TIM Encoder Interface MSP.
* @param htim TIM Encoder Interface handle
* @retval None
*/
__weak void HAL_TIM_Encoder_MspDeInit(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_Encoder_MspDeInit could be implemented in the user file
*/
}
/**
* @brief Starts the TIM Encoder Interface.
* @param htim TIM Encoder Interface handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_ALL: TIM Channel 1 and TIM Channel 2 are selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_Start(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
/* Set the TIM channel(s) state */
if (Channel == TIM_CHANNEL_1)
{
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else if (Channel == TIM_CHANNEL_2)
{
if ((channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
/* Enable the encoder interface channels */
switch (Channel)
{
case TIM_CHANNEL_1:
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
break;
}
case TIM_CHANNEL_2:
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
break;
}
default :
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
break;
}
}
/* Enable the Peripheral */
__HAL_TIM_ENABLE(htim);
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Encoder Interface.
* @param htim TIM Encoder Interface handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_ALL: TIM Channel 1 and TIM Channel 2 are selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_Stop(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
/* Disable the Input Capture channels 1 and 2
(in the EncoderInterface the two possible channels that can be used are TIM_CHANNEL_1 and TIM_CHANNEL_2) */
switch (Channel)
{
case TIM_CHANNEL_1:
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
break;
}
case TIM_CHANNEL_2:
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
break;
}
default :
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
break;
}
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel(s) state */
if ((Channel == TIM_CHANNEL_1) || (Channel == TIM_CHANNEL_2))
{
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Encoder Interface in interrupt mode.
* @param htim TIM Encoder Interface handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_ALL: TIM Channel 1 and TIM Channel 2 are selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
/* Set the TIM channel(s) state */
if (Channel == TIM_CHANNEL_1)
{
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else if (Channel == TIM_CHANNEL_2)
{
if ((channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
if ((channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (channel_2_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_1_state != HAL_TIM_CHANNEL_STATE_READY)
|| (complementary_channel_2_state != HAL_TIM_CHANNEL_STATE_READY))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
/* Enable the encoder interface channels */
/* Enable the capture compare Interrupts 1 and/or 2 */
switch (Channel)
{
case TIM_CHANNEL_1:
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
break;
}
case TIM_CHANNEL_2:
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
break;
}
default :
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC1);
__HAL_TIM_ENABLE_IT(htim, TIM_IT_CC2);
break;
}
}
/* Enable the Peripheral */
__HAL_TIM_ENABLE(htim);
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Encoder Interface in interrupt mode.
* @param htim TIM Encoder Interface handle
* @param Channel TIM Channels to be disabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_ALL: TIM Channel 1 and TIM Channel 2 are selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
/* Disable the Input Capture channels 1 and 2
(in the EncoderInterface the two possible channels that can be used are TIM_CHANNEL_1 and TIM_CHANNEL_2) */
if (Channel == TIM_CHANNEL_1)
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
/* Disable the capture compare Interrupts 1 */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
}
else if (Channel == TIM_CHANNEL_2)
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
/* Disable the capture compare Interrupts 2 */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
}
else
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
/* Disable the capture compare Interrupts 1 and 2 */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC1);
__HAL_TIM_DISABLE_IT(htim, TIM_IT_CC2);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel(s) state */
if ((Channel == TIM_CHANNEL_1) || (Channel == TIM_CHANNEL_2))
{
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Starts the TIM Encoder Interface in DMA mode.
* @param htim TIM Encoder Interface handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_ALL: TIM Channel 1 and TIM Channel 2 are selected
* @param pData1 The destination Buffer address for IC1.
* @param pData2 The destination Buffer address for IC2.
* @param Length The length of data to be transferred from TIM peripheral to memory.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, uint32_t *pData1,
uint32_t *pData2, uint16_t Length)
{
HAL_TIM_ChannelStateTypeDef channel_1_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef channel_2_state = TIM_CHANNEL_STATE_GET(htim, TIM_CHANNEL_2);
HAL_TIM_ChannelStateTypeDef complementary_channel_1_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_1);
HAL_TIM_ChannelStateTypeDef complementary_channel_2_state = TIM_CHANNEL_N_STATE_GET(htim, TIM_CHANNEL_2);
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
/* Set the TIM channel(s) state */
if (Channel == TIM_CHANNEL_1)
{
if ((channel_1_state == HAL_TIM_CHANNEL_STATE_BUSY)
|| (complementary_channel_1_state == HAL_TIM_CHANNEL_STATE_BUSY))
{
return HAL_BUSY;
}
else if ((channel_1_state == HAL_TIM_CHANNEL_STATE_READY)
&& (complementary_channel_1_state == HAL_TIM_CHANNEL_STATE_READY))
{
if ((pData1 == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
}
else if (Channel == TIM_CHANNEL_2)
{
if ((channel_2_state == HAL_TIM_CHANNEL_STATE_BUSY)
|| (complementary_channel_2_state == HAL_TIM_CHANNEL_STATE_BUSY))
{
return HAL_BUSY;
}
else if ((channel_2_state == HAL_TIM_CHANNEL_STATE_READY)
&& (complementary_channel_2_state == HAL_TIM_CHANNEL_STATE_READY))
{
if ((pData2 == NULL) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
}
else
{
if ((channel_1_state == HAL_TIM_CHANNEL_STATE_BUSY)
|| (channel_2_state == HAL_TIM_CHANNEL_STATE_BUSY)
|| (complementary_channel_1_state == HAL_TIM_CHANNEL_STATE_BUSY)
|| (complementary_channel_2_state == HAL_TIM_CHANNEL_STATE_BUSY))
{
return HAL_BUSY;
}
else if ((channel_1_state == HAL_TIM_CHANNEL_STATE_READY)
&& (channel_2_state == HAL_TIM_CHANNEL_STATE_READY)
&& (complementary_channel_1_state == HAL_TIM_CHANNEL_STATE_READY)
&& (complementary_channel_2_state == HAL_TIM_CHANNEL_STATE_READY))
{
if ((((pData1 == NULL) || (pData2 == NULL))) || (Length == 0U))
{
return HAL_ERROR;
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_BUSY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_BUSY);
}
}
else
{
return HAL_ERROR;
}
}
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)&htim->Instance->CCR1, (uint32_t)pData1,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Input Capture DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
/* Enable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
/* Enable the Peripheral */
__HAL_TIM_ENABLE(htim);
break;
}
case TIM_CHANNEL_2:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAError;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)&htim->Instance->CCR2, (uint32_t)pData2,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Input Capture DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC2);
/* Enable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
/* Enable the Peripheral */
__HAL_TIM_ENABLE(htim);
break;
}
default:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)&htim->Instance->CCR1, (uint32_t)pData1,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)&htim->Instance->CCR2, (uint32_t)pData2,
Length) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
/* Enable the TIM Input Capture DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC1);
/* Enable the TIM Input Capture DMA request */
__HAL_TIM_ENABLE_DMA(htim, TIM_DMA_CC2);
/* Enable the Capture compare channel */
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_ENABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_ENABLE);
/* Enable the Peripheral */
__HAL_TIM_ENABLE(htim);
break;
}
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Stops the TIM Encoder Interface in DMA mode.
* @param htim TIM Encoder Interface handle
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_ALL: TIM Channel 1 and TIM Channel 2 are selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_Encoder_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel)
{
/* Check the parameters */
assert_param(IS_TIM_ENCODER_INTERFACE_INSTANCE(htim->Instance));
/* Disable the Input Capture channels 1 and 2
(in the EncoderInterface the two possible channels that can be used are TIM_CHANNEL_1 and TIM_CHANNEL_2) */
if (Channel == TIM_CHANNEL_1)
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
/* Disable the capture compare DMA Request 1 */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
}
else if (Channel == TIM_CHANNEL_2)
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
/* Disable the capture compare DMA Request 2 */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC2);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
}
else
{
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_1, TIM_CCx_DISABLE);
TIM_CCxChannelCmd(htim->Instance, TIM_CHANNEL_2, TIM_CCx_DISABLE);
/* Disable the capture compare DMA Request 1 and 2 */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC1);
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_CC2);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
}
/* Disable the Peripheral */
__HAL_TIM_DISABLE(htim);
/* Set the TIM channel(s) state */
if ((Channel == TIM_CHANNEL_1) || (Channel == TIM_CHANNEL_2))
{
TIM_CHANNEL_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, Channel, HAL_TIM_CHANNEL_STATE_READY);
}
else
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
/* Return function status */
return HAL_OK;
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group7 TIM IRQ handler management
* @brief TIM IRQ handler management
*
@verbatim
==============================================================================
##### IRQ handler management #####
==============================================================================
[..]
This section provides Timer IRQ handler function.
@endverbatim
* @{
*/
/**
* @brief This function handles TIM interrupts requests.
* @param htim TIM handle
* @retval None
*/
void HAL_TIM_IRQHandler(TIM_HandleTypeDef *htim)
{
uint32_t itsource = htim->Instance->DIER;
uint32_t itflag = htim->Instance->SR;
/* Capture compare 1 event */
if ((itflag & (TIM_FLAG_CC1)) == (TIM_FLAG_CC1))
{
if ((itsource & (TIM_IT_CC1)) == (TIM_IT_CC1))
{
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_CC1);
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
/* Input capture event */
if ((htim->Instance->CCMR1 & TIM_CCMR1_CC1S) != 0x00U)
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->IC_CaptureCallback(htim);
#else
HAL_TIM_IC_CaptureCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Output compare event */
else
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->OC_DelayElapsedCallback(htim);
htim->PWM_PulseFinishedCallback(htim);
#else
HAL_TIM_OC_DelayElapsedCallback(htim);
HAL_TIM_PWM_PulseFinishedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
}
}
/* Capture compare 2 event */
if ((itflag & (TIM_FLAG_CC2)) == (TIM_FLAG_CC2))
{
if ((itsource & (TIM_IT_CC2)) == (TIM_IT_CC2))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_CC2);
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
/* Input capture event */
if ((htim->Instance->CCMR1 & TIM_CCMR1_CC2S) != 0x00U)
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->IC_CaptureCallback(htim);
#else
HAL_TIM_IC_CaptureCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Output compare event */
else
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->OC_DelayElapsedCallback(htim);
htim->PWM_PulseFinishedCallback(htim);
#else
HAL_TIM_OC_DelayElapsedCallback(htim);
HAL_TIM_PWM_PulseFinishedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
}
/* Capture compare 3 event */
if ((itflag & (TIM_FLAG_CC3)) == (TIM_FLAG_CC3))
{
if ((itsource & (TIM_IT_CC3)) == (TIM_IT_CC3))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_CC3);
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
/* Input capture event */
if ((htim->Instance->CCMR2 & TIM_CCMR2_CC3S) != 0x00U)
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->IC_CaptureCallback(htim);
#else
HAL_TIM_IC_CaptureCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Output compare event */
else
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->OC_DelayElapsedCallback(htim);
htim->PWM_PulseFinishedCallback(htim);
#else
HAL_TIM_OC_DelayElapsedCallback(htim);
HAL_TIM_PWM_PulseFinishedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
}
/* Capture compare 4 event */
if ((itflag & (TIM_FLAG_CC4)) == (TIM_FLAG_CC4))
{
if ((itsource & (TIM_IT_CC4)) == (TIM_IT_CC4))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_CC4);
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
/* Input capture event */
if ((htim->Instance->CCMR2 & TIM_CCMR2_CC4S) != 0x00U)
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->IC_CaptureCallback(htim);
#else
HAL_TIM_IC_CaptureCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/* Output compare event */
else
{
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->OC_DelayElapsedCallback(htim);
htim->PWM_PulseFinishedCallback(htim);
#else
HAL_TIM_OC_DelayElapsedCallback(htim);
HAL_TIM_PWM_PulseFinishedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
}
/* TIM Update event */
if ((itflag & (TIM_FLAG_UPDATE)) == (TIM_FLAG_UPDATE))
{
if ((itsource & (TIM_IT_UPDATE)) == (TIM_IT_UPDATE))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_UPDATE);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->PeriodElapsedCallback(htim);
#else
HAL_TIM_PeriodElapsedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM Break input event */
if (((itflag & (TIM_FLAG_BREAK)) == (TIM_FLAG_BREAK)) || \
((itflag & (TIM_FLAG_SYSTEM_BREAK)) == (TIM_FLAG_SYSTEM_BREAK)))
{
if ((itsource & (TIM_IT_BREAK)) == (TIM_IT_BREAK))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_BREAK | TIM_FLAG_SYSTEM_BREAK);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->BreakCallback(htim);
#else
HAL_TIMEx_BreakCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM Break2 input event */
if ((itflag & (TIM_FLAG_BREAK2)) == (TIM_FLAG_BREAK2))
{
if ((itsource & (TIM_IT_BREAK)) == (TIM_IT_BREAK))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_BREAK2);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->Break2Callback(htim);
#else
HAL_TIMEx_Break2Callback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM Trigger detection event */
if ((itflag & (TIM_FLAG_TRIGGER)) == (TIM_FLAG_TRIGGER))
{
if ((itsource & (TIM_IT_TRIGGER)) == (TIM_IT_TRIGGER))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_TRIGGER);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->TriggerCallback(htim);
#else
HAL_TIM_TriggerCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM commutation event */
if ((itflag & (TIM_FLAG_COM)) == (TIM_FLAG_COM))
{
if ((itsource & (TIM_IT_COM)) == (TIM_IT_COM))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_COM);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->CommutationCallback(htim);
#else
HAL_TIMEx_CommutCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM Encoder index event */
if ((itflag & (TIM_FLAG_IDX)) == (TIM_FLAG_IDX))
{
if ((itsource & (TIM_IT_IDX)) == (TIM_IT_IDX))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_IDX);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->EncoderIndexCallback(htim);
#else
HAL_TIMEx_EncoderIndexCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM Direction change event */
if ((itflag & (TIM_FLAG_DIR)) == (TIM_FLAG_DIR))
{
if ((itsource & (TIM_IT_DIR)) == (TIM_IT_DIR))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_DIR);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->DirectionChangeCallback(htim);
#else
HAL_TIMEx_DirectionChangeCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM Index error event */
if ((itflag & (TIM_FLAG_IERR)) == (TIM_FLAG_IERR))
{
if ((itsource & (TIM_IT_IERR)) == (TIM_IT_IERR))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_IERR);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->IndexErrorCallback(htim);
#else
HAL_TIMEx_IndexErrorCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
/* TIM Transition error event */
if ((itflag & (TIM_FLAG_TERR)) == (TIM_FLAG_TERR))
{
if ((itsource & (TIM_IT_TERR)) == (TIM_IT_TERR))
{
__HAL_TIM_CLEAR_FLAG(htim, TIM_FLAG_TERR);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->TransitionErrorCallback(htim);
#else
HAL_TIMEx_TransitionErrorCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
}
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group8 TIM Peripheral Control functions
* @brief TIM Peripheral Control functions
*
@verbatim
==============================================================================
##### Peripheral Control functions #####
==============================================================================
[..]
This section provides functions allowing to:
(+) Configure The Input Output channels for OC, PWM, IC or One Pulse mode.
(+) Configure External Clock source.
(+) Configure Complementary channels, break features and dead time.
(+) Configure Master and the Slave synchronization.
(+) Configure the DMA Burst Mode.
@endverbatim
* @{
*/
/**
* @brief Initializes the TIM Output Compare Channels according to the specified
* parameters in the TIM_OC_InitTypeDef.
* @param htim TIM Output Compare handle
* @param sConfig TIM Output Compare configuration structure
* @param Channel TIM Channels to configure
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OC_ConfigChannel(TIM_HandleTypeDef *htim,
const TIM_OC_InitTypeDef *sConfig,
uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CHANNELS(Channel));
assert_param(IS_TIM_OC_CHANNEL_MODE(sConfig->OCMode, Channel));
assert_param(IS_TIM_OC_POLARITY(sConfig->OCPolarity));
/* Process Locked */
__HAL_LOCK(htim);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Check the parameters */
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
/* Configure the TIM Channel 1 in Output Compare */
TIM_OC1_SetConfig(htim->Instance, sConfig);
break;
}
case TIM_CHANNEL_2:
{
/* Check the parameters */
assert_param(IS_TIM_CC2_INSTANCE(htim->Instance));
/* Configure the TIM Channel 2 in Output Compare */
TIM_OC2_SetConfig(htim->Instance, sConfig);
break;
}
case TIM_CHANNEL_3:
{
/* Check the parameters */
assert_param(IS_TIM_CC3_INSTANCE(htim->Instance));
/* Configure the TIM Channel 3 in Output Compare */
TIM_OC3_SetConfig(htim->Instance, sConfig);
break;
}
case TIM_CHANNEL_4:
{
/* Check the parameters */
assert_param(IS_TIM_CC4_INSTANCE(htim->Instance));
/* Configure the TIM Channel 4 in Output Compare */
TIM_OC4_SetConfig(htim->Instance, sConfig);
break;
}
case TIM_CHANNEL_5:
{
/* Check the parameters */
assert_param(IS_TIM_CC5_INSTANCE(htim->Instance));
/* Configure the TIM Channel 5 in Output Compare */
TIM_OC5_SetConfig(htim->Instance, sConfig);
break;
}
case TIM_CHANNEL_6:
{
/* Check the parameters */
assert_param(IS_TIM_CC6_INSTANCE(htim->Instance));
/* Configure the TIM Channel 6 in Output Compare */
TIM_OC6_SetConfig(htim->Instance, sConfig);
break;
}
default:
status = HAL_ERROR;
break;
}
__HAL_UNLOCK(htim);
return status;
}
/**
* @brief Initializes the TIM Input Capture Channels according to the specified
* parameters in the TIM_IC_InitTypeDef.
* @param htim TIM IC handle
* @param sConfig TIM Input Capture configuration structure
* @param Channel TIM Channel to configure
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_IC_ConfigChannel(TIM_HandleTypeDef *htim, const TIM_IC_InitTypeDef *sConfig, uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
assert_param(IS_TIM_IC_POLARITY(sConfig->ICPolarity));
assert_param(IS_TIM_IC_SELECTION(sConfig->ICSelection));
assert_param(IS_TIM_IC_PRESCALER(sConfig->ICPrescaler));
assert_param(IS_TIM_IC_FILTER(sConfig->ICFilter));
/* Process Locked */
__HAL_LOCK(htim);
if (Channel == TIM_CHANNEL_1)
{
/* TI1 Configuration */
TIM_TI1_SetConfig(htim->Instance,
sConfig->ICPolarity,
sConfig->ICSelection,
sConfig->ICFilter);
/* Reset the IC1PSC Bits */
htim->Instance->CCMR1 &= ~TIM_CCMR1_IC1PSC;
/* Set the IC1PSC value */
htim->Instance->CCMR1 |= sConfig->ICPrescaler;
}
else if (Channel == TIM_CHANNEL_2)
{
/* TI2 Configuration */
assert_param(IS_TIM_CC2_INSTANCE(htim->Instance));
TIM_TI2_SetConfig(htim->Instance,
sConfig->ICPolarity,
sConfig->ICSelection,
sConfig->ICFilter);
/* Reset the IC2PSC Bits */
htim->Instance->CCMR1 &= ~TIM_CCMR1_IC2PSC;
/* Set the IC2PSC value */
htim->Instance->CCMR1 |= (sConfig->ICPrescaler << 8U);
}
else if (Channel == TIM_CHANNEL_3)
{
/* TI3 Configuration */
assert_param(IS_TIM_CC3_INSTANCE(htim->Instance));
TIM_TI3_SetConfig(htim->Instance,
sConfig->ICPolarity,
sConfig->ICSelection,
sConfig->ICFilter);
/* Reset the IC3PSC Bits */
htim->Instance->CCMR2 &= ~TIM_CCMR2_IC3PSC;
/* Set the IC3PSC value */
htim->Instance->CCMR2 |= sConfig->ICPrescaler;
}
else if (Channel == TIM_CHANNEL_4)
{
/* TI4 Configuration */
assert_param(IS_TIM_CC4_INSTANCE(htim->Instance));
TIM_TI4_SetConfig(htim->Instance,
sConfig->ICPolarity,
sConfig->ICSelection,
sConfig->ICFilter);
/* Reset the IC4PSC Bits */
htim->Instance->CCMR2 &= ~TIM_CCMR2_IC4PSC;
/* Set the IC4PSC value */
htim->Instance->CCMR2 |= (sConfig->ICPrescaler << 8U);
}
else
{
status = HAL_ERROR;
}
__HAL_UNLOCK(htim);
return status;
}
/**
* @brief Initializes the TIM PWM channels according to the specified
* parameters in the TIM_OC_InitTypeDef.
* @param htim TIM PWM handle
* @param sConfig TIM PWM configuration structure
* @param Channel TIM Channels to be configured
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_PWM_ConfigChannel(TIM_HandleTypeDef *htim,
const TIM_OC_InitTypeDef *sConfig,
uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_CHANNELS(Channel));
assert_param(IS_TIM_PWM_MODE(sConfig->OCMode));
assert_param(IS_TIM_OC_POLARITY(sConfig->OCPolarity));
assert_param(IS_TIM_FAST_STATE(sConfig->OCFastMode));
/* Process Locked */
__HAL_LOCK(htim);
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Check the parameters */
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
/* Configure the Channel 1 in PWM mode */
TIM_OC1_SetConfig(htim->Instance, sConfig);
/* Set the Preload enable bit for channel1 */
htim->Instance->CCMR1 |= TIM_CCMR1_OC1PE;
/* Configure the Output Fast mode */
htim->Instance->CCMR1 &= ~TIM_CCMR1_OC1FE;
htim->Instance->CCMR1 |= sConfig->OCFastMode;
break;
}
case TIM_CHANNEL_2:
{
/* Check the parameters */
assert_param(IS_TIM_CC2_INSTANCE(htim->Instance));
/* Configure the Channel 2 in PWM mode */
TIM_OC2_SetConfig(htim->Instance, sConfig);
/* Set the Preload enable bit for channel2 */
htim->Instance->CCMR1 |= TIM_CCMR1_OC2PE;
/* Configure the Output Fast mode */
htim->Instance->CCMR1 &= ~TIM_CCMR1_OC2FE;
htim->Instance->CCMR1 |= sConfig->OCFastMode << 8U;
break;
}
case TIM_CHANNEL_3:
{
/* Check the parameters */
assert_param(IS_TIM_CC3_INSTANCE(htim->Instance));
/* Configure the Channel 3 in PWM mode */
TIM_OC3_SetConfig(htim->Instance, sConfig);
/* Set the Preload enable bit for channel3 */
htim->Instance->CCMR2 |= TIM_CCMR2_OC3PE;
/* Configure the Output Fast mode */
htim->Instance->CCMR2 &= ~TIM_CCMR2_OC3FE;
htim->Instance->CCMR2 |= sConfig->OCFastMode;
break;
}
case TIM_CHANNEL_4:
{
/* Check the parameters */
assert_param(IS_TIM_CC4_INSTANCE(htim->Instance));
/* Configure the Channel 4 in PWM mode */
TIM_OC4_SetConfig(htim->Instance, sConfig);
/* Set the Preload enable bit for channel4 */
htim->Instance->CCMR2 |= TIM_CCMR2_OC4PE;
/* Configure the Output Fast mode */
htim->Instance->CCMR2 &= ~TIM_CCMR2_OC4FE;
htim->Instance->CCMR2 |= sConfig->OCFastMode << 8U;
break;
}
case TIM_CHANNEL_5:
{
/* Check the parameters */
assert_param(IS_TIM_CC5_INSTANCE(htim->Instance));
/* Configure the Channel 5 in PWM mode */
TIM_OC5_SetConfig(htim->Instance, sConfig);
/* Set the Preload enable bit for channel5*/
htim->Instance->CCMR3 |= TIM_CCMR3_OC5PE;
/* Configure the Output Fast mode */
htim->Instance->CCMR3 &= ~TIM_CCMR3_OC5FE;
htim->Instance->CCMR3 |= sConfig->OCFastMode;
break;
}
case TIM_CHANNEL_6:
{
/* Check the parameters */
assert_param(IS_TIM_CC6_INSTANCE(htim->Instance));
/* Configure the Channel 6 in PWM mode */
TIM_OC6_SetConfig(htim->Instance, sConfig);
/* Set the Preload enable bit for channel6 */
htim->Instance->CCMR3 |= TIM_CCMR3_OC6PE;
/* Configure the Output Fast mode */
htim->Instance->CCMR3 &= ~TIM_CCMR3_OC6FE;
htim->Instance->CCMR3 |= sConfig->OCFastMode << 8U;
break;
}
default:
status = HAL_ERROR;
break;
}
__HAL_UNLOCK(htim);
return status;
}
/**
* @brief Initializes the TIM One Pulse Channels according to the specified
* parameters in the TIM_OnePulse_InitTypeDef.
* @param htim TIM One Pulse handle
* @param sConfig TIM One Pulse configuration structure
* @param OutputChannel TIM output channel to configure
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @param InputChannel TIM input Channel to configure
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @note To output a waveform with a minimum delay user can enable the fast
* mode by calling the @ref __HAL_TIM_ENABLE_OCxFAST macro. Then CCx
* output is forced in response to the edge detection on TIx input,
* without taking in account the comparison.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_OnePulse_ConfigChannel(TIM_HandleTypeDef *htim, TIM_OnePulse_InitTypeDef *sConfig,
uint32_t OutputChannel, uint32_t InputChannel)
{
HAL_StatusTypeDef status = HAL_OK;
TIM_OC_InitTypeDef temp1;
/* Check the parameters */
assert_param(IS_TIM_OPM_CHANNELS(OutputChannel));
assert_param(IS_TIM_OPM_CHANNELS(InputChannel));
if (OutputChannel != InputChannel)
{
/* Process Locked */
__HAL_LOCK(htim);
htim->State = HAL_TIM_STATE_BUSY;
/* Extract the Output compare configuration from sConfig structure */
temp1.OCMode = sConfig->OCMode;
temp1.Pulse = sConfig->Pulse;
temp1.OCPolarity = sConfig->OCPolarity;
temp1.OCNPolarity = sConfig->OCNPolarity;
temp1.OCIdleState = sConfig->OCIdleState;
temp1.OCNIdleState = sConfig->OCNIdleState;
switch (OutputChannel)
{
case TIM_CHANNEL_1:
{
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
TIM_OC1_SetConfig(htim->Instance, &temp1);
break;
}
case TIM_CHANNEL_2:
{
assert_param(IS_TIM_CC2_INSTANCE(htim->Instance));
TIM_OC2_SetConfig(htim->Instance, &temp1);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
switch (InputChannel)
{
case TIM_CHANNEL_1:
{
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
TIM_TI1_SetConfig(htim->Instance, sConfig->ICPolarity,
sConfig->ICSelection, sConfig->ICFilter);
/* Reset the IC1PSC Bits */
htim->Instance->CCMR1 &= ~TIM_CCMR1_IC1PSC;
/* Select the Trigger source */
htim->Instance->SMCR &= ~TIM_SMCR_TS;
htim->Instance->SMCR |= TIM_TS_TI1FP1;
/* Select the Slave Mode */
htim->Instance->SMCR &= ~TIM_SMCR_SMS;
htim->Instance->SMCR |= TIM_SLAVEMODE_TRIGGER;
break;
}
case TIM_CHANNEL_2:
{
assert_param(IS_TIM_CC2_INSTANCE(htim->Instance));
TIM_TI2_SetConfig(htim->Instance, sConfig->ICPolarity,
sConfig->ICSelection, sConfig->ICFilter);
/* Reset the IC2PSC Bits */
htim->Instance->CCMR1 &= ~TIM_CCMR1_IC2PSC;
/* Select the Trigger source */
htim->Instance->SMCR &= ~TIM_SMCR_TS;
htim->Instance->SMCR |= TIM_TS_TI2FP2;
/* Select the Slave Mode */
htim->Instance->SMCR &= ~TIM_SMCR_SMS;
htim->Instance->SMCR |= TIM_SLAVEMODE_TRIGGER;
break;
}
default:
status = HAL_ERROR;
break;
}
}
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return status;
}
else
{
return HAL_ERROR;
}
}
/**
* @brief Configure the DMA Burst to transfer Data from the memory to the TIM peripheral
* @param htim TIM handle
* @param BurstBaseAddress TIM Base address from where the DMA will start the Data write
* This parameter can be one of the following values:
* @arg TIM_DMABASE_CR1
* @arg TIM_DMABASE_CR2
* @arg TIM_DMABASE_SMCR
* @arg TIM_DMABASE_DIER
* @arg TIM_DMABASE_SR
* @arg TIM_DMABASE_EGR
* @arg TIM_DMABASE_CCMR1
* @arg TIM_DMABASE_CCMR2
* @arg TIM_DMABASE_CCER
* @arg TIM_DMABASE_CNT
* @arg TIM_DMABASE_PSC
* @arg TIM_DMABASE_ARR
* @arg TIM_DMABASE_RCR
* @arg TIM_DMABASE_CCR1
* @arg TIM_DMABASE_CCR2
* @arg TIM_DMABASE_CCR3
* @arg TIM_DMABASE_CCR4
* @arg TIM_DMABASE_BDTR
* @arg TIM_DMABASE_CCMR3
* @arg TIM_DMABASE_CCR5
* @arg TIM_DMABASE_CCR6
* @arg TIM_DMABASE_DTR2
* @arg TIM_DMABASE_ECR
* @arg TIM_DMABASE_TISEL
* @arg TIM_DMABASE_AF1
* @arg TIM_DMABASE_AF2
* @arg TIM_DMABASE_OR
* @param BurstRequestSrc TIM DMA Request sources
* This parameter can be one of the following values:
* @arg TIM_DMA_UPDATE: TIM update Interrupt source
* @arg TIM_DMA_CC1: TIM Capture Compare 1 DMA source
* @arg TIM_DMA_CC2: TIM Capture Compare 2 DMA source
* @arg TIM_DMA_CC3: TIM Capture Compare 3 DMA source
* @arg TIM_DMA_CC4: TIM Capture Compare 4 DMA source
* @arg TIM_DMA_COM: TIM Commutation DMA source
* @arg TIM_DMA_TRIGGER: TIM Trigger DMA source
* @param BurstBuffer The Buffer address.
* @param BurstLength DMA Burst length. This parameter can be one value
* between: TIM_DMABURSTLENGTH_1TRANSFER and TIM_DMABURSTLENGTH_26TRANSFER.
* @note This function should be used only when BurstLength is equal to DMA data transfer length.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_DMABurst_WriteStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, const uint32_t *BurstBuffer,
uint32_t BurstLength)
{
HAL_StatusTypeDef status;
status = HAL_TIM_DMABurst_MultiWriteStart(htim, BurstBaseAddress, BurstRequestSrc, BurstBuffer, BurstLength,
((BurstLength) >> 8U) + 1U);
return status;
}
/**
* @brief Configure the DMA Burst to transfer multiple Data from the memory to the TIM peripheral
* @param htim TIM handle
* @param BurstBaseAddress TIM Base address from where the DMA will start the Data write
* This parameter can be one of the following values:
* @arg TIM_DMABASE_CR1
* @arg TIM_DMABASE_CR2
* @arg TIM_DMABASE_SMCR
* @arg TIM_DMABASE_DIER
* @arg TIM_DMABASE_SR
* @arg TIM_DMABASE_EGR
* @arg TIM_DMABASE_CCMR1
* @arg TIM_DMABASE_CCMR2
* @arg TIM_DMABASE_CCER
* @arg TIM_DMABASE_CNT
* @arg TIM_DMABASE_PSC
* @arg TIM_DMABASE_ARR
* @arg TIM_DMABASE_RCR
* @arg TIM_DMABASE_CCR1
* @arg TIM_DMABASE_CCR2
* @arg TIM_DMABASE_CCR3
* @arg TIM_DMABASE_CCR4
* @arg TIM_DMABASE_BDTR
* @arg TIM_DMABASE_CCMR3
* @arg TIM_DMABASE_CCR5
* @arg TIM_DMABASE_CCR6
* @arg TIM_DMABASE_DTR2
* @arg TIM_DMABASE_ECR
* @arg TIM_DMABASE_TISEL
* @arg TIM_DMABASE_AF1
* @arg TIM_DMABASE_AF2
* @arg TIM_DMABASE_OR
* @param BurstRequestSrc TIM DMA Request sources
* This parameter can be one of the following values:
* @arg TIM_DMA_UPDATE: TIM update Interrupt source
* @arg TIM_DMA_CC1: TIM Capture Compare 1 DMA source
* @arg TIM_DMA_CC2: TIM Capture Compare 2 DMA source
* @arg TIM_DMA_CC3: TIM Capture Compare 3 DMA source
* @arg TIM_DMA_CC4: TIM Capture Compare 4 DMA source
* @arg TIM_DMA_COM: TIM Commutation DMA source
* @arg TIM_DMA_TRIGGER: TIM Trigger DMA source
* @param BurstBuffer The Buffer address.
* @param BurstLength DMA Burst length. This parameter can be one value
* between: TIM_DMABURSTLENGTH_1TRANSFER and TIM_DMABURSTLENGTH_26TRANSFER.
* @param DataLength Data length. This parameter can be one value
* between 1 and 0xFFFF.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_DMABurst_MultiWriteStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, const uint32_t *BurstBuffer,
uint32_t BurstLength, uint32_t DataLength)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_DMABURST_INSTANCE(htim->Instance));
assert_param(IS_TIM_DMA_BASE(BurstBaseAddress));
assert_param(IS_TIM_DMA_SOURCE(BurstRequestSrc));
assert_param(IS_TIM_DMA_LENGTH(BurstLength));
assert_param(IS_TIM_DMA_DATA_LENGTH(DataLength));
if (htim->DMABurstState == HAL_DMA_BURST_STATE_BUSY)
{
return HAL_BUSY;
}
else if (htim->DMABurstState == HAL_DMA_BURST_STATE_READY)
{
if ((BurstBuffer == NULL) && (BurstLength > 0U))
{
return HAL_ERROR;
}
else
{
htim->DMABurstState = HAL_DMA_BURST_STATE_BUSY;
}
}
else
{
/* nothing to do */
}
switch (BurstRequestSrc)
{
case TIM_DMA_UPDATE:
{
/* Set the DMA Period elapsed callbacks */
htim->hdma[TIM_DMA_ID_UPDATE]->XferCpltCallback = TIM_DMAPeriodElapsedCplt;
htim->hdma[TIM_DMA_ID_UPDATE]->XferHalfCpltCallback = TIM_DMAPeriodElapsedHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_UPDATE]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_UPDATE], (uint32_t)BurstBuffer,
(uint32_t)&htim->Instance->DMAR, DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC1:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)BurstBuffer,
(uint32_t)&htim->Instance->DMAR, DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC2:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)BurstBuffer,
(uint32_t)&htim->Instance->DMAR, DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC3:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC3]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC3]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC3]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC3], (uint32_t)BurstBuffer,
(uint32_t)&htim->Instance->DMAR, DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC4:
{
/* Set the DMA compare callbacks */
htim->hdma[TIM_DMA_ID_CC4]->XferCpltCallback = TIM_DMADelayPulseCplt;
htim->hdma[TIM_DMA_ID_CC4]->XferHalfCpltCallback = TIM_DMADelayPulseHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC4]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC4], (uint32_t)BurstBuffer,
(uint32_t)&htim->Instance->DMAR, DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_COM:
{
/* Set the DMA commutation callbacks */
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferCpltCallback = TIMEx_DMACommutationCplt;
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferHalfCpltCallback = TIMEx_DMACommutationHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_COMMUTATION], (uint32_t)BurstBuffer,
(uint32_t)&htim->Instance->DMAR, DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_TRIGGER:
{
/* Set the DMA trigger callbacks */
htim->hdma[TIM_DMA_ID_TRIGGER]->XferCpltCallback = TIM_DMATriggerCplt;
htim->hdma[TIM_DMA_ID_TRIGGER]->XferHalfCpltCallback = TIM_DMATriggerHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_TRIGGER]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_TRIGGER], (uint32_t)BurstBuffer,
(uint32_t)&htim->Instance->DMAR, DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Configure the DMA Burst Mode */
htim->Instance->DCR = (BurstBaseAddress | BurstLength);
/* Enable the TIM DMA Request */
__HAL_TIM_ENABLE_DMA(htim, BurstRequestSrc);
}
/* Return function status */
return status;
}
/**
* @brief Stops the TIM DMA Burst mode
* @param htim TIM handle
* @param BurstRequestSrc TIM DMA Request sources to disable
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_DMABurst_WriteStop(TIM_HandleTypeDef *htim, uint32_t BurstRequestSrc)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_DMA_SOURCE(BurstRequestSrc));
/* Abort the DMA transfer (at least disable the DMA channel) */
switch (BurstRequestSrc)
{
case TIM_DMA_UPDATE:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_UPDATE]);
break;
}
case TIM_DMA_CC1:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
break;
}
case TIM_DMA_CC2:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
break;
}
case TIM_DMA_CC3:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC3]);
break;
}
case TIM_DMA_CC4:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC4]);
break;
}
case TIM_DMA_COM:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_COMMUTATION]);
break;
}
case TIM_DMA_TRIGGER:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_TRIGGER]);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the TIM Update DMA request */
__HAL_TIM_DISABLE_DMA(htim, BurstRequestSrc);
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
}
/* Return function status */
return status;
}
/**
* @brief Configure the DMA Burst to transfer Data from the TIM peripheral to the memory
* @param htim TIM handle
* @param BurstBaseAddress TIM Base address from where the DMA will start the Data read
* This parameter can be one of the following values:
* @arg TIM_DMABASE_CR1
* @arg TIM_DMABASE_CR2
* @arg TIM_DMABASE_SMCR
* @arg TIM_DMABASE_DIER
* @arg TIM_DMABASE_SR
* @arg TIM_DMABASE_EGR
* @arg TIM_DMABASE_CCMR1
* @arg TIM_DMABASE_CCMR2
* @arg TIM_DMABASE_CCER
* @arg TIM_DMABASE_CNT
* @arg TIM_DMABASE_PSC
* @arg TIM_DMABASE_ARR
* @arg TIM_DMABASE_RCR
* @arg TIM_DMABASE_CCR1
* @arg TIM_DMABASE_CCR2
* @arg TIM_DMABASE_CCR3
* @arg TIM_DMABASE_CCR4
* @arg TIM_DMABASE_BDTR
* @arg TIM_DMABASE_CCMR3
* @arg TIM_DMABASE_CCR5
* @arg TIM_DMABASE_CCR6
* @arg TIM_DMABASE_DTR2
* @arg TIM_DMABASE_ECR
* @arg TIM_DMABASE_TISEL
* @arg TIM_DMABASE_AF1
* @arg TIM_DMABASE_AF2
* @arg TIM_DMABASE_OR
* @param BurstRequestSrc TIM DMA Request sources
* This parameter can be one of the following values:
* @arg TIM_DMA_UPDATE: TIM update Interrupt source
* @arg TIM_DMA_CC1: TIM Capture Compare 1 DMA source
* @arg TIM_DMA_CC2: TIM Capture Compare 2 DMA source
* @arg TIM_DMA_CC3: TIM Capture Compare 3 DMA source
* @arg TIM_DMA_CC4: TIM Capture Compare 4 DMA source
* @arg TIM_DMA_COM: TIM Commutation DMA source
* @arg TIM_DMA_TRIGGER: TIM Trigger DMA source
* @param BurstBuffer The Buffer address.
* @param BurstLength DMA Burst length. This parameter can be one value
* between: TIM_DMABURSTLENGTH_1TRANSFER and TIM_DMABURSTLENGTH_26TRANSFER.
* @note This function should be used only when BurstLength is equal to DMA data transfer length.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_DMABurst_ReadStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, uint32_t *BurstBuffer, uint32_t BurstLength)
{
HAL_StatusTypeDef status;
status = HAL_TIM_DMABurst_MultiReadStart(htim, BurstBaseAddress, BurstRequestSrc, BurstBuffer, BurstLength,
((BurstLength) >> 8U) + 1U);
return status;
}
/**
* @brief Configure the DMA Burst to transfer Data from the TIM peripheral to the memory
* @param htim TIM handle
* @param BurstBaseAddress TIM Base address from where the DMA will start the Data read
* This parameter can be one of the following values:
* @arg TIM_DMABASE_CR1
* @arg TIM_DMABASE_CR2
* @arg TIM_DMABASE_SMCR
* @arg TIM_DMABASE_DIER
* @arg TIM_DMABASE_SR
* @arg TIM_DMABASE_EGR
* @arg TIM_DMABASE_CCMR1
* @arg TIM_DMABASE_CCMR2
* @arg TIM_DMABASE_CCER
* @arg TIM_DMABASE_CNT
* @arg TIM_DMABASE_PSC
* @arg TIM_DMABASE_ARR
* @arg TIM_DMABASE_RCR
* @arg TIM_DMABASE_CCR1
* @arg TIM_DMABASE_CCR2
* @arg TIM_DMABASE_CCR3
* @arg TIM_DMABASE_CCR4
* @arg TIM_DMABASE_BDTR
* @arg TIM_DMABASE_CCMR3
* @arg TIM_DMABASE_CCR5
* @arg TIM_DMABASE_CCR6
* @arg TIM_DMABASE_DTR2
* @arg TIM_DMABASE_ECR
* @arg TIM_DMABASE_TISEL
* @arg TIM_DMABASE_AF1
* @arg TIM_DMABASE_AF2
* @arg TIM_DMABASE_OR
* @param BurstRequestSrc TIM DMA Request sources
* This parameter can be one of the following values:
* @arg TIM_DMA_UPDATE: TIM update Interrupt source
* @arg TIM_DMA_CC1: TIM Capture Compare 1 DMA source
* @arg TIM_DMA_CC2: TIM Capture Compare 2 DMA source
* @arg TIM_DMA_CC3: TIM Capture Compare 3 DMA source
* @arg TIM_DMA_CC4: TIM Capture Compare 4 DMA source
* @arg TIM_DMA_COM: TIM Commutation DMA source
* @arg TIM_DMA_TRIGGER: TIM Trigger DMA source
* @param BurstBuffer The Buffer address.
* @param BurstLength DMA Burst length. This parameter can be one value
* between: TIM_DMABURSTLENGTH_1TRANSFER and TIM_DMABURSTLENGTH_26TRANSFER.
* @param DataLength Data length. This parameter can be one value
* between 1 and 0xFFFF.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_DMABurst_MultiReadStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, uint32_t *BurstBuffer,
uint32_t BurstLength, uint32_t DataLength)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_DMABURST_INSTANCE(htim->Instance));
assert_param(IS_TIM_DMA_BASE(BurstBaseAddress));
assert_param(IS_TIM_DMA_SOURCE(BurstRequestSrc));
assert_param(IS_TIM_DMA_LENGTH(BurstLength));
assert_param(IS_TIM_DMA_DATA_LENGTH(DataLength));
if (htim->DMABurstState == HAL_DMA_BURST_STATE_BUSY)
{
return HAL_BUSY;
}
else if (htim->DMABurstState == HAL_DMA_BURST_STATE_READY)
{
if ((BurstBuffer == NULL) && (BurstLength > 0U))
{
return HAL_ERROR;
}
else
{
htim->DMABurstState = HAL_DMA_BURST_STATE_BUSY;
}
}
else
{
/* nothing to do */
}
switch (BurstRequestSrc)
{
case TIM_DMA_UPDATE:
{
/* Set the DMA Period elapsed callbacks */
htim->hdma[TIM_DMA_ID_UPDATE]->XferCpltCallback = TIM_DMAPeriodElapsedCplt;
htim->hdma[TIM_DMA_ID_UPDATE]->XferHalfCpltCallback = TIM_DMAPeriodElapsedHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_UPDATE]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_UPDATE], (uint32_t)&htim->Instance->DMAR, (uint32_t)BurstBuffer,
DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC1:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC1]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC1]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC1]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC1], (uint32_t)&htim->Instance->DMAR, (uint32_t)BurstBuffer,
DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC2:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC2]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC2]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC2]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC2], (uint32_t)&htim->Instance->DMAR, (uint32_t)BurstBuffer,
DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC3:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC3]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC3]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC3]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC3], (uint32_t)&htim->Instance->DMAR, (uint32_t)BurstBuffer,
DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_CC4:
{
/* Set the DMA capture callbacks */
htim->hdma[TIM_DMA_ID_CC4]->XferCpltCallback = TIM_DMACaptureCplt;
htim->hdma[TIM_DMA_ID_CC4]->XferHalfCpltCallback = TIM_DMACaptureHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_CC4]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_CC4], (uint32_t)&htim->Instance->DMAR, (uint32_t)BurstBuffer,
DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_COM:
{
/* Set the DMA commutation callbacks */
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferCpltCallback = TIMEx_DMACommutationCplt;
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferHalfCpltCallback = TIMEx_DMACommutationHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_COMMUTATION]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_COMMUTATION], (uint32_t)&htim->Instance->DMAR, (uint32_t)BurstBuffer,
DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
case TIM_DMA_TRIGGER:
{
/* Set the DMA trigger callbacks */
htim->hdma[TIM_DMA_ID_TRIGGER]->XferCpltCallback = TIM_DMATriggerCplt;
htim->hdma[TIM_DMA_ID_TRIGGER]->XferHalfCpltCallback = TIM_DMATriggerHalfCplt;
/* Set the DMA error callback */
htim->hdma[TIM_DMA_ID_TRIGGER]->XferErrorCallback = TIM_DMAError ;
/* Enable the DMA channel */
if (HAL_DMA_Start_IT(htim->hdma[TIM_DMA_ID_TRIGGER], (uint32_t)&htim->Instance->DMAR, (uint32_t)BurstBuffer,
DataLength) != HAL_OK)
{
/* Return error status */
return HAL_ERROR;
}
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Configure the DMA Burst Mode */
htim->Instance->DCR = (BurstBaseAddress | BurstLength);
/* Enable the TIM DMA Request */
__HAL_TIM_ENABLE_DMA(htim, BurstRequestSrc);
}
/* Return function status */
return status;
}
/**
* @brief Stop the DMA burst reading
* @param htim TIM handle
* @param BurstRequestSrc TIM DMA Request sources to disable.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_DMABurst_ReadStop(TIM_HandleTypeDef *htim, uint32_t BurstRequestSrc)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_DMA_SOURCE(BurstRequestSrc));
/* Abort the DMA transfer (at least disable the DMA channel) */
switch (BurstRequestSrc)
{
case TIM_DMA_UPDATE:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_UPDATE]);
break;
}
case TIM_DMA_CC1:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC1]);
break;
}
case TIM_DMA_CC2:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC2]);
break;
}
case TIM_DMA_CC3:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC3]);
break;
}
case TIM_DMA_CC4:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_CC4]);
break;
}
case TIM_DMA_COM:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_COMMUTATION]);
break;
}
case TIM_DMA_TRIGGER:
{
(void)HAL_DMA_Abort_IT(htim->hdma[TIM_DMA_ID_TRIGGER]);
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Disable the TIM Update DMA request */
__HAL_TIM_DISABLE_DMA(htim, BurstRequestSrc);
/* Change the DMA burst operation state */
htim->DMABurstState = HAL_DMA_BURST_STATE_READY;
}
/* Return function status */
return status;
}
/**
* @brief Generate a software event
* @param htim TIM handle
* @param EventSource specifies the event source.
* This parameter can be one of the following values:
* @arg TIM_EVENTSOURCE_UPDATE: Timer update Event source
* @arg TIM_EVENTSOURCE_CC1: Timer Capture Compare 1 Event source
* @arg TIM_EVENTSOURCE_CC2: Timer Capture Compare 2 Event source
* @arg TIM_EVENTSOURCE_CC3: Timer Capture Compare 3 Event source
* @arg TIM_EVENTSOURCE_CC4: Timer Capture Compare 4 Event source
* @arg TIM_EVENTSOURCE_COM: Timer COM event source
* @arg TIM_EVENTSOURCE_TRIGGER: Timer Trigger Event source
* @arg TIM_EVENTSOURCE_BREAK: Timer Break event source
* @arg TIM_EVENTSOURCE_BREAK2: Timer Break2 event source
* @note Basic timers can only generate an update event.
* @note TIM_EVENTSOURCE_COM is relevant only with advanced timer instances.
* @note TIM_EVENTSOURCE_BREAK and TIM_EVENTSOURCE_BREAK2 are relevant
* only for timer instances supporting break input(s).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_GenerateEvent(TIM_HandleTypeDef *htim, uint32_t EventSource)
{
/* Check the parameters */
assert_param(IS_TIM_INSTANCE(htim->Instance));
assert_param(IS_TIM_EVENT_SOURCE(EventSource));
/* Process Locked */
__HAL_LOCK(htim);
/* Change the TIM state */
htim->State = HAL_TIM_STATE_BUSY;
/* Set the event sources */
htim->Instance->EGR = EventSource;
/* Change the TIM state */
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
/* Return function status */
return HAL_OK;
}
/**
* @brief Configures the OCRef clear feature
* @param htim TIM handle
* @param sClearInputConfig pointer to a TIM_ClearInputConfigTypeDef structure that
* contains the OCREF clear feature and parameters for the TIM peripheral.
* @param Channel specifies the TIM Channel
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1
* @arg TIM_CHANNEL_2: TIM Channel 2
* @arg TIM_CHANNEL_3: TIM Channel 3
* @arg TIM_CHANNEL_4: TIM Channel 4
* @arg TIM_CHANNEL_5: TIM Channel 5
* @arg TIM_CHANNEL_6: TIM Channel 6
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_ConfigOCrefClear(TIM_HandleTypeDef *htim,
const TIM_ClearInputConfigTypeDef *sClearInputConfig,
uint32_t Channel)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_TIM_OCXREF_CLEAR_INSTANCE(htim->Instance));
assert_param(IS_TIM_CLEARINPUT_SOURCE(sClearInputConfig->ClearInputSource));
/* Process Locked */
__HAL_LOCK(htim);
htim->State = HAL_TIM_STATE_BUSY;
switch (sClearInputConfig->ClearInputSource)
{
case TIM_CLEARINPUTSOURCE_NONE:
{
/* Clear the OCREF clear selection bit and the the ETR Bits */
if (IS_TIM_OCCS_INSTANCE(htim->Instance))
{
CLEAR_BIT(htim->Instance->SMCR, (TIM_SMCR_OCCS | TIM_SMCR_ETF | TIM_SMCR_ETPS | TIM_SMCR_ECE | TIM_SMCR_ETP));
/* Clear TIMx_AF2_OCRSEL (reset value) */
CLEAR_BIT(htim->Instance->AF2, TIMx_AF2_OCRSEL);
}
else
{
CLEAR_BIT(htim->Instance->SMCR, (TIM_SMCR_ETF | TIM_SMCR_ETPS | TIM_SMCR_ECE | TIM_SMCR_ETP));
}
break;
}
case TIM_CLEARINPUTSOURCE_COMP1:
case TIM_CLEARINPUTSOURCE_COMP2:
case TIM_CLEARINPUTSOURCE_COMP3:
case TIM_CLEARINPUTSOURCE_COMP4:
#if defined (COMP5)
case TIM_CLEARINPUTSOURCE_COMP5:
#endif /* COMP5 */
#if defined (COMP6)
case TIM_CLEARINPUTSOURCE_COMP6:
#endif /* COMP6 */
#if defined (COMP7)
case TIM_CLEARINPUTSOURCE_COMP7:
#endif /* COMP7 */
{
if (IS_TIM_OCCS_INSTANCE(htim->Instance))
{
/* Clear the OCREF clear selection bit */
CLEAR_BIT(htim->Instance->SMCR, TIM_SMCR_OCCS);
}
/* Set the clear input source */
MODIFY_REG(htim->Instance->AF2, TIMx_AF2_OCRSEL, sClearInputConfig->ClearInputSource);
break;
}
case TIM_CLEARINPUTSOURCE_ETR:
{
/* Check the parameters */
assert_param(IS_TIM_CLEARINPUT_POLARITY(sClearInputConfig->ClearInputPolarity));
assert_param(IS_TIM_CLEARINPUT_PRESCALER(sClearInputConfig->ClearInputPrescaler));
assert_param(IS_TIM_CLEARINPUT_FILTER(sClearInputConfig->ClearInputFilter));
/* When OCRef clear feature is used with ETR source, ETR prescaler must be off */
if (sClearInputConfig->ClearInputPrescaler != TIM_CLEARINPUTPRESCALER_DIV1)
{
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return HAL_ERROR;
}
TIM_ETR_SetConfig(htim->Instance,
sClearInputConfig->ClearInputPrescaler,
sClearInputConfig->ClearInputPolarity,
sClearInputConfig->ClearInputFilter);
if (IS_TIM_OCCS_INSTANCE(htim->Instance))
{
/* Set the OCREF clear selection bit */
SET_BIT(htim->Instance->SMCR, TIM_SMCR_OCCS);
/* Clear TIMx_AF2_OCRSEL (reset value) */
CLEAR_BIT(htim->Instance->AF2, TIMx_AF2_OCRSEL);
}
break;
}
default:
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
switch (Channel)
{
case TIM_CHANNEL_1:
{
if (sClearInputConfig->ClearInputState != (uint32_t)DISABLE)
{
/* Enable the OCREF clear feature for Channel 1 */
SET_BIT(htim->Instance->CCMR1, TIM_CCMR1_OC1CE);
}
else
{
/* Disable the OCREF clear feature for Channel 1 */
CLEAR_BIT(htim->Instance->CCMR1, TIM_CCMR1_OC1CE);
}
break;
}
case TIM_CHANNEL_2:
{
if (sClearInputConfig->ClearInputState != (uint32_t)DISABLE)
{
/* Enable the OCREF clear feature for Channel 2 */
SET_BIT(htim->Instance->CCMR1, TIM_CCMR1_OC2CE);
}
else
{
/* Disable the OCREF clear feature for Channel 2 */
CLEAR_BIT(htim->Instance->CCMR1, TIM_CCMR1_OC2CE);
}
break;
}
case TIM_CHANNEL_3:
{
if (sClearInputConfig->ClearInputState != (uint32_t)DISABLE)
{
/* Enable the OCREF clear feature for Channel 3 */
SET_BIT(htim->Instance->CCMR2, TIM_CCMR2_OC3CE);
}
else
{
/* Disable the OCREF clear feature for Channel 3 */
CLEAR_BIT(htim->Instance->CCMR2, TIM_CCMR2_OC3CE);
}
break;
}
case TIM_CHANNEL_4:
{
if (sClearInputConfig->ClearInputState != (uint32_t)DISABLE)
{
/* Enable the OCREF clear feature for Channel 4 */
SET_BIT(htim->Instance->CCMR2, TIM_CCMR2_OC4CE);
}
else
{
/* Disable the OCREF clear feature for Channel 4 */
CLEAR_BIT(htim->Instance->CCMR2, TIM_CCMR2_OC4CE);
}
break;
}
case TIM_CHANNEL_5:
{
if (sClearInputConfig->ClearInputState != (uint32_t)DISABLE)
{
/* Enable the OCREF clear feature for Channel 5 */
SET_BIT(htim->Instance->CCMR3, TIM_CCMR3_OC5CE);
}
else
{
/* Disable the OCREF clear feature for Channel 5 */
CLEAR_BIT(htim->Instance->CCMR3, TIM_CCMR3_OC5CE);
}
break;
}
case TIM_CHANNEL_6:
{
if (sClearInputConfig->ClearInputState != (uint32_t)DISABLE)
{
/* Enable the OCREF clear feature for Channel 6 */
SET_BIT(htim->Instance->CCMR3, TIM_CCMR3_OC6CE);
}
else
{
/* Disable the OCREF clear feature for Channel 6 */
CLEAR_BIT(htim->Instance->CCMR3, TIM_CCMR3_OC6CE);
}
break;
}
default:
break;
}
}
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return status;
}
/**
* @brief Configures the clock source to be used
* @param htim TIM handle
* @param sClockSourceConfig pointer to a TIM_ClockConfigTypeDef structure that
* contains the clock source information for the TIM peripheral.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_ConfigClockSource(TIM_HandleTypeDef *htim, const TIM_ClockConfigTypeDef *sClockSourceConfig)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
/* Process Locked */
__HAL_LOCK(htim);
htim->State = HAL_TIM_STATE_BUSY;
/* Check the parameters */
assert_param(IS_TIM_CLOCKSOURCE(sClockSourceConfig->ClockSource));
/* Reset the SMS, TS, ECE, ETPS and ETRF bits */
tmpsmcr = htim->Instance->SMCR;
tmpsmcr &= ~(TIM_SMCR_SMS | TIM_SMCR_TS);
tmpsmcr &= ~(TIM_SMCR_ETF | TIM_SMCR_ETPS | TIM_SMCR_ECE | TIM_SMCR_ETP);
htim->Instance->SMCR = tmpsmcr;
switch (sClockSourceConfig->ClockSource)
{
case TIM_CLOCKSOURCE_INTERNAL:
{
assert_param(IS_TIM_INSTANCE(htim->Instance));
break;
}
case TIM_CLOCKSOURCE_ETRMODE1:
{
/* Check whether or not the timer instance supports external trigger input mode 1 (ETRF)*/
assert_param(IS_TIM_CLOCKSOURCE_ETRMODE1_INSTANCE(htim->Instance));
/* Check ETR input conditioning related parameters */
assert_param(IS_TIM_CLOCKPRESCALER(sClockSourceConfig->ClockPrescaler));
assert_param(IS_TIM_CLOCKPOLARITY(sClockSourceConfig->ClockPolarity));
assert_param(IS_TIM_CLOCKFILTER(sClockSourceConfig->ClockFilter));
/* Configure the ETR Clock source */
TIM_ETR_SetConfig(htim->Instance,
sClockSourceConfig->ClockPrescaler,
sClockSourceConfig->ClockPolarity,
sClockSourceConfig->ClockFilter);
/* Select the External clock mode1 and the ETRF trigger */
tmpsmcr = htim->Instance->SMCR;
tmpsmcr |= (TIM_SLAVEMODE_EXTERNAL1 | TIM_CLOCKSOURCE_ETRMODE1);
/* Write to TIMx SMCR */
htim->Instance->SMCR = tmpsmcr;
break;
}
case TIM_CLOCKSOURCE_ETRMODE2:
{
/* Check whether or not the timer instance supports external trigger input mode 2 (ETRF)*/
assert_param(IS_TIM_CLOCKSOURCE_ETRMODE2_INSTANCE(htim->Instance));
/* Check ETR input conditioning related parameters */
assert_param(IS_TIM_CLOCKPRESCALER(sClockSourceConfig->ClockPrescaler));
assert_param(IS_TIM_CLOCKPOLARITY(sClockSourceConfig->ClockPolarity));
assert_param(IS_TIM_CLOCKFILTER(sClockSourceConfig->ClockFilter));
/* Configure the ETR Clock source */
TIM_ETR_SetConfig(htim->Instance,
sClockSourceConfig->ClockPrescaler,
sClockSourceConfig->ClockPolarity,
sClockSourceConfig->ClockFilter);
/* Enable the External clock mode2 */
htim->Instance->SMCR |= TIM_SMCR_ECE;
break;
}
case TIM_CLOCKSOURCE_TI1:
{
/* Check whether or not the timer instance supports external clock mode 1 */
assert_param(IS_TIM_CLOCKSOURCE_TIX_INSTANCE(htim->Instance));
/* Check TI1 input conditioning related parameters */
assert_param(IS_TIM_CLOCKPOLARITY(sClockSourceConfig->ClockPolarity));
assert_param(IS_TIM_CLOCKFILTER(sClockSourceConfig->ClockFilter));
TIM_TI1_ConfigInputStage(htim->Instance,
sClockSourceConfig->ClockPolarity,
sClockSourceConfig->ClockFilter);
TIM_ITRx_SetConfig(htim->Instance, TIM_CLOCKSOURCE_TI1);
break;
}
case TIM_CLOCKSOURCE_TI2:
{
/* Check whether or not the timer instance supports external clock mode 1 (ETRF)*/
assert_param(IS_TIM_CLOCKSOURCE_TIX_INSTANCE(htim->Instance));
/* Check TI2 input conditioning related parameters */
assert_param(IS_TIM_CLOCKPOLARITY(sClockSourceConfig->ClockPolarity));
assert_param(IS_TIM_CLOCKFILTER(sClockSourceConfig->ClockFilter));
TIM_TI2_ConfigInputStage(htim->Instance,
sClockSourceConfig->ClockPolarity,
sClockSourceConfig->ClockFilter);
TIM_ITRx_SetConfig(htim->Instance, TIM_CLOCKSOURCE_TI2);
break;
}
case TIM_CLOCKSOURCE_TI1ED:
{
/* Check whether or not the timer instance supports external clock mode 1 */
assert_param(IS_TIM_CLOCKSOURCE_TIX_INSTANCE(htim->Instance));
/* Check TI1 input conditioning related parameters */
assert_param(IS_TIM_CLOCKPOLARITY(sClockSourceConfig->ClockPolarity));
assert_param(IS_TIM_CLOCKFILTER(sClockSourceConfig->ClockFilter));
TIM_TI1_ConfigInputStage(htim->Instance,
sClockSourceConfig->ClockPolarity,
sClockSourceConfig->ClockFilter);
TIM_ITRx_SetConfig(htim->Instance, TIM_CLOCKSOURCE_TI1ED);
break;
}
case TIM_CLOCKSOURCE_ITR0:
case TIM_CLOCKSOURCE_ITR1:
case TIM_CLOCKSOURCE_ITR2:
case TIM_CLOCKSOURCE_ITR3:
#if defined (TIM5)
case TIM_CLOCKSOURCE_ITR4:
#endif /* TIM5 */
case TIM_CLOCKSOURCE_ITR5:
case TIM_CLOCKSOURCE_ITR6:
case TIM_CLOCKSOURCE_ITR7:
case TIM_CLOCKSOURCE_ITR8:
#if defined (TIM20)
case TIM_CLOCKSOURCE_ITR9:
#endif /* TIM20 */
#if defined (HRTIM1)
case TIM_CLOCKSOURCE_ITR10:
#endif /* HRTIM1 */
case TIM_CLOCKSOURCE_ITR11:
{
/* Check whether or not the timer instance supports internal trigger input */
assert_param(IS_TIM_CLOCKSOURCE_INSTANCE((htim->Instance), sClockSourceConfig->ClockSource));
TIM_ITRx_SetConfig(htim->Instance, sClockSourceConfig->ClockSource);
break;
}
default:
status = HAL_ERROR;
break;
}
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return status;
}
/**
* @brief Selects the signal connected to the TI1 input: direct from CH1_input
* or a XOR combination between CH1_input, CH2_input & CH3_input
* @param htim TIM handle.
* @param TI1_Selection Indicate whether or not channel 1 is connected to the
* output of a XOR gate.
* This parameter can be one of the following values:
* @arg TIM_TI1SELECTION_CH1: The TIMx_CH1 pin is connected to TI1 input
* @arg TIM_TI1SELECTION_XORCOMBINATION: The TIMx_CH1, CH2 and CH3
* pins are connected to the TI1 input (XOR combination)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_ConfigTI1Input(TIM_HandleTypeDef *htim, uint32_t TI1_Selection)
{
uint32_t tmpcr2;
/* Check the parameters */
assert_param(IS_TIM_XOR_INSTANCE(htim->Instance));
assert_param(IS_TIM_TI1SELECTION(TI1_Selection));
/* Get the TIMx CR2 register value */
tmpcr2 = htim->Instance->CR2;
/* Reset the TI1 selection */
tmpcr2 &= ~TIM_CR2_TI1S;
/* Set the TI1 selection */
tmpcr2 |= TI1_Selection;
/* Write to TIMxCR2 */
htim->Instance->CR2 = tmpcr2;
return HAL_OK;
}
/**
* @brief Configures the TIM in Slave mode
* @param htim TIM handle.
* @param sSlaveConfig pointer to a TIM_SlaveConfigTypeDef structure that
* contains the selected trigger (internal trigger input, filtered
* timer input or external trigger input) and the Slave mode
* (Disable, Reset, Gated, Trigger, External clock mode 1, Reset + Trigger, Gated + Reset).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_SlaveConfigSynchro(TIM_HandleTypeDef *htim, const TIM_SlaveConfigTypeDef *sSlaveConfig)
{
/* Check the parameters */
assert_param(IS_TIM_SLAVE_INSTANCE(htim->Instance));
assert_param(IS_TIM_SLAVE_MODE(sSlaveConfig->SlaveMode));
assert_param(IS_TIM_TRIGGER_INSTANCE(htim->Instance, sSlaveConfig->InputTrigger));
__HAL_LOCK(htim);
htim->State = HAL_TIM_STATE_BUSY;
if (TIM_SlaveTimer_SetConfig(htim, sSlaveConfig) != HAL_OK)
{
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return HAL_ERROR;
}
/* Disable Trigger Interrupt */
__HAL_TIM_DISABLE_IT(htim, TIM_IT_TRIGGER);
/* Disable Trigger DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_TRIGGER);
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Configures the TIM in Slave mode in interrupt mode
* @param htim TIM handle.
* @param sSlaveConfig pointer to a TIM_SlaveConfigTypeDef structure that
* contains the selected trigger (internal trigger input, filtered
* timer input or external trigger input) and the Slave mode
* (Disable, Reset, Gated, Trigger, External clock mode 1, Reset + Trigger, Gated + Reset).
* @retval HAL status
*/
HAL_StatusTypeDef HAL_TIM_SlaveConfigSynchro_IT(TIM_HandleTypeDef *htim,
const TIM_SlaveConfigTypeDef *sSlaveConfig)
{
/* Check the parameters */
assert_param(IS_TIM_SLAVE_INSTANCE(htim->Instance));
assert_param(IS_TIM_SLAVE_MODE(sSlaveConfig->SlaveMode));
assert_param(IS_TIM_TRIGGER_INSTANCE(htim->Instance, sSlaveConfig->InputTrigger));
__HAL_LOCK(htim);
htim->State = HAL_TIM_STATE_BUSY;
if (TIM_SlaveTimer_SetConfig(htim, sSlaveConfig) != HAL_OK)
{
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return HAL_ERROR;
}
/* Enable Trigger Interrupt */
__HAL_TIM_ENABLE_IT(htim, TIM_IT_TRIGGER);
/* Disable Trigger DMA request */
__HAL_TIM_DISABLE_DMA(htim, TIM_DMA_TRIGGER);
htim->State = HAL_TIM_STATE_READY;
__HAL_UNLOCK(htim);
return HAL_OK;
}
/**
* @brief Read the captured value from Capture Compare unit
* @param htim TIM handle.
* @param Channel TIM Channels to be enabled
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @retval Captured value
*/
uint32_t HAL_TIM_ReadCapturedValue(const TIM_HandleTypeDef *htim, uint32_t Channel)
{
uint32_t tmpreg = 0U;
switch (Channel)
{
case TIM_CHANNEL_1:
{
/* Check the parameters */
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
/* Return the capture 1 value */
tmpreg = htim->Instance->CCR1;
break;
}
case TIM_CHANNEL_2:
{
/* Check the parameters */
assert_param(IS_TIM_CC2_INSTANCE(htim->Instance));
/* Return the capture 2 value */
tmpreg = htim->Instance->CCR2;
break;
}
case TIM_CHANNEL_3:
{
/* Check the parameters */
assert_param(IS_TIM_CC3_INSTANCE(htim->Instance));
/* Return the capture 3 value */
tmpreg = htim->Instance->CCR3;
break;
}
case TIM_CHANNEL_4:
{
/* Check the parameters */
assert_param(IS_TIM_CC4_INSTANCE(htim->Instance));
/* Return the capture 4 value */
tmpreg = htim->Instance->CCR4;
break;
}
default:
break;
}
return tmpreg;
}
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group9 TIM Callbacks functions
* @brief TIM Callbacks functions
*
@verbatim
==============================================================================
##### TIM Callbacks functions #####
==============================================================================
[..]
This section provides TIM callback functions:
(+) TIM Period elapsed callback
(+) TIM Output Compare callback
(+) TIM Input capture callback
(+) TIM Trigger callback
(+) TIM Error callback
(+) TIM Index callback
(+) TIM Direction change callback
(+) TIM Index error callback
(+) TIM Transition error callback
@endverbatim
* @{
*/
/**
* @brief Period elapsed callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_PeriodElapsedCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_PeriodElapsedCallback could be implemented in the user file
*/
}
/**
* @brief Period elapsed half complete callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_PeriodElapsedHalfCpltCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_PeriodElapsedHalfCpltCallback could be implemented in the user file
*/
}
/**
* @brief Output Compare callback in non-blocking mode
* @param htim TIM OC handle
* @retval None
*/
__weak void HAL_TIM_OC_DelayElapsedCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_OC_DelayElapsedCallback could be implemented in the user file
*/
}
/**
* @brief Input Capture callback in non-blocking mode
* @param htim TIM IC handle
* @retval None
*/
__weak void HAL_TIM_IC_CaptureCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_IC_CaptureCallback could be implemented in the user file
*/
}
/**
* @brief Input Capture half complete callback in non-blocking mode
* @param htim TIM IC handle
* @retval None
*/
__weak void HAL_TIM_IC_CaptureHalfCpltCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_IC_CaptureHalfCpltCallback could be implemented in the user file
*/
}
/**
* @brief PWM Pulse finished callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_PWM_PulseFinishedCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_PWM_PulseFinishedCallback could be implemented in the user file
*/
}
/**
* @brief PWM Pulse finished half complete callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_PWM_PulseFinishedHalfCpltCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_PWM_PulseFinishedHalfCpltCallback could be implemented in the user file
*/
}
/**
* @brief Hall Trigger detection callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_TriggerCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_TriggerCallback could be implemented in the user file
*/
}
/**
* @brief Hall Trigger detection half complete callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_TriggerHalfCpltCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_TriggerHalfCpltCallback could be implemented in the user file
*/
}
/**
* @brief Timer error callback in non-blocking mode
* @param htim TIM handle
* @retval None
*/
__weak void HAL_TIM_ErrorCallback(TIM_HandleTypeDef *htim)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(htim);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_TIM_ErrorCallback could be implemented in the user file
*/
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/**
* @brief Register a User TIM callback to be used instead of the weak predefined callback
* @param htim tim handle
* @param CallbackID ID of the callback to be registered
* This parameter can be one of the following values:
* @arg @ref HAL_TIM_BASE_MSPINIT_CB_ID Base MspInit Callback ID
* @arg @ref HAL_TIM_BASE_MSPDEINIT_CB_ID Base MspDeInit Callback ID
* @arg @ref HAL_TIM_IC_MSPINIT_CB_ID IC MspInit Callback ID
* @arg @ref HAL_TIM_IC_MSPDEINIT_CB_ID IC MspDeInit Callback ID
* @arg @ref HAL_TIM_OC_MSPINIT_CB_ID OC MspInit Callback ID
* @arg @ref HAL_TIM_OC_MSPDEINIT_CB_ID OC MspDeInit Callback ID
* @arg @ref HAL_TIM_PWM_MSPINIT_CB_ID PWM MspInit Callback ID
* @arg @ref HAL_TIM_PWM_MSPDEINIT_CB_ID PWM MspDeInit Callback ID
* @arg @ref HAL_TIM_ONE_PULSE_MSPINIT_CB_ID One Pulse MspInit Callback ID
* @arg @ref HAL_TIM_ONE_PULSE_MSPDEINIT_CB_ID One Pulse MspDeInit Callback ID
* @arg @ref HAL_TIM_ENCODER_MSPINIT_CB_ID Encoder MspInit Callback ID
* @arg @ref HAL_TIM_ENCODER_MSPDEINIT_CB_ID Encoder MspDeInit Callback ID
* @arg @ref HAL_TIM_HALL_SENSOR_MSPINIT_CB_ID Hall Sensor MspInit Callback ID
* @arg @ref HAL_TIM_HALL_SENSOR_MSPDEINIT_CB_ID Hall Sensor MspDeInit Callback ID
* @arg @ref HAL_TIM_PERIOD_ELAPSED_CB_ID Period Elapsed Callback ID
* @arg @ref HAL_TIM_PERIOD_ELAPSED_HALF_CB_ID Period Elapsed half complete Callback ID
* @arg @ref HAL_TIM_TRIGGER_CB_ID Trigger Callback ID
* @arg @ref HAL_TIM_TRIGGER_HALF_CB_ID Trigger half complete Callback ID
* @arg @ref HAL_TIM_IC_CAPTURE_CB_ID Input Capture Callback ID
* @arg @ref HAL_TIM_IC_CAPTURE_HALF_CB_ID Input Capture half complete Callback ID
* @arg @ref HAL_TIM_OC_DELAY_ELAPSED_CB_ID Output Compare Delay Elapsed Callback ID
* @arg @ref HAL_TIM_PWM_PULSE_FINISHED_CB_ID PWM Pulse Finished Callback ID
* @arg @ref HAL_TIM_PWM_PULSE_FINISHED_HALF_CB_ID PWM Pulse Finished half complete Callback ID
* @arg @ref HAL_TIM_ERROR_CB_ID Error Callback ID
* @arg @ref HAL_TIM_COMMUTATION_CB_ID Commutation Callback ID
* @arg @ref HAL_TIM_COMMUTATION_HALF_CB_ID Commutation half complete Callback ID
* @arg @ref HAL_TIM_BREAK_CB_ID Break Callback ID
* @arg @ref HAL_TIM_BREAK2_CB_ID Break2 Callback ID
* @arg @ref HAL_TIM_ENCODER_INDEX_CB_ID Encoder Index Callback ID
* @arg @ref HAL_TIM_DIRECTION_CHANGE_CB_ID Direction Change Callback ID
* @arg @ref HAL_TIM_INDEX_ERROR_CB_ID Index Error Callback ID
* @arg @ref HAL_TIM_TRANSITION_ERROR_CB_ID Transition Error Callback ID
* @param pCallback pointer to the callback function
* @retval status
*/
HAL_StatusTypeDef HAL_TIM_RegisterCallback(TIM_HandleTypeDef *htim, HAL_TIM_CallbackIDTypeDef CallbackID,
pTIM_CallbackTypeDef pCallback)
{
HAL_StatusTypeDef status = HAL_OK;
if (pCallback == NULL)
{
return HAL_ERROR;
}
if (htim->State == HAL_TIM_STATE_READY)
{
switch (CallbackID)
{
case HAL_TIM_BASE_MSPINIT_CB_ID :
htim->Base_MspInitCallback = pCallback;
break;
case HAL_TIM_BASE_MSPDEINIT_CB_ID :
htim->Base_MspDeInitCallback = pCallback;
break;
case HAL_TIM_IC_MSPINIT_CB_ID :
htim->IC_MspInitCallback = pCallback;
break;
case HAL_TIM_IC_MSPDEINIT_CB_ID :
htim->IC_MspDeInitCallback = pCallback;
break;
case HAL_TIM_OC_MSPINIT_CB_ID :
htim->OC_MspInitCallback = pCallback;
break;
case HAL_TIM_OC_MSPDEINIT_CB_ID :
htim->OC_MspDeInitCallback = pCallback;
break;
case HAL_TIM_PWM_MSPINIT_CB_ID :
htim->PWM_MspInitCallback = pCallback;
break;
case HAL_TIM_PWM_MSPDEINIT_CB_ID :
htim->PWM_MspDeInitCallback = pCallback;
break;
case HAL_TIM_ONE_PULSE_MSPINIT_CB_ID :
htim->OnePulse_MspInitCallback = pCallback;
break;
case HAL_TIM_ONE_PULSE_MSPDEINIT_CB_ID :
htim->OnePulse_MspDeInitCallback = pCallback;
break;
case HAL_TIM_ENCODER_MSPINIT_CB_ID :
htim->Encoder_MspInitCallback = pCallback;
break;
case HAL_TIM_ENCODER_MSPDEINIT_CB_ID :
htim->Encoder_MspDeInitCallback = pCallback;
break;
case HAL_TIM_HALL_SENSOR_MSPINIT_CB_ID :
htim->HallSensor_MspInitCallback = pCallback;
break;
case HAL_TIM_HALL_SENSOR_MSPDEINIT_CB_ID :
htim->HallSensor_MspDeInitCallback = pCallback;
break;
case HAL_TIM_PERIOD_ELAPSED_CB_ID :
htim->PeriodElapsedCallback = pCallback;
break;
case HAL_TIM_PERIOD_ELAPSED_HALF_CB_ID :
htim->PeriodElapsedHalfCpltCallback = pCallback;
break;
case HAL_TIM_TRIGGER_CB_ID :
htim->TriggerCallback = pCallback;
break;
case HAL_TIM_TRIGGER_HALF_CB_ID :
htim->TriggerHalfCpltCallback = pCallback;
break;
case HAL_TIM_IC_CAPTURE_CB_ID :
htim->IC_CaptureCallback = pCallback;
break;
case HAL_TIM_IC_CAPTURE_HALF_CB_ID :
htim->IC_CaptureHalfCpltCallback = pCallback;
break;
case HAL_TIM_OC_DELAY_ELAPSED_CB_ID :
htim->OC_DelayElapsedCallback = pCallback;
break;
case HAL_TIM_PWM_PULSE_FINISHED_CB_ID :
htim->PWM_PulseFinishedCallback = pCallback;
break;
case HAL_TIM_PWM_PULSE_FINISHED_HALF_CB_ID :
htim->PWM_PulseFinishedHalfCpltCallback = pCallback;
break;
case HAL_TIM_ERROR_CB_ID :
htim->ErrorCallback = pCallback;
break;
case HAL_TIM_COMMUTATION_CB_ID :
htim->CommutationCallback = pCallback;
break;
case HAL_TIM_COMMUTATION_HALF_CB_ID :
htim->CommutationHalfCpltCallback = pCallback;
break;
case HAL_TIM_BREAK_CB_ID :
htim->BreakCallback = pCallback;
break;
case HAL_TIM_BREAK2_CB_ID :
htim->Break2Callback = pCallback;
break;
case HAL_TIM_ENCODER_INDEX_CB_ID :
htim->EncoderIndexCallback = pCallback;
break;
case HAL_TIM_DIRECTION_CHANGE_CB_ID :
htim->DirectionChangeCallback = pCallback;
break;
case HAL_TIM_INDEX_ERROR_CB_ID :
htim->IndexErrorCallback = pCallback;
break;
case HAL_TIM_TRANSITION_ERROR_CB_ID :
htim->TransitionErrorCallback = pCallback;
break;
default :
/* Return error status */
status = HAL_ERROR;
break;
}
}
else if (htim->State == HAL_TIM_STATE_RESET)
{
switch (CallbackID)
{
case HAL_TIM_BASE_MSPINIT_CB_ID :
htim->Base_MspInitCallback = pCallback;
break;
case HAL_TIM_BASE_MSPDEINIT_CB_ID :
htim->Base_MspDeInitCallback = pCallback;
break;
case HAL_TIM_IC_MSPINIT_CB_ID :
htim->IC_MspInitCallback = pCallback;
break;
case HAL_TIM_IC_MSPDEINIT_CB_ID :
htim->IC_MspDeInitCallback = pCallback;
break;
case HAL_TIM_OC_MSPINIT_CB_ID :
htim->OC_MspInitCallback = pCallback;
break;
case HAL_TIM_OC_MSPDEINIT_CB_ID :
htim->OC_MspDeInitCallback = pCallback;
break;
case HAL_TIM_PWM_MSPINIT_CB_ID :
htim->PWM_MspInitCallback = pCallback;
break;
case HAL_TIM_PWM_MSPDEINIT_CB_ID :
htim->PWM_MspDeInitCallback = pCallback;
break;
case HAL_TIM_ONE_PULSE_MSPINIT_CB_ID :
htim->OnePulse_MspInitCallback = pCallback;
break;
case HAL_TIM_ONE_PULSE_MSPDEINIT_CB_ID :
htim->OnePulse_MspDeInitCallback = pCallback;
break;
case HAL_TIM_ENCODER_MSPINIT_CB_ID :
htim->Encoder_MspInitCallback = pCallback;
break;
case HAL_TIM_ENCODER_MSPDEINIT_CB_ID :
htim->Encoder_MspDeInitCallback = pCallback;
break;
case HAL_TIM_HALL_SENSOR_MSPINIT_CB_ID :
htim->HallSensor_MspInitCallback = pCallback;
break;
case HAL_TIM_HALL_SENSOR_MSPDEINIT_CB_ID :
htim->HallSensor_MspDeInitCallback = pCallback;
break;
default :
/* Return error status */
status = HAL_ERROR;
break;
}
}
else
{
/* Return error status */
status = HAL_ERROR;
}
return status;
}
/**
* @brief Unregister a TIM callback
* TIM callback is redirected to the weak predefined callback
* @param htim tim handle
* @param CallbackID ID of the callback to be unregistered
* This parameter can be one of the following values:
* @arg @ref HAL_TIM_BASE_MSPINIT_CB_ID Base MspInit Callback ID
* @arg @ref HAL_TIM_BASE_MSPDEINIT_CB_ID Base MspDeInit Callback ID
* @arg @ref HAL_TIM_IC_MSPINIT_CB_ID IC MspInit Callback ID
* @arg @ref HAL_TIM_IC_MSPDEINIT_CB_ID IC MspDeInit Callback ID
* @arg @ref HAL_TIM_OC_MSPINIT_CB_ID OC MspInit Callback ID
* @arg @ref HAL_TIM_OC_MSPDEINIT_CB_ID OC MspDeInit Callback ID
* @arg @ref HAL_TIM_PWM_MSPINIT_CB_ID PWM MspInit Callback ID
* @arg @ref HAL_TIM_PWM_MSPDEINIT_CB_ID PWM MspDeInit Callback ID
* @arg @ref HAL_TIM_ONE_PULSE_MSPINIT_CB_ID One Pulse MspInit Callback ID
* @arg @ref HAL_TIM_ONE_PULSE_MSPDEINIT_CB_ID One Pulse MspDeInit Callback ID
* @arg @ref HAL_TIM_ENCODER_MSPINIT_CB_ID Encoder MspInit Callback ID
* @arg @ref HAL_TIM_ENCODER_MSPDEINIT_CB_ID Encoder MspDeInit Callback ID
* @arg @ref HAL_TIM_HALL_SENSOR_MSPINIT_CB_ID Hall Sensor MspInit Callback ID
* @arg @ref HAL_TIM_HALL_SENSOR_MSPDEINIT_CB_ID Hall Sensor MspDeInit Callback ID
* @arg @ref HAL_TIM_PERIOD_ELAPSED_CB_ID Period Elapsed Callback ID
* @arg @ref HAL_TIM_PERIOD_ELAPSED_HALF_CB_ID Period Elapsed half complete Callback ID
* @arg @ref HAL_TIM_TRIGGER_CB_ID Trigger Callback ID
* @arg @ref HAL_TIM_TRIGGER_HALF_CB_ID Trigger half complete Callback ID
* @arg @ref HAL_TIM_IC_CAPTURE_CB_ID Input Capture Callback ID
* @arg @ref HAL_TIM_IC_CAPTURE_HALF_CB_ID Input Capture half complete Callback ID
* @arg @ref HAL_TIM_OC_DELAY_ELAPSED_CB_ID Output Compare Delay Elapsed Callback ID
* @arg @ref HAL_TIM_PWM_PULSE_FINISHED_CB_ID PWM Pulse Finished Callback ID
* @arg @ref HAL_TIM_PWM_PULSE_FINISHED_HALF_CB_ID PWM Pulse Finished half complete Callback ID
* @arg @ref HAL_TIM_ERROR_CB_ID Error Callback ID
* @arg @ref HAL_TIM_COMMUTATION_CB_ID Commutation Callback ID
* @arg @ref HAL_TIM_COMMUTATION_HALF_CB_ID Commutation half complete Callback ID
* @arg @ref HAL_TIM_BREAK_CB_ID Break Callback ID
* @arg @ref HAL_TIM_BREAK2_CB_ID Break2 Callback ID
* @arg @ref HAL_TIM_ENCODER_INDEX_CB_ID Encoder Index Callback ID
* @arg @ref HAL_TIM_DIRECTION_CHANGE_CB_ID Direction Change Callback ID
* @arg @ref HAL_TIM_INDEX_ERROR_CB_ID Index Error Callback ID
* @arg @ref HAL_TIM_TRANSITION_ERROR_CB_ID Transition Error Callback ID
* @retval status
*/
HAL_StatusTypeDef HAL_TIM_UnRegisterCallback(TIM_HandleTypeDef *htim, HAL_TIM_CallbackIDTypeDef CallbackID)
{
HAL_StatusTypeDef status = HAL_OK;
if (htim->State == HAL_TIM_STATE_READY)
{
switch (CallbackID)
{
case HAL_TIM_BASE_MSPINIT_CB_ID :
/* Legacy weak Base MspInit Callback */
htim->Base_MspInitCallback = HAL_TIM_Base_MspInit;
break;
case HAL_TIM_BASE_MSPDEINIT_CB_ID :
/* Legacy weak Base Msp DeInit Callback */
htim->Base_MspDeInitCallback = HAL_TIM_Base_MspDeInit;
break;
case HAL_TIM_IC_MSPINIT_CB_ID :
/* Legacy weak IC Msp Init Callback */
htim->IC_MspInitCallback = HAL_TIM_IC_MspInit;
break;
case HAL_TIM_IC_MSPDEINIT_CB_ID :
/* Legacy weak IC Msp DeInit Callback */
htim->IC_MspDeInitCallback = HAL_TIM_IC_MspDeInit;
break;
case HAL_TIM_OC_MSPINIT_CB_ID :
/* Legacy weak OC Msp Init Callback */
htim->OC_MspInitCallback = HAL_TIM_OC_MspInit;
break;
case HAL_TIM_OC_MSPDEINIT_CB_ID :
/* Legacy weak OC Msp DeInit Callback */
htim->OC_MspDeInitCallback = HAL_TIM_OC_MspDeInit;
break;
case HAL_TIM_PWM_MSPINIT_CB_ID :
/* Legacy weak PWM Msp Init Callback */
htim->PWM_MspInitCallback = HAL_TIM_PWM_MspInit;
break;
case HAL_TIM_PWM_MSPDEINIT_CB_ID :
/* Legacy weak PWM Msp DeInit Callback */
htim->PWM_MspDeInitCallback = HAL_TIM_PWM_MspDeInit;
break;
case HAL_TIM_ONE_PULSE_MSPINIT_CB_ID :
/* Legacy weak One Pulse Msp Init Callback */
htim->OnePulse_MspInitCallback = HAL_TIM_OnePulse_MspInit;
break;
case HAL_TIM_ONE_PULSE_MSPDEINIT_CB_ID :
/* Legacy weak One Pulse Msp DeInit Callback */
htim->OnePulse_MspDeInitCallback = HAL_TIM_OnePulse_MspDeInit;
break;
case HAL_TIM_ENCODER_MSPINIT_CB_ID :
/* Legacy weak Encoder Msp Init Callback */
htim->Encoder_MspInitCallback = HAL_TIM_Encoder_MspInit;
break;
case HAL_TIM_ENCODER_MSPDEINIT_CB_ID :
/* Legacy weak Encoder Msp DeInit Callback */
htim->Encoder_MspDeInitCallback = HAL_TIM_Encoder_MspDeInit;
break;
case HAL_TIM_HALL_SENSOR_MSPINIT_CB_ID :
/* Legacy weak Hall Sensor Msp Init Callback */
htim->HallSensor_MspInitCallback = HAL_TIMEx_HallSensor_MspInit;
break;
case HAL_TIM_HALL_SENSOR_MSPDEINIT_CB_ID :
/* Legacy weak Hall Sensor Msp DeInit Callback */
htim->HallSensor_MspDeInitCallback = HAL_TIMEx_HallSensor_MspDeInit;
break;
case HAL_TIM_PERIOD_ELAPSED_CB_ID :
/* Legacy weak Period Elapsed Callback */
htim->PeriodElapsedCallback = HAL_TIM_PeriodElapsedCallback;
break;
case HAL_TIM_PERIOD_ELAPSED_HALF_CB_ID :
/* Legacy weak Period Elapsed half complete Callback */
htim->PeriodElapsedHalfCpltCallback = HAL_TIM_PeriodElapsedHalfCpltCallback;
break;
case HAL_TIM_TRIGGER_CB_ID :
/* Legacy weak Trigger Callback */
htim->TriggerCallback = HAL_TIM_TriggerCallback;
break;
case HAL_TIM_TRIGGER_HALF_CB_ID :
/* Legacy weak Trigger half complete Callback */
htim->TriggerHalfCpltCallback = HAL_TIM_TriggerHalfCpltCallback;
break;
case HAL_TIM_IC_CAPTURE_CB_ID :
/* Legacy weak IC Capture Callback */
htim->IC_CaptureCallback = HAL_TIM_IC_CaptureCallback;
break;
case HAL_TIM_IC_CAPTURE_HALF_CB_ID :
/* Legacy weak IC Capture half complete Callback */
htim->IC_CaptureHalfCpltCallback = HAL_TIM_IC_CaptureHalfCpltCallback;
break;
case HAL_TIM_OC_DELAY_ELAPSED_CB_ID :
/* Legacy weak OC Delay Elapsed Callback */
htim->OC_DelayElapsedCallback = HAL_TIM_OC_DelayElapsedCallback;
break;
case HAL_TIM_PWM_PULSE_FINISHED_CB_ID :
/* Legacy weak PWM Pulse Finished Callback */
htim->PWM_PulseFinishedCallback = HAL_TIM_PWM_PulseFinishedCallback;
break;
case HAL_TIM_PWM_PULSE_FINISHED_HALF_CB_ID :
/* Legacy weak PWM Pulse Finished half complete Callback */
htim->PWM_PulseFinishedHalfCpltCallback = HAL_TIM_PWM_PulseFinishedHalfCpltCallback;
break;
case HAL_TIM_ERROR_CB_ID :
/* Legacy weak Error Callback */
htim->ErrorCallback = HAL_TIM_ErrorCallback;
break;
case HAL_TIM_COMMUTATION_CB_ID :
/* Legacy weak Commutation Callback */
htim->CommutationCallback = HAL_TIMEx_CommutCallback;
break;
case HAL_TIM_COMMUTATION_HALF_CB_ID :
/* Legacy weak Commutation half complete Callback */
htim->CommutationHalfCpltCallback = HAL_TIMEx_CommutHalfCpltCallback;
break;
case HAL_TIM_BREAK_CB_ID :
/* Legacy weak Break Callback */
htim->BreakCallback = HAL_TIMEx_BreakCallback;
break;
case HAL_TIM_BREAK2_CB_ID :
/* Legacy weak Break2 Callback */
htim->Break2Callback = HAL_TIMEx_Break2Callback;
break;
case HAL_TIM_ENCODER_INDEX_CB_ID :
/* Legacy weak Encoder Index Callback */
htim->EncoderIndexCallback = HAL_TIMEx_EncoderIndexCallback;
break;
case HAL_TIM_DIRECTION_CHANGE_CB_ID :
/* Legacy weak Direction Change Callback */
htim->DirectionChangeCallback = HAL_TIMEx_DirectionChangeCallback;
break;
case HAL_TIM_INDEX_ERROR_CB_ID :
/* Legacy weak Index Error Callback */
htim->IndexErrorCallback = HAL_TIMEx_IndexErrorCallback;
break;
case HAL_TIM_TRANSITION_ERROR_CB_ID :
/* Legacy weak Transition Error Callback */
htim->TransitionErrorCallback = HAL_TIMEx_TransitionErrorCallback;
break;
default :
/* Return error status */
status = HAL_ERROR;
break;
}
}
else if (htim->State == HAL_TIM_STATE_RESET)
{
switch (CallbackID)
{
case HAL_TIM_BASE_MSPINIT_CB_ID :
/* Legacy weak Base MspInit Callback */
htim->Base_MspInitCallback = HAL_TIM_Base_MspInit;
break;
case HAL_TIM_BASE_MSPDEINIT_CB_ID :
/* Legacy weak Base Msp DeInit Callback */
htim->Base_MspDeInitCallback = HAL_TIM_Base_MspDeInit;
break;
case HAL_TIM_IC_MSPINIT_CB_ID :
/* Legacy weak IC Msp Init Callback */
htim->IC_MspInitCallback = HAL_TIM_IC_MspInit;
break;
case HAL_TIM_IC_MSPDEINIT_CB_ID :
/* Legacy weak IC Msp DeInit Callback */
htim->IC_MspDeInitCallback = HAL_TIM_IC_MspDeInit;
break;
case HAL_TIM_OC_MSPINIT_CB_ID :
/* Legacy weak OC Msp Init Callback */
htim->OC_MspInitCallback = HAL_TIM_OC_MspInit;
break;
case HAL_TIM_OC_MSPDEINIT_CB_ID :
/* Legacy weak OC Msp DeInit Callback */
htim->OC_MspDeInitCallback = HAL_TIM_OC_MspDeInit;
break;
case HAL_TIM_PWM_MSPINIT_CB_ID :
/* Legacy weak PWM Msp Init Callback */
htim->PWM_MspInitCallback = HAL_TIM_PWM_MspInit;
break;
case HAL_TIM_PWM_MSPDEINIT_CB_ID :
/* Legacy weak PWM Msp DeInit Callback */
htim->PWM_MspDeInitCallback = HAL_TIM_PWM_MspDeInit;
break;
case HAL_TIM_ONE_PULSE_MSPINIT_CB_ID :
/* Legacy weak One Pulse Msp Init Callback */
htim->OnePulse_MspInitCallback = HAL_TIM_OnePulse_MspInit;
break;
case HAL_TIM_ONE_PULSE_MSPDEINIT_CB_ID :
/* Legacy weak One Pulse Msp DeInit Callback */
htim->OnePulse_MspDeInitCallback = HAL_TIM_OnePulse_MspDeInit;
break;
case HAL_TIM_ENCODER_MSPINIT_CB_ID :
/* Legacy weak Encoder Msp Init Callback */
htim->Encoder_MspInitCallback = HAL_TIM_Encoder_MspInit;
break;
case HAL_TIM_ENCODER_MSPDEINIT_CB_ID :
/* Legacy weak Encoder Msp DeInit Callback */
htim->Encoder_MspDeInitCallback = HAL_TIM_Encoder_MspDeInit;
break;
case HAL_TIM_HALL_SENSOR_MSPINIT_CB_ID :
/* Legacy weak Hall Sensor Msp Init Callback */
htim->HallSensor_MspInitCallback = HAL_TIMEx_HallSensor_MspInit;
break;
case HAL_TIM_HALL_SENSOR_MSPDEINIT_CB_ID :
/* Legacy weak Hall Sensor Msp DeInit Callback */
htim->HallSensor_MspDeInitCallback = HAL_TIMEx_HallSensor_MspDeInit;
break;
default :
/* Return error status */
status = HAL_ERROR;
break;
}
}
else
{
/* Return error status */
status = HAL_ERROR;
}
return status;
}
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group10 TIM Peripheral State functions
* @brief TIM Peripheral State functions
*
@verbatim
==============================================================================
##### Peripheral State functions #####
==============================================================================
[..]
This subsection permits to get in run-time the status of the peripheral
and the data flow.
@endverbatim
* @{
*/
/**
* @brief Return the TIM Base handle state.
* @param htim TIM Base handle
* @retval HAL state
*/
HAL_TIM_StateTypeDef HAL_TIM_Base_GetState(const TIM_HandleTypeDef *htim)
{
return htim->State;
}
/**
* @brief Return the TIM OC handle state.
* @param htim TIM Output Compare handle
* @retval HAL state
*/
HAL_TIM_StateTypeDef HAL_TIM_OC_GetState(const TIM_HandleTypeDef *htim)
{
return htim->State;
}
/**
* @brief Return the TIM PWM handle state.
* @param htim TIM handle
* @retval HAL state
*/
HAL_TIM_StateTypeDef HAL_TIM_PWM_GetState(const TIM_HandleTypeDef *htim)
{
return htim->State;
}
/**
* @brief Return the TIM Input Capture handle state.
* @param htim TIM IC handle
* @retval HAL state
*/
HAL_TIM_StateTypeDef HAL_TIM_IC_GetState(const TIM_HandleTypeDef *htim)
{
return htim->State;
}
/**
* @brief Return the TIM One Pulse Mode handle state.
* @param htim TIM OPM handle
* @retval HAL state
*/
HAL_TIM_StateTypeDef HAL_TIM_OnePulse_GetState(const TIM_HandleTypeDef *htim)
{
return htim->State;
}
/**
* @brief Return the TIM Encoder Mode handle state.
* @param htim TIM Encoder Interface handle
* @retval HAL state
*/
HAL_TIM_StateTypeDef HAL_TIM_Encoder_GetState(const TIM_HandleTypeDef *htim)
{
return htim->State;
}
/**
* @brief Return the TIM Encoder Mode handle state.
* @param htim TIM handle
* @retval Active channel
*/
HAL_TIM_ActiveChannel HAL_TIM_GetActiveChannel(const TIM_HandleTypeDef *htim)
{
return htim->Channel;
}
/**
* @brief Return actual state of the TIM channel.
* @param htim TIM handle
* @param Channel TIM Channel
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1
* @arg TIM_CHANNEL_2: TIM Channel 2
* @arg TIM_CHANNEL_3: TIM Channel 3
* @arg TIM_CHANNEL_4: TIM Channel 4
* @arg TIM_CHANNEL_5: TIM Channel 5
* @arg TIM_CHANNEL_6: TIM Channel 6
* @retval TIM Channel state
*/
HAL_TIM_ChannelStateTypeDef HAL_TIM_GetChannelState(const TIM_HandleTypeDef *htim, uint32_t Channel)
{
HAL_TIM_ChannelStateTypeDef channel_state;
/* Check the parameters */
assert_param(IS_TIM_CCX_INSTANCE(htim->Instance, Channel));
channel_state = TIM_CHANNEL_STATE_GET(htim, Channel);
return channel_state;
}
/**
* @brief Return actual state of a DMA burst operation.
* @param htim TIM handle
* @retval DMA burst state
*/
HAL_TIM_DMABurstStateTypeDef HAL_TIM_DMABurstState(const TIM_HandleTypeDef *htim)
{
/* Check the parameters */
assert_param(IS_TIM_DMABURST_INSTANCE(htim->Instance));
return htim->DMABurstState;
}
/**
* @}
*/
/**
* @}
*/
/** @defgroup TIM_Private_Functions TIM Private Functions
* @{
*/
/**
* @brief TIM DMA error callback
* @param hdma pointer to DMA handle.
* @retval None
*/
void TIM_DMAError(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (hdma == htim->hdma[TIM_DMA_ID_CC1])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC2])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC3])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_3, HAL_TIM_CHANNEL_STATE_READY);
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC4])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_4, HAL_TIM_CHANNEL_STATE_READY);
}
else
{
htim->State = HAL_TIM_STATE_READY;
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->ErrorCallback(htim);
#else
HAL_TIM_ErrorCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
/**
* @brief TIM DMA Delay Pulse complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
static void TIM_DMADelayPulseCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (hdma == htim->hdma[TIM_DMA_ID_CC1])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC2])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC3])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_3, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC4])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_4, HAL_TIM_CHANNEL_STATE_READY);
}
}
else
{
/* nothing to do */
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->PWM_PulseFinishedCallback(htim);
#else
HAL_TIM_PWM_PulseFinishedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
/**
* @brief TIM DMA Delay Pulse half complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
void TIM_DMADelayPulseHalfCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (hdma == htim->hdma[TIM_DMA_ID_CC1])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC2])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC3])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC4])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
}
else
{
/* nothing to do */
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->PWM_PulseFinishedHalfCpltCallback(htim);
#else
HAL_TIM_PWM_PulseFinishedHalfCpltCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
/**
* @brief TIM DMA Capture complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
void TIM_DMACaptureCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (hdma == htim->hdma[TIM_DMA_ID_CC1])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_1, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC2])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_2, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC3])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_3, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_3, HAL_TIM_CHANNEL_STATE_READY);
}
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC4])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
if (hdma->Init.Mode == DMA_NORMAL)
{
TIM_CHANNEL_STATE_SET(htim, TIM_CHANNEL_4, HAL_TIM_CHANNEL_STATE_READY);
TIM_CHANNEL_N_STATE_SET(htim, TIM_CHANNEL_4, HAL_TIM_CHANNEL_STATE_READY);
}
}
else
{
/* nothing to do */
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->IC_CaptureCallback(htim);
#else
HAL_TIM_IC_CaptureCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
/**
* @brief TIM DMA Capture half complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
void TIM_DMACaptureHalfCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (hdma == htim->hdma[TIM_DMA_ID_CC1])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_1;
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC2])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_2;
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC3])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_3;
}
else if (hdma == htim->hdma[TIM_DMA_ID_CC4])
{
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_4;
}
else
{
/* nothing to do */
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->IC_CaptureHalfCpltCallback(htim);
#else
HAL_TIM_IC_CaptureHalfCpltCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
htim->Channel = HAL_TIM_ACTIVE_CHANNEL_CLEARED;
}
/**
* @brief TIM DMA Period Elapse complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
static void TIM_DMAPeriodElapsedCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (htim->hdma[TIM_DMA_ID_UPDATE]->Init.Mode == DMA_NORMAL)
{
htim->State = HAL_TIM_STATE_READY;
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->PeriodElapsedCallback(htim);
#else
HAL_TIM_PeriodElapsedCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/**
* @brief TIM DMA Period Elapse half complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
static void TIM_DMAPeriodElapsedHalfCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->PeriodElapsedHalfCpltCallback(htim);
#else
HAL_TIM_PeriodElapsedHalfCpltCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/**
* @brief TIM DMA Trigger callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
static void TIM_DMATriggerCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
if (htim->hdma[TIM_DMA_ID_TRIGGER]->Init.Mode == DMA_NORMAL)
{
htim->State = HAL_TIM_STATE_READY;
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->TriggerCallback(htim);
#else
HAL_TIM_TriggerCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/**
* @brief TIM DMA Trigger half complete callback.
* @param hdma pointer to DMA handle.
* @retval None
*/
static void TIM_DMATriggerHalfCplt(DMA_HandleTypeDef *hdma)
{
TIM_HandleTypeDef *htim = (TIM_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
htim->TriggerHalfCpltCallback(htim);
#else
HAL_TIM_TriggerHalfCpltCallback(htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
}
/**
* @brief Time Base configuration
* @param TIMx TIM peripheral
* @param Structure TIM Base configuration structure
* @retval None
*/
void TIM_Base_SetConfig(TIM_TypeDef *TIMx, const TIM_Base_InitTypeDef *Structure)
{
uint32_t tmpcr1;
tmpcr1 = TIMx->CR1;
/* Set TIM Time Base Unit parameters ---------------------------------------*/
if (IS_TIM_COUNTER_MODE_SELECT_INSTANCE(TIMx))
{
/* Select the Counter Mode */
tmpcr1 &= ~(TIM_CR1_DIR | TIM_CR1_CMS);
tmpcr1 |= Structure->CounterMode;
}
if (IS_TIM_CLOCK_DIVISION_INSTANCE(TIMx))
{
/* Set the clock division */
tmpcr1 &= ~TIM_CR1_CKD;
tmpcr1 |= (uint32_t)Structure->ClockDivision;
}
/* Set the auto-reload preload */
MODIFY_REG(tmpcr1, TIM_CR1_ARPE, Structure->AutoReloadPreload);
TIMx->CR1 = tmpcr1;
/* Set the Autoreload value */
TIMx->ARR = (uint32_t)Structure->Period ;
/* Set the Prescaler value */
TIMx->PSC = Structure->Prescaler;
if (IS_TIM_REPETITION_COUNTER_INSTANCE(TIMx))
{
/* Set the Repetition Counter value */
TIMx->RCR = Structure->RepetitionCounter;
}
/* Generate an update event to reload the Prescaler
and the repetition counter (only for advanced timer) value immediately */
TIMx->EGR = TIM_EGR_UG;
/* Check if the update flag is set after the Update Generation, if so clear the UIF flag */
if (HAL_IS_BIT_SET(TIMx->SR, TIM_FLAG_UPDATE))
{
/* Clear the update flag */
CLEAR_BIT(TIMx->SR, TIM_FLAG_UPDATE);
}
}
/**
* @brief Timer Output Compare 1 configuration
* @param TIMx to select the TIM peripheral
* @param OC_Config The output configuration structure
* @retval None
*/
static void TIM_OC1_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config)
{
uint32_t tmpccmrx;
uint32_t tmpccer;
uint32_t tmpcr2;
/* Get the TIMx CCER register value */
tmpccer = TIMx->CCER;
/* Disable the Channel 1: Reset the CC1E Bit */
TIMx->CCER &= ~TIM_CCER_CC1E;
/* Get the TIMx CR2 register value */
tmpcr2 = TIMx->CR2;
/* Get the TIMx CCMR1 register value */
tmpccmrx = TIMx->CCMR1;
/* Reset the Output Compare Mode Bits */
tmpccmrx &= ~TIM_CCMR1_OC1M;
tmpccmrx &= ~TIM_CCMR1_CC1S;
/* Select the Output Compare Mode */
tmpccmrx |= OC_Config->OCMode;
/* Reset the Output Polarity level */
tmpccer &= ~TIM_CCER_CC1P;
/* Set the Output Compare Polarity */
tmpccer |= OC_Config->OCPolarity;
if (IS_TIM_CCXN_INSTANCE(TIMx, TIM_CHANNEL_1))
{
/* Check parameters */
assert_param(IS_TIM_OCN_POLARITY(OC_Config->OCNPolarity));
/* Reset the Output N Polarity level */
tmpccer &= ~TIM_CCER_CC1NP;
/* Set the Output N Polarity */
tmpccer |= OC_Config->OCNPolarity;
/* Reset the Output N State */
tmpccer &= ~TIM_CCER_CC1NE;
}
if (IS_TIM_BREAK_INSTANCE(TIMx))
{
/* Check parameters */
assert_param(IS_TIM_OCNIDLE_STATE(OC_Config->OCNIdleState));
assert_param(IS_TIM_OCIDLE_STATE(OC_Config->OCIdleState));
/* Reset the Output Compare and Output Compare N IDLE State */
tmpcr2 &= ~TIM_CR2_OIS1;
tmpcr2 &= ~TIM_CR2_OIS1N;
/* Set the Output Idle state */
tmpcr2 |= OC_Config->OCIdleState;
/* Set the Output N Idle state */
tmpcr2 |= OC_Config->OCNIdleState;
}
/* Write to TIMx CR2 */
TIMx->CR2 = tmpcr2;
/* Write to TIMx CCMR1 */
TIMx->CCMR1 = tmpccmrx;
/* Set the Capture Compare Register value */
TIMx->CCR1 = OC_Config->Pulse;
/* Write to TIMx CCER */
TIMx->CCER = tmpccer;
}
/**
* @brief Timer Output Compare 2 configuration
* @param TIMx to select the TIM peripheral
* @param OC_Config The output configuration structure
* @retval None
*/
void TIM_OC2_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config)
{
uint32_t tmpccmrx;
uint32_t tmpccer;
uint32_t tmpcr2;
/* Get the TIMx CCER register value */
tmpccer = TIMx->CCER;
/* Disable the Channel 2: Reset the CC2E Bit */
TIMx->CCER &= ~TIM_CCER_CC2E;
/* Get the TIMx CR2 register value */
tmpcr2 = TIMx->CR2;
/* Get the TIMx CCMR1 register value */
tmpccmrx = TIMx->CCMR1;
/* Reset the Output Compare mode and Capture/Compare selection Bits */
tmpccmrx &= ~TIM_CCMR1_OC2M;
tmpccmrx &= ~TIM_CCMR1_CC2S;
/* Select the Output Compare Mode */
tmpccmrx |= (OC_Config->OCMode << 8U);
/* Reset the Output Polarity level */
tmpccer &= ~TIM_CCER_CC2P;
/* Set the Output Compare Polarity */
tmpccer |= (OC_Config->OCPolarity << 4U);
if (IS_TIM_CCXN_INSTANCE(TIMx, TIM_CHANNEL_2))
{
assert_param(IS_TIM_OCN_POLARITY(OC_Config->OCNPolarity));
/* Reset the Output N Polarity level */
tmpccer &= ~TIM_CCER_CC2NP;
/* Set the Output N Polarity */
tmpccer |= (OC_Config->OCNPolarity << 4U);
/* Reset the Output N State */
tmpccer &= ~TIM_CCER_CC2NE;
}
if (IS_TIM_BREAK_INSTANCE(TIMx))
{
/* Check parameters */
assert_param(IS_TIM_OCNIDLE_STATE(OC_Config->OCNIdleState));
assert_param(IS_TIM_OCIDLE_STATE(OC_Config->OCIdleState));
/* Reset the Output Compare and Output Compare N IDLE State */
tmpcr2 &= ~TIM_CR2_OIS2;
tmpcr2 &= ~TIM_CR2_OIS2N;
/* Set the Output Idle state */
tmpcr2 |= (OC_Config->OCIdleState << 2U);
/* Set the Output N Idle state */
tmpcr2 |= (OC_Config->OCNIdleState << 2U);
}
/* Write to TIMx CR2 */
TIMx->CR2 = tmpcr2;
/* Write to TIMx CCMR1 */
TIMx->CCMR1 = tmpccmrx;
/* Set the Capture Compare Register value */
TIMx->CCR2 = OC_Config->Pulse;
/* Write to TIMx CCER */
TIMx->CCER = tmpccer;
}
/**
* @brief Timer Output Compare 3 configuration
* @param TIMx to select the TIM peripheral
* @param OC_Config The output configuration structure
* @retval None
*/
static void TIM_OC3_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config)
{
uint32_t tmpccmrx;
uint32_t tmpccer;
uint32_t tmpcr2;
/* Get the TIMx CCER register value */
tmpccer = TIMx->CCER;
/* Disable the Channel 3: Reset the CC2E Bit */
TIMx->CCER &= ~TIM_CCER_CC3E;
/* Get the TIMx CR2 register value */
tmpcr2 = TIMx->CR2;
/* Get the TIMx CCMR2 register value */
tmpccmrx = TIMx->CCMR2;
/* Reset the Output Compare mode and Capture/Compare selection Bits */
tmpccmrx &= ~TIM_CCMR2_OC3M;
tmpccmrx &= ~TIM_CCMR2_CC3S;
/* Select the Output Compare Mode */
tmpccmrx |= OC_Config->OCMode;
/* Reset the Output Polarity level */
tmpccer &= ~TIM_CCER_CC3P;
/* Set the Output Compare Polarity */
tmpccer |= (OC_Config->OCPolarity << 8U);
if (IS_TIM_CCXN_INSTANCE(TIMx, TIM_CHANNEL_3))
{
assert_param(IS_TIM_OCN_POLARITY(OC_Config->OCNPolarity));
/* Reset the Output N Polarity level */
tmpccer &= ~TIM_CCER_CC3NP;
/* Set the Output N Polarity */
tmpccer |= (OC_Config->OCNPolarity << 8U);
/* Reset the Output N State */
tmpccer &= ~TIM_CCER_CC3NE;
}
if (IS_TIM_BREAK_INSTANCE(TIMx))
{
/* Check parameters */
assert_param(IS_TIM_OCNIDLE_STATE(OC_Config->OCNIdleState));
assert_param(IS_TIM_OCIDLE_STATE(OC_Config->OCIdleState));
/* Reset the Output Compare and Output Compare N IDLE State */
tmpcr2 &= ~TIM_CR2_OIS3;
tmpcr2 &= ~TIM_CR2_OIS3N;
/* Set the Output Idle state */
tmpcr2 |= (OC_Config->OCIdleState << 4U);
/* Set the Output N Idle state */
tmpcr2 |= (OC_Config->OCNIdleState << 4U);
}
/* Write to TIMx CR2 */
TIMx->CR2 = tmpcr2;
/* Write to TIMx CCMR2 */
TIMx->CCMR2 = tmpccmrx;
/* Set the Capture Compare Register value */
TIMx->CCR3 = OC_Config->Pulse;
/* Write to TIMx CCER */
TIMx->CCER = tmpccer;
}
/**
* @brief Timer Output Compare 4 configuration
* @param TIMx to select the TIM peripheral
* @param OC_Config The output configuration structure
* @retval None
*/
static void TIM_OC4_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config)
{
uint32_t tmpccmrx;
uint32_t tmpccer;
uint32_t tmpcr2;
/* Get the TIMx CCER register value */
tmpccer = TIMx->CCER;
/* Disable the Channel 4: Reset the CC4E Bit */
TIMx->CCER &= ~TIM_CCER_CC4E;
/* Get the TIMx CR2 register value */
tmpcr2 = TIMx->CR2;
/* Get the TIMx CCMR2 register value */
tmpccmrx = TIMx->CCMR2;
/* Reset the Output Compare mode and Capture/Compare selection Bits */
tmpccmrx &= ~TIM_CCMR2_OC4M;
tmpccmrx &= ~TIM_CCMR2_CC4S;
/* Select the Output Compare Mode */
tmpccmrx |= (OC_Config->OCMode << 8U);
/* Reset the Output Polarity level */
tmpccer &= ~TIM_CCER_CC4P;
/* Set the Output Compare Polarity */
tmpccer |= (OC_Config->OCPolarity << 12U);
if (IS_TIM_CCXN_INSTANCE(TIMx, TIM_CHANNEL_4))
{
assert_param(IS_TIM_OCN_POLARITY(OC_Config->OCNPolarity));
/* Reset the Output N Polarity level */
tmpccer &= ~TIM_CCER_CC4NP;
/* Set the Output N Polarity */
tmpccer |= (OC_Config->OCNPolarity << 12U);
/* Reset the Output N State */
tmpccer &= ~TIM_CCER_CC4NE;
}
if (IS_TIM_BREAK_INSTANCE(TIMx))
{
/* Check parameters */
assert_param(IS_TIM_OCNIDLE_STATE(OC_Config->OCNIdleState));
assert_param(IS_TIM_OCIDLE_STATE(OC_Config->OCIdleState));
/* Reset the Output Compare IDLE State */
tmpcr2 &= ~TIM_CR2_OIS4;
/* Reset the Output Compare N IDLE State */
tmpcr2 &= ~TIM_CR2_OIS4N;
/* Set the Output Idle state */
tmpcr2 |= (OC_Config->OCIdleState << 6U);
/* Set the Output N Idle state */
tmpcr2 |= (OC_Config->OCNIdleState << 6U);
}
/* Write to TIMx CR2 */
TIMx->CR2 = tmpcr2;
/* Write to TIMx CCMR2 */
TIMx->CCMR2 = tmpccmrx;
/* Set the Capture Compare Register value */
TIMx->CCR4 = OC_Config->Pulse;
/* Write to TIMx CCER */
TIMx->CCER = tmpccer;
}
/**
* @brief Timer Output Compare 5 configuration
* @param TIMx to select the TIM peripheral
* @param OC_Config The output configuration structure
* @retval None
*/
static void TIM_OC5_SetConfig(TIM_TypeDef *TIMx,
const TIM_OC_InitTypeDef *OC_Config)
{
uint32_t tmpccmrx;
uint32_t tmpccer;
uint32_t tmpcr2;
/* Get the TIMx CCER register value */
tmpccer = TIMx->CCER;
/* Disable the output: Reset the CCxE Bit */
TIMx->CCER &= ~TIM_CCER_CC5E;
/* Get the TIMx CR2 register value */
tmpcr2 = TIMx->CR2;
/* Get the TIMx CCMR1 register value */
tmpccmrx = TIMx->CCMR3;
/* Reset the Output Compare Mode Bits */
tmpccmrx &= ~(TIM_CCMR3_OC5M);
/* Select the Output Compare Mode */
tmpccmrx |= OC_Config->OCMode;
/* Reset the Output Polarity level */
tmpccer &= ~TIM_CCER_CC5P;
/* Set the Output Compare Polarity */
tmpccer |= (OC_Config->OCPolarity << 16U);
if (IS_TIM_BREAK_INSTANCE(TIMx))
{
/* Reset the Output Compare IDLE State */
tmpcr2 &= ~TIM_CR2_OIS5;
/* Set the Output Idle state */
tmpcr2 |= (OC_Config->OCIdleState << 8U);
}
/* Write to TIMx CR2 */
TIMx->CR2 = tmpcr2;
/* Write to TIMx CCMR3 */
TIMx->CCMR3 = tmpccmrx;
/* Set the Capture Compare Register value */
TIMx->CCR5 = OC_Config->Pulse;
/* Write to TIMx CCER */
TIMx->CCER = tmpccer;
}
/**
* @brief Timer Output Compare 6 configuration
* @param TIMx to select the TIM peripheral
* @param OC_Config The output configuration structure
* @retval None
*/
static void TIM_OC6_SetConfig(TIM_TypeDef *TIMx,
const TIM_OC_InitTypeDef *OC_Config)
{
uint32_t tmpccmrx;
uint32_t tmpccer;
uint32_t tmpcr2;
/* Get the TIMx CCER register value */
tmpccer = TIMx->CCER;
/* Disable the output: Reset the CCxE Bit */
TIMx->CCER &= ~TIM_CCER_CC6E;
/* Get the TIMx CR2 register value */
tmpcr2 = TIMx->CR2;
/* Get the TIMx CCMR1 register value */
tmpccmrx = TIMx->CCMR3;
/* Reset the Output Compare Mode Bits */
tmpccmrx &= ~(TIM_CCMR3_OC6M);
/* Select the Output Compare Mode */
tmpccmrx |= (OC_Config->OCMode << 8U);
/* Reset the Output Polarity level */
tmpccer &= (uint32_t)~TIM_CCER_CC6P;
/* Set the Output Compare Polarity */
tmpccer |= (OC_Config->OCPolarity << 20U);
if (IS_TIM_BREAK_INSTANCE(TIMx))
{
/* Reset the Output Compare IDLE State */
tmpcr2 &= ~TIM_CR2_OIS6;
/* Set the Output Idle state */
tmpcr2 |= (OC_Config->OCIdleState << 10U);
}
/* Write to TIMx CR2 */
TIMx->CR2 = tmpcr2;
/* Write to TIMx CCMR3 */
TIMx->CCMR3 = tmpccmrx;
/* Set the Capture Compare Register value */
TIMx->CCR6 = OC_Config->Pulse;
/* Write to TIMx CCER */
TIMx->CCER = tmpccer;
}
/**
* @brief Slave Timer configuration function
* @param htim TIM handle
* @param sSlaveConfig Slave timer configuration
* @retval None
*/
static HAL_StatusTypeDef TIM_SlaveTimer_SetConfig(TIM_HandleTypeDef *htim,
const TIM_SlaveConfigTypeDef *sSlaveConfig)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t tmpsmcr;
uint32_t tmpccmr1;
uint32_t tmpccer;
/* Get the TIMx SMCR register value */
tmpsmcr = htim->Instance->SMCR;
/* Reset the Trigger Selection Bits */
tmpsmcr &= ~TIM_SMCR_TS;
/* Set the Input Trigger source */
tmpsmcr |= sSlaveConfig->InputTrigger;
/* Reset the slave mode Bits */
tmpsmcr &= ~TIM_SMCR_SMS;
/* Set the slave mode */
tmpsmcr |= sSlaveConfig->SlaveMode;
/* Write to TIMx SMCR */
htim->Instance->SMCR = tmpsmcr;
/* Configure the trigger prescaler, filter, and polarity */
switch (sSlaveConfig->InputTrigger)
{
case TIM_TS_ETRF:
{
/* Check the parameters */
assert_param(IS_TIM_CLOCKSOURCE_ETRMODE1_INSTANCE(htim->Instance));
assert_param(IS_TIM_TRIGGERPRESCALER(sSlaveConfig->TriggerPrescaler));
assert_param(IS_TIM_TRIGGERPOLARITY(sSlaveConfig->TriggerPolarity));
assert_param(IS_TIM_TRIGGERFILTER(sSlaveConfig->TriggerFilter));
/* Configure the ETR Trigger source */
TIM_ETR_SetConfig(htim->Instance,
sSlaveConfig->TriggerPrescaler,
sSlaveConfig->TriggerPolarity,
sSlaveConfig->TriggerFilter);
break;
}
case TIM_TS_TI1F_ED:
{
/* Check the parameters */
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
assert_param(IS_TIM_TRIGGERFILTER(sSlaveConfig->TriggerFilter));
if ((sSlaveConfig->SlaveMode == TIM_SLAVEMODE_GATED) || \
(sSlaveConfig->SlaveMode == TIM_SLAVEMODE_COMBINED_GATEDRESET))
{
return HAL_ERROR;
}
/* Disable the Channel 1: Reset the CC1E Bit */
tmpccer = htim->Instance->CCER;
htim->Instance->CCER &= ~TIM_CCER_CC1E;
tmpccmr1 = htim->Instance->CCMR1;
/* Set the filter */
tmpccmr1 &= ~TIM_CCMR1_IC1F;
tmpccmr1 |= ((sSlaveConfig->TriggerFilter) << 4U);
/* Write to TIMx CCMR1 and CCER registers */
htim->Instance->CCMR1 = tmpccmr1;
htim->Instance->CCER = tmpccer;
break;
}
case TIM_TS_TI1FP1:
{
/* Check the parameters */
assert_param(IS_TIM_CC1_INSTANCE(htim->Instance));
assert_param(IS_TIM_TRIGGERPOLARITY(sSlaveConfig->TriggerPolarity));
assert_param(IS_TIM_TRIGGERFILTER(sSlaveConfig->TriggerFilter));
/* Configure TI1 Filter and Polarity */
TIM_TI1_ConfigInputStage(htim->Instance,
sSlaveConfig->TriggerPolarity,
sSlaveConfig->TriggerFilter);
break;
}
case TIM_TS_TI2FP2:
{
/* Check the parameters */
assert_param(IS_TIM_CC2_INSTANCE(htim->Instance));
assert_param(IS_TIM_TRIGGERPOLARITY(sSlaveConfig->TriggerPolarity));
assert_param(IS_TIM_TRIGGERFILTER(sSlaveConfig->TriggerFilter));
/* Configure TI2 Filter and Polarity */
TIM_TI2_ConfigInputStage(htim->Instance,
sSlaveConfig->TriggerPolarity,
sSlaveConfig->TriggerFilter);
break;
}
case TIM_TS_ITR0:
case TIM_TS_ITR1:
case TIM_TS_ITR2:
case TIM_TS_ITR3:
#if defined (TIM5)
case TIM_TS_ITR4:
#endif /* TIM5 */
case TIM_TS_ITR5:
case TIM_TS_ITR6:
case TIM_TS_ITR7:
case TIM_TS_ITR8:
#if defined (TIM20)
case TIM_TS_ITR9:
#endif /* TIM20 */
#if defined (HRTIM1)
case TIM_TS_ITR10:
#endif /* HRTIM1 */
case TIM_TS_ITR11:
{
/* Check the parameter */
assert_param(IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE((htim->Instance), sSlaveConfig->InputTrigger));
break;
}
default:
status = HAL_ERROR;
break;
}
return status;
}
/**
* @brief Configure the TI1 as Input.
* @param TIMx to select the TIM peripheral.
* @param TIM_ICPolarity The Input Polarity.
* This parameter can be one of the following values:
* @arg TIM_ICPOLARITY_RISING
* @arg TIM_ICPOLARITY_FALLING
* @arg TIM_ICPOLARITY_BOTHEDGE
* @param TIM_ICSelection specifies the input to be used.
* This parameter can be one of the following values:
* @arg TIM_ICSELECTION_DIRECTTI: TIM Input 1 is selected to be connected to IC1.
* @arg TIM_ICSELECTION_INDIRECTTI: TIM Input 1 is selected to be connected to IC2.
* @arg TIM_ICSELECTION_TRC: TIM Input 1 is selected to be connected to TRC.
* @param TIM_ICFilter Specifies the Input Capture Filter.
* This parameter must be a value between 0x00 and 0x0F.
* @retval None
* @note TIM_ICFilter and TIM_ICPolarity are not used in INDIRECT mode as TI2FP1
* (on channel2 path) is used as the input signal. Therefore CCMR1 must be
* protected against un-initialized filter and polarity values.
*/
void TIM_TI1_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection,
uint32_t TIM_ICFilter)
{
uint32_t tmpccmr1;
uint32_t tmpccer;
/* Disable the Channel 1: Reset the CC1E Bit */
tmpccer = TIMx->CCER;
TIMx->CCER &= ~TIM_CCER_CC1E;
tmpccmr1 = TIMx->CCMR1;
/* Select the Input */
if (IS_TIM_CC2_INSTANCE(TIMx) != RESET)
{
tmpccmr1 &= ~TIM_CCMR1_CC1S;
tmpccmr1 |= TIM_ICSelection;
}
else
{
tmpccmr1 |= TIM_CCMR1_CC1S_0;
}
/* Set the filter */
tmpccmr1 &= ~TIM_CCMR1_IC1F;
tmpccmr1 |= ((TIM_ICFilter << 4U) & TIM_CCMR1_IC1F);
/* Select the Polarity and set the CC1E Bit */
tmpccer &= ~(TIM_CCER_CC1P | TIM_CCER_CC1NP);
tmpccer |= (TIM_ICPolarity & (TIM_CCER_CC1P | TIM_CCER_CC1NP));
/* Write to TIMx CCMR1 and CCER registers */
TIMx->CCMR1 = tmpccmr1;
TIMx->CCER = tmpccer;
}
/**
* @brief Configure the Polarity and Filter for TI1.
* @param TIMx to select the TIM peripheral.
* @param TIM_ICPolarity The Input Polarity.
* This parameter can be one of the following values:
* @arg TIM_ICPOLARITY_RISING
* @arg TIM_ICPOLARITY_FALLING
* @arg TIM_ICPOLARITY_BOTHEDGE
* @param TIM_ICFilter Specifies the Input Capture Filter.
* This parameter must be a value between 0x00 and 0x0F.
* @retval None
*/
static void TIM_TI1_ConfigInputStage(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICFilter)
{
uint32_t tmpccmr1;
uint32_t tmpccer;
/* Disable the Channel 1: Reset the CC1E Bit */
tmpccer = TIMx->CCER;
TIMx->CCER &= ~TIM_CCER_CC1E;
tmpccmr1 = TIMx->CCMR1;
/* Set the filter */
tmpccmr1 &= ~TIM_CCMR1_IC1F;
tmpccmr1 |= (TIM_ICFilter << 4U);
/* Select the Polarity and set the CC1E Bit */
tmpccer &= ~(TIM_CCER_CC1P | TIM_CCER_CC1NP);
tmpccer |= TIM_ICPolarity;
/* Write to TIMx CCMR1 and CCER registers */
TIMx->CCMR1 = tmpccmr1;
TIMx->CCER = tmpccer;
}
/**
* @brief Configure the TI2 as Input.
* @param TIMx to select the TIM peripheral
* @param TIM_ICPolarity The Input Polarity.
* This parameter can be one of the following values:
* @arg TIM_ICPOLARITY_RISING
* @arg TIM_ICPOLARITY_FALLING
* @arg TIM_ICPOLARITY_BOTHEDGE
* @param TIM_ICSelection specifies the input to be used.
* This parameter can be one of the following values:
* @arg TIM_ICSELECTION_DIRECTTI: TIM Input 2 is selected to be connected to IC2.
* @arg TIM_ICSELECTION_INDIRECTTI: TIM Input 2 is selected to be connected to IC1.
* @arg TIM_ICSELECTION_TRC: TIM Input 2 is selected to be connected to TRC.
* @param TIM_ICFilter Specifies the Input Capture Filter.
* This parameter must be a value between 0x00 and 0x0F.
* @retval None
* @note TIM_ICFilter and TIM_ICPolarity are not used in INDIRECT mode as TI1FP2
* (on channel1 path) is used as the input signal. Therefore CCMR1 must be
* protected against un-initialized filter and polarity values.
*/
static void TIM_TI2_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection,
uint32_t TIM_ICFilter)
{
uint32_t tmpccmr1;
uint32_t tmpccer;
/* Disable the Channel 2: Reset the CC2E Bit */
tmpccer = TIMx->CCER;
TIMx->CCER &= ~TIM_CCER_CC2E;
tmpccmr1 = TIMx->CCMR1;
/* Select the Input */
tmpccmr1 &= ~TIM_CCMR1_CC2S;
tmpccmr1 |= (TIM_ICSelection << 8U);
/* Set the filter */
tmpccmr1 &= ~TIM_CCMR1_IC2F;
tmpccmr1 |= ((TIM_ICFilter << 12U) & TIM_CCMR1_IC2F);
/* Select the Polarity and set the CC2E Bit */
tmpccer &= ~(TIM_CCER_CC2P | TIM_CCER_CC2NP);
tmpccer |= ((TIM_ICPolarity << 4U) & (TIM_CCER_CC2P | TIM_CCER_CC2NP));
/* Write to TIMx CCMR1 and CCER registers */
TIMx->CCMR1 = tmpccmr1 ;
TIMx->CCER = tmpccer;
}
/**
* @brief Configure the Polarity and Filter for TI2.
* @param TIMx to select the TIM peripheral.
* @param TIM_ICPolarity The Input Polarity.
* This parameter can be one of the following values:
* @arg TIM_ICPOLARITY_RISING
* @arg TIM_ICPOLARITY_FALLING
* @arg TIM_ICPOLARITY_BOTHEDGE
* @param TIM_ICFilter Specifies the Input Capture Filter.
* This parameter must be a value between 0x00 and 0x0F.
* @retval None
*/
static void TIM_TI2_ConfigInputStage(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICFilter)
{
uint32_t tmpccmr1;
uint32_t tmpccer;
/* Disable the Channel 2: Reset the CC2E Bit */
tmpccer = TIMx->CCER;
TIMx->CCER &= ~TIM_CCER_CC2E;
tmpccmr1 = TIMx->CCMR1;
/* Set the filter */
tmpccmr1 &= ~TIM_CCMR1_IC2F;
tmpccmr1 |= (TIM_ICFilter << 12U);
/* Select the Polarity and set the CC2E Bit */
tmpccer &= ~(TIM_CCER_CC2P | TIM_CCER_CC2NP);
tmpccer |= (TIM_ICPolarity << 4U);
/* Write to TIMx CCMR1 and CCER registers */
TIMx->CCMR1 = tmpccmr1 ;
TIMx->CCER = tmpccer;
}
/**
* @brief Configure the TI3 as Input.
* @param TIMx to select the TIM peripheral
* @param TIM_ICPolarity The Input Polarity.
* This parameter can be one of the following values:
* @arg TIM_ICPOLARITY_RISING
* @arg TIM_ICPOLARITY_FALLING
* @arg TIM_ICPOLARITY_BOTHEDGE
* @param TIM_ICSelection specifies the input to be used.
* This parameter can be one of the following values:
* @arg TIM_ICSELECTION_DIRECTTI: TIM Input 3 is selected to be connected to IC3.
* @arg TIM_ICSELECTION_INDIRECTTI: TIM Input 3 is selected to be connected to IC4.
* @arg TIM_ICSELECTION_TRC: TIM Input 3 is selected to be connected to TRC.
* @param TIM_ICFilter Specifies the Input Capture Filter.
* This parameter must be a value between 0x00 and 0x0F.
* @retval None
* @note TIM_ICFilter and TIM_ICPolarity are not used in INDIRECT mode as TI3FP4
* (on channel1 path) is used as the input signal. Therefore CCMR2 must be
* protected against un-initialized filter and polarity values.
*/
static void TIM_TI3_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection,
uint32_t TIM_ICFilter)
{
uint32_t tmpccmr2;
uint32_t tmpccer;
/* Disable the Channel 3: Reset the CC3E Bit */
tmpccer = TIMx->CCER;
TIMx->CCER &= ~TIM_CCER_CC3E;
tmpccmr2 = TIMx->CCMR2;
/* Select the Input */
tmpccmr2 &= ~TIM_CCMR2_CC3S;
tmpccmr2 |= TIM_ICSelection;
/* Set the filter */
tmpccmr2 &= ~TIM_CCMR2_IC3F;
tmpccmr2 |= ((TIM_ICFilter << 4U) & TIM_CCMR2_IC3F);
/* Select the Polarity and set the CC3E Bit */
tmpccer &= ~(TIM_CCER_CC3P | TIM_CCER_CC3NP);
tmpccer |= ((TIM_ICPolarity << 8U) & (TIM_CCER_CC3P | TIM_CCER_CC3NP));
/* Write to TIMx CCMR2 and CCER registers */
TIMx->CCMR2 = tmpccmr2;
TIMx->CCER = tmpccer;
}
/**
* @brief Configure the TI4 as Input.
* @param TIMx to select the TIM peripheral
* @param TIM_ICPolarity The Input Polarity.
* This parameter can be one of the following values:
* @arg TIM_ICPOLARITY_RISING
* @arg TIM_ICPOLARITY_FALLING
* @arg TIM_ICPOLARITY_BOTHEDGE
* @param TIM_ICSelection specifies the input to be used.
* This parameter can be one of the following values:
* @arg TIM_ICSELECTION_DIRECTTI: TIM Input 4 is selected to be connected to IC4.
* @arg TIM_ICSELECTION_INDIRECTTI: TIM Input 4 is selected to be connected to IC3.
* @arg TIM_ICSELECTION_TRC: TIM Input 4 is selected to be connected to TRC.
* @param TIM_ICFilter Specifies the Input Capture Filter.
* This parameter must be a value between 0x00 and 0x0F.
* @note TIM_ICFilter and TIM_ICPolarity are not used in INDIRECT mode as TI4FP3
* (on channel1 path) is used as the input signal. Therefore CCMR2 must be
* protected against un-initialized filter and polarity values.
* @retval None
*/
static void TIM_TI4_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection,
uint32_t TIM_ICFilter)
{
uint32_t tmpccmr2;
uint32_t tmpccer;
/* Disable the Channel 4: Reset the CC4E Bit */
tmpccer = TIMx->CCER;
TIMx->CCER &= ~TIM_CCER_CC4E;
tmpccmr2 = TIMx->CCMR2;
/* Select the Input */
tmpccmr2 &= ~TIM_CCMR2_CC4S;
tmpccmr2 |= (TIM_ICSelection << 8U);
/* Set the filter */
tmpccmr2 &= ~TIM_CCMR2_IC4F;
tmpccmr2 |= ((TIM_ICFilter << 12U) & TIM_CCMR2_IC4F);
/* Select the Polarity and set the CC4E Bit */
tmpccer &= ~(TIM_CCER_CC4P | TIM_CCER_CC4NP);
tmpccer |= ((TIM_ICPolarity << 12U) & (TIM_CCER_CC4P | TIM_CCER_CC4NP));
/* Write to TIMx CCMR2 and CCER registers */
TIMx->CCMR2 = tmpccmr2;
TIMx->CCER = tmpccer ;
}
/**
* @brief Selects the Input Trigger source
* @param TIMx to select the TIM peripheral
* @param InputTriggerSource The Input Trigger source.
* This parameter can be one of the following values:
* @arg TIM_TS_ITR0: Internal Trigger 0
* @arg TIM_TS_ITR1: Internal Trigger 1
* @arg TIM_TS_ITR2: Internal Trigger 2
* @arg TIM_TS_ITR3: Internal Trigger 3
* @arg TIM_TS_ITR4: Internal Trigger 4 (*)
* @arg TIM_TS_ITR5: Internal Trigger 5
* @arg TIM_TS_ITR6: Internal Trigger 6
* @arg TIM_TS_ITR7: Internal Trigger 7
* @arg TIM_TS_ITR8: Internal Trigger 8
* @arg TIM_TS_ITR9: Internal Trigger 9 (*)
* @arg TIM_TS_ITR10: Internal Trigger 10
* @arg TIM_TS_ITR11: Internal Trigger 11
* @arg TIM_TS_TI1F_ED: TI1 Edge Detector
* @arg TIM_TS_TI1FP1: Filtered Timer Input 1
* @arg TIM_TS_TI2FP2: Filtered Timer Input 2
* @arg TIM_TS_ETRF: External Trigger input
*
* (*) Value not defined in all devices.
*
* @retval None
*/
static void TIM_ITRx_SetConfig(TIM_TypeDef *TIMx, uint32_t InputTriggerSource)
{
uint32_t tmpsmcr;
/* Get the TIMx SMCR register value */
tmpsmcr = TIMx->SMCR;
/* Reset the TS Bits */
tmpsmcr &= ~TIM_SMCR_TS;
/* Set the Input Trigger source and the slave mode*/
tmpsmcr |= (InputTriggerSource | TIM_SLAVEMODE_EXTERNAL1);
/* Write to TIMx SMCR */
TIMx->SMCR = tmpsmcr;
}
/**
* @brief Configures the TIMx External Trigger (ETR).
* @param TIMx to select the TIM peripheral
* @param TIM_ExtTRGPrescaler The external Trigger Prescaler.
* This parameter can be one of the following values:
* @arg TIM_ETRPRESCALER_DIV1: ETRP Prescaler OFF.
* @arg TIM_ETRPRESCALER_DIV2: ETRP frequency divided by 2.
* @arg TIM_ETRPRESCALER_DIV4: ETRP frequency divided by 4.
* @arg TIM_ETRPRESCALER_DIV8: ETRP frequency divided by 8.
* @param TIM_ExtTRGPolarity The external Trigger Polarity.
* This parameter can be one of the following values:
* @arg TIM_ETRPOLARITY_INVERTED: active low or falling edge active.
* @arg TIM_ETRPOLARITY_NONINVERTED: active high or rising edge active.
* @param ExtTRGFilter External Trigger Filter.
* This parameter must be a value between 0x00 and 0x0F
* @retval None
*/
void TIM_ETR_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ExtTRGPrescaler,
uint32_t TIM_ExtTRGPolarity, uint32_t ExtTRGFilter)
{
uint32_t tmpsmcr;
tmpsmcr = TIMx->SMCR;
/* Reset the ETR Bits */
tmpsmcr &= ~(TIM_SMCR_ETF | TIM_SMCR_ETPS | TIM_SMCR_ECE | TIM_SMCR_ETP);
/* Set the Prescaler, the Filter value and the Polarity */
tmpsmcr |= (uint32_t)(TIM_ExtTRGPrescaler | (TIM_ExtTRGPolarity | (ExtTRGFilter << 8U)));
/* Write to TIMx SMCR */
TIMx->SMCR = tmpsmcr;
}
/**
* @brief Enables or disables the TIM Capture Compare Channel x.
* @param TIMx to select the TIM peripheral
* @param Channel specifies the TIM Channel
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1
* @arg TIM_CHANNEL_2: TIM Channel 2
* @arg TIM_CHANNEL_3: TIM Channel 3
* @arg TIM_CHANNEL_4: TIM Channel 4
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @param ChannelState specifies the TIM Channel CCxE bit new state.
* This parameter can be: TIM_CCx_ENABLE or TIM_CCx_DISABLE.
* @retval None
*/
void TIM_CCxChannelCmd(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ChannelState)
{
uint32_t tmp;
/* Check the parameters */
assert_param(IS_TIM_CC1_INSTANCE(TIMx));
assert_param(IS_TIM_CHANNELS(Channel));
tmp = TIM_CCER_CC1E << (Channel & 0x1FU); /* 0x1FU = 31 bits max shift */
/* Reset the CCxE Bit */
TIMx->CCER &= ~tmp;
/* Set or reset the CCxE Bit */
TIMx->CCER |= (uint32_t)(ChannelState << (Channel & 0x1FU)); /* 0x1FU = 31 bits max shift */
}
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/**
* @brief Reset interrupt callbacks to the legacy weak callbacks.
* @param htim pointer to a TIM_HandleTypeDef structure that contains
* the configuration information for TIM module.
* @retval None
*/
void TIM_ResetCallback(TIM_HandleTypeDef *htim)
{
/* Reset the TIM callback to the legacy weak callbacks */
htim->PeriodElapsedCallback = HAL_TIM_PeriodElapsedCallback;
htim->PeriodElapsedHalfCpltCallback = HAL_TIM_PeriodElapsedHalfCpltCallback;
htim->TriggerCallback = HAL_TIM_TriggerCallback;
htim->TriggerHalfCpltCallback = HAL_TIM_TriggerHalfCpltCallback;
htim->IC_CaptureCallback = HAL_TIM_IC_CaptureCallback;
htim->IC_CaptureHalfCpltCallback = HAL_TIM_IC_CaptureHalfCpltCallback;
htim->OC_DelayElapsedCallback = HAL_TIM_OC_DelayElapsedCallback;
htim->PWM_PulseFinishedCallback = HAL_TIM_PWM_PulseFinishedCallback;
htim->PWM_PulseFinishedHalfCpltCallback = HAL_TIM_PWM_PulseFinishedHalfCpltCallback;
htim->ErrorCallback = HAL_TIM_ErrorCallback;
htim->CommutationCallback = HAL_TIMEx_CommutCallback;
htim->CommutationHalfCpltCallback = HAL_TIMEx_CommutHalfCpltCallback;
htim->BreakCallback = HAL_TIMEx_BreakCallback;
htim->Break2Callback = HAL_TIMEx_Break2Callback;
htim->EncoderIndexCallback = HAL_TIMEx_EncoderIndexCallback;
htim->DirectionChangeCallback = HAL_TIMEx_DirectionChangeCallback;
htim->IndexErrorCallback = HAL_TIMEx_IndexErrorCallback;
htim->TransitionErrorCallback = HAL_TIMEx_TransitionErrorCallback;
}
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/**
* @}
*/
#endif /* HAL_TIM_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 260,401 | C | 31.057368 | 120 | 0.627187 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal.c | /**
******************************************************************************
* @file stm32g4xx_hal.c
* @author MCD Application Team
* @brief HAL module driver.
* This is the common part of the HAL initialization
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
The common HAL driver contains a set of generic and common APIs that can be
used by the PPP peripheral drivers and the user to start using the HAL.
[..]
The HAL contains two APIs' categories:
(+) Common HAL APIs
(+) Services HAL APIs
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup HAL HAL
* @brief HAL module driver
* @{
*/
#ifdef HAL_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/**
* @brief STM32G4xx HAL Driver version number V1.2.3
*/
#define __STM32G4xx_HAL_VERSION_MAIN (0x01U) /*!< [31:24] main version */
#define __STM32G4xx_HAL_VERSION_SUB1 (0x02U) /*!< [23:16] sub1 version */
#define __STM32G4xx_HAL_VERSION_SUB2 (0x03U) /*!< [15:8] sub2 version */
#define __STM32G4xx_HAL_VERSION_RC (0x00U) /*!< [7:0] release candidate */
#define __STM32G4xx_HAL_VERSION ((__STM32G4xx_HAL_VERSION_MAIN << 24U)\
|(__STM32G4xx_HAL_VERSION_SUB1 << 16U)\
|(__STM32G4xx_HAL_VERSION_SUB2 << 8U )\
|(__STM32G4xx_HAL_VERSION_RC))
#if defined(VREFBUF)
#define VREFBUF_TIMEOUT_VALUE 10U /* 10 ms */
#endif /* VREFBUF */
/* ------------ SYSCFG registers bit address in the alias region ------------ */
#define SYSCFG_OFFSET (SYSCFG_BASE - PERIPH_BASE)
/* --- MEMRMP Register ---*/
/* Alias word address of FB_MODE bit */
#define MEMRMP_OFFSET SYSCFG_OFFSET
#define FB_MODE_BitNumber ((uint8_t)0x8)
#define FB_MODE_BB (PERIPH_BB_BASE + (MEMRMP_OFFSET * 32) + (FB_MODE_BitNumber * 4))
/* --- GPC Register ---*/
/* Alias word address of CCMER bit */
#define SCSR_OFFSET (SYSCFG_OFFSET + 0x18)
#define CCMER_BitNumber ((uint8_t)0x0)
#define SCSR_CCMER_BB (PERIPH_BB_BASE + (SCSR_OFFSET * 32) + (CCMER_BitNumber * 4))
/* Private macro -------------------------------------------------------------*/
/* Exported variables ---------------------------------------------------------*/
/** @defgroup HAL_Exported_Variables HAL Exported Variables
* @{
*/
__IO uint32_t uwTick;
uint32_t uwTickPrio = (1UL << __NVIC_PRIO_BITS); /* Invalid PRIO */
uint32_t uwTickFreq = HAL_TICK_FREQ_DEFAULT; /* 1KHz */
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup HAL_Exported_Functions HAL Exported Functions
* @{
*/
/** @defgroup HAL_Exported_Functions_Group1 Initialization and de-initialization Functions
* @brief HAL Initialization and de-initialization functions
*
@verbatim
===============================================================================
##### Initialization and Configuration functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Initialize the Flash interface the NVIC allocation and initial time base
clock configuration.
(+) De-Initialize common part of the HAL.
(+) Configure the time base source to have 1ms time base with a dedicated
Tick interrupt priority.
(++) SysTick timer is used by default as source of time base, but user
can eventually implement his proper time base source (a general purpose
timer for example or other time source), keeping in mind that Time base
duration should be kept 1ms since PPP_TIMEOUT_VALUEs are defined and
handled in milliseconds basis.
(++) Time base configuration function (HAL_InitTick ()) is called automatically
at the beginning of the program after reset by HAL_Init() or at any time
when clock is configured, by HAL_RCC_ClockConfig().
(++) Source of time base is configured to generate interrupts at regular
time intervals. Care must be taken if HAL_Delay() is called from a
peripheral ISR process, the Tick interrupt line must have higher priority
(numerically lower) than the peripheral interrupt. Otherwise the caller
ISR process will be blocked.
(++) functions affecting time base configurations are declared as __weak
to make override possible in case of other implementations in user file.
@endverbatim
* @{
*/
/**
* @brief This function is used to configure the Flash prefetch, the Instruction and Data caches,
* the time base source, NVIC and any required global low level hardware
* by calling the HAL_MspInit() callback function to be optionally defined in user file
* stm32g4xx_hal_msp.c.
*
* @note HAL_Init() function is called at the beginning of program after reset and before
* the clock configuration.
*
* @note In the default implementation the System Timer (Systick) is used as source of time base.
* The Systick configuration is based on HSI clock, as HSI is the clock
* used after a system Reset and the NVIC configuration is set to Priority group 4.
* Once done, time base tick starts incrementing: the tick variable counter is incremented
* each 1ms in the SysTick_Handler() interrupt handler.
*
* @retval HAL status
*/
HAL_StatusTypeDef HAL_Init(void)
{
HAL_StatusTypeDef status = HAL_OK;
/* Configure Flash prefetch, Instruction cache, Data cache */
/* Default configuration at reset is: */
/* - Prefetch disabled */
/* - Instruction cache enabled */
/* - Data cache enabled */
#if (INSTRUCTION_CACHE_ENABLE == 0U)
__HAL_FLASH_INSTRUCTION_CACHE_DISABLE();
#endif /* INSTRUCTION_CACHE_ENABLE */
#if (DATA_CACHE_ENABLE == 0U)
__HAL_FLASH_DATA_CACHE_DISABLE();
#endif /* DATA_CACHE_ENABLE */
#if (PREFETCH_ENABLE != 0U)
__HAL_FLASH_PREFETCH_BUFFER_ENABLE();
#endif /* PREFETCH_ENABLE */
/* Set Interrupt Group Priority */
HAL_NVIC_SetPriorityGrouping(NVIC_PRIORITYGROUP_4);
/* Use SysTick as time base source and configure 1ms tick (default clock after Reset is HSI) */
if (HAL_InitTick(TICK_INT_PRIORITY) != HAL_OK)
{
status = HAL_ERROR;
}
else
{
/* Init the low level hardware */
HAL_MspInit();
}
/* Return function status */
return status;
}
/**
* @brief This function de-initializes common part of the HAL and stops the source of time base.
* @note This function is optional.
* @retval HAL status
*/
HAL_StatusTypeDef HAL_DeInit(void)
{
/* Reset of all peripherals */
__HAL_RCC_APB1_FORCE_RESET();
__HAL_RCC_APB1_RELEASE_RESET();
__HAL_RCC_APB2_FORCE_RESET();
__HAL_RCC_APB2_RELEASE_RESET();
__HAL_RCC_AHB1_FORCE_RESET();
__HAL_RCC_AHB1_RELEASE_RESET();
__HAL_RCC_AHB2_FORCE_RESET();
__HAL_RCC_AHB2_RELEASE_RESET();
__HAL_RCC_AHB3_FORCE_RESET();
__HAL_RCC_AHB3_RELEASE_RESET();
/* De-Init the low level hardware */
HAL_MspDeInit();
/* Return function status */
return HAL_OK;
}
/**
* @brief Initialize the MSP.
* @retval None
*/
__weak void HAL_MspInit(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes the MSP.
* @retval None
*/
__weak void HAL_MspDeInit(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_MspDeInit could be implemented in the user file
*/
}
/**
* @brief This function configures the source of the time base:
* The time source is configured to have 1ms time base with a dedicated
* Tick interrupt priority.
* @note This function is called automatically at the beginning of program after
* reset by HAL_Init() or at any time when clock is reconfigured by HAL_RCC_ClockConfig().
* @note In the default implementation, SysTick timer is the source of time base.
* It is used to generate interrupts at regular time intervals.
* Care must be taken if HAL_Delay() is called from a peripheral ISR process,
* The SysTick interrupt must have higher priority (numerically lower)
* than the peripheral interrupt. Otherwise the caller ISR process will be blocked.
* The function is declared as __weak to be overwritten in case of other
* implementation in user file.
* @param TickPriority: Tick interrupt priority.
* @retval HAL status
*/
__weak HAL_StatusTypeDef HAL_InitTick(uint32_t TickPriority)
{
HAL_StatusTypeDef status = HAL_OK;
if (uwTickFreq != 0U)
{
/* Configure the SysTick to have interrupt in 1ms time basis*/
if (HAL_SYSTICK_Config(SystemCoreClock / (1000U / uwTickFreq)) == 0U)
{
/* Configure the SysTick IRQ priority */
if (TickPriority < (1UL << __NVIC_PRIO_BITS))
{
HAL_NVIC_SetPriority(SysTick_IRQn, TickPriority, 0U);
uwTickPrio = TickPriority;
}
else
{
status = HAL_ERROR;
}
}
else
{
status = HAL_ERROR;
}
}
else
{
status = HAL_ERROR;
}
/* Return function status */
return status;
}
/**
* @}
*/
/** @defgroup HAL_Exported_Functions_Group2 HAL Control functions
* @brief HAL Control functions
*
@verbatim
===============================================================================
##### HAL Control functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Provide a tick value in millisecond
(+) Provide a blocking delay in millisecond
(+) Suspend the time base source interrupt
(+) Resume the time base source interrupt
(+) Get the HAL API driver version
(+) Get the device identifier
(+) Get the device revision identifier
@endverbatim
* @{
*/
/**
* @brief This function is called to increment a global variable "uwTick"
* used as application time base.
* @note In the default implementation, this variable is incremented each 1ms
* in SysTick ISR.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval None
*/
__weak void HAL_IncTick(void)
{
uwTick += uwTickFreq;
}
/**
* @brief Provides a tick value in millisecond.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval tick value
*/
__weak uint32_t HAL_GetTick(void)
{
return uwTick;
}
/**
* @brief This function returns a tick priority.
* @retval tick priority
*/
uint32_t HAL_GetTickPrio(void)
{
return uwTickPrio;
}
/**
* @brief Set new tick Freq.
* @retval status
*/
HAL_StatusTypeDef HAL_SetTickFreq(uint32_t Freq)
{
HAL_StatusTypeDef status = HAL_OK;
uint32_t prevTickFreq;
assert_param(IS_TICKFREQ(Freq));
if (uwTickFreq != Freq)
{
/* Back up uwTickFreq frequency */
prevTickFreq = uwTickFreq;
/* Update uwTickFreq global variable used by HAL_InitTick() */
uwTickFreq = Freq;
/* Apply the new tick Freq */
status = HAL_InitTick(uwTickPrio);
if (status != HAL_OK)
{
/* Restore previous tick frequency */
uwTickFreq = prevTickFreq;
}
}
return status;
}
/**
* @brief Returns tick frequency.
* @retval Tick frequency.
* Value of @ref HAL_TickFreqTypeDef.
*/
uint32_t HAL_GetTickFreq(void)
{
return uwTickFreq;
}
/**
* @brief This function provides minimum delay (in milliseconds) based
* on variable incremented.
* @note In the default implementation , SysTick timer is the source of time base.
* It is used to generate interrupts at regular time intervals where uwTick
* is incremented.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @param Delay specifies the delay time length, in milliseconds.
* @retval None
*/
__weak void HAL_Delay(uint32_t Delay)
{
uint32_t tickstart = HAL_GetTick();
uint32_t wait = Delay;
/* Add a freq to guarantee minimum wait */
if (wait < HAL_MAX_DELAY)
{
wait += (uint32_t)(uwTickFreq);
}
while ((HAL_GetTick() - tickstart) < wait)
{
}
}
/**
* @brief Suspends Tick increment.
* @note In the default implementation , SysTick timer is the source of time base. It is
* used to generate interrupts at regular time intervals. Once HAL_SuspendTick()
* is called, the SysTick interrupt will be disabled and so Tick increment
* is suspended.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval None
*/
__weak void HAL_SuspendTick(void)
{
/* Disable SysTick Interrupt */
CLEAR_BIT(SysTick->CTRL, SysTick_CTRL_TICKINT_Msk);
}
/**
* @brief Resume Tick increment.
* @note In the default implementation , SysTick timer is the source of time base. It is
* used to generate interrupts at regular time intervals. Once HAL_ResumeTick()
* is called, the SysTick interrupt will be enabled and so Tick increment
* is resumed.
* @note This function is declared as __weak to be overwritten in case of other
* implementations in user file.
* @retval None
*/
__weak void HAL_ResumeTick(void)
{
/* Enable SysTick Interrupt */
SET_BIT(SysTick->CTRL, SysTick_CTRL_TICKINT_Msk);
}
/**
* @brief Returns the HAL revision.
* @retval version : 0xXYZR (8bits for each decimal, R for RC)
*/
uint32_t HAL_GetHalVersion(void)
{
return __STM32G4xx_HAL_VERSION;
}
/**
* @brief Returns the device revision identifier.
* @retval Device revision identifier
*/
uint32_t HAL_GetREVID(void)
{
return ((DBGMCU->IDCODE & DBGMCU_IDCODE_REV_ID) >> 16U);
}
/**
* @brief Returns the device identifier.
* @retval Device identifier
*/
uint32_t HAL_GetDEVID(void)
{
return (DBGMCU->IDCODE & DBGMCU_IDCODE_DEV_ID);
}
/**
* @brief Return the first word of the unique device identifier (UID based on 96 bits)
* @retval Device identifier
*/
uint32_t HAL_GetUIDw0(void)
{
return (READ_REG(*((uint32_t *)UID_BASE)));
}
/**
* @brief Return the second word of the unique device identifier (UID based on 96 bits)
* @retval Device identifier
*/
uint32_t HAL_GetUIDw1(void)
{
return (READ_REG(*((uint32_t *)(UID_BASE + 4U))));
}
/**
* @brief Return the third word of the unique device identifier (UID based on 96 bits)
* @retval Device identifier
*/
uint32_t HAL_GetUIDw2(void)
{
return (READ_REG(*((uint32_t *)(UID_BASE + 8U))));
}
/**
* @}
*/
/** @defgroup HAL_Exported_Functions_Group3 HAL Debug functions
* @brief HAL Debug functions
*
@verbatim
===============================================================================
##### HAL Debug functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Enable/Disable Debug module during SLEEP mode
(+) Enable/Disable Debug module during STOP0/STOP1/STOP2 modes
(+) Enable/Disable Debug module during STANDBY mode
@endverbatim
* @{
*/
/**
* @brief Enable the Debug Module during SLEEP mode.
* @retval None
*/
void HAL_DBGMCU_EnableDBGSleepMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_SLEEP);
}
/**
* @brief Disable the Debug Module during SLEEP mode.
* @retval None
*/
void HAL_DBGMCU_DisableDBGSleepMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_SLEEP);
}
/**
* @brief Enable the Debug Module during STOP0/STOP1/STOP2 modes.
* @retval None
*/
void HAL_DBGMCU_EnableDBGStopMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STOP);
}
/**
* @brief Disable the Debug Module during STOP0/STOP1/STOP2 modes.
* @retval None
*/
void HAL_DBGMCU_DisableDBGStopMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STOP);
}
/**
* @brief Enable the Debug Module during STANDBY mode.
* @retval None
*/
void HAL_DBGMCU_EnableDBGStandbyMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STANDBY);
}
/**
* @brief Disable the Debug Module during STANDBY mode.
* @retval None
*/
void HAL_DBGMCU_DisableDBGStandbyMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STANDBY);
}
/**
* @}
*/
/** @defgroup HAL_Exported_Functions_Group4 HAL SYSCFG configuration functions
* @brief HAL SYSCFG configuration functions
*
@verbatim
===============================================================================
##### HAL SYSCFG configuration functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Start a hardware CCMSRAM erase operation
(+) Enable/Disable the Internal FLASH Bank Swapping
(+) Configure the Voltage reference buffer
(+) Enable/Disable the Voltage reference buffer
(+) Enable/Disable the I/O analog switch voltage booster
@endverbatim
* @{
*/
/**
* @brief Start a hardware CCMSRAM erase operation.
* @note As long as CCMSRAM is not erased the CCMER bit will be set.
* This bit is automatically reset at the end of the CCMSRAM erase operation.
* @retval None
*/
void HAL_SYSCFG_CCMSRAMErase(void)
{
/* unlock the write protection of the CCMER bit */
SYSCFG->SKR = 0xCA;
SYSCFG->SKR = 0x53;
/* Starts a hardware CCMSRAM erase operation*/
SET_BIT(SYSCFG->SCSR, SYSCFG_SCSR_CCMER);
}
/**
* @brief Enable the Internal FLASH Bank Swapping.
*
* @note This function can be used only for STM32G4xx devices.
*
* @note Flash Bank2 mapped at 0x08000000 (and aliased @0x00000000)
* and Flash Bank1 mapped at 0x08040000 (and aliased at 0x00040000)
*
* @retval None
*/
void HAL_SYSCFG_EnableMemorySwappingBank(void)
{
SET_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_FB_MODE);
}
/**
* @brief Disable the Internal FLASH Bank Swapping.
*
* @note This function can be used only for STM32G4xx devices.
*
* @note The default state : Flash Bank1 mapped at 0x08000000 (and aliased @0x0000 0000)
* and Flash Bank2 mapped at 0x08040000 (and aliased at 0x00040000)
*
* @retval None
*/
void HAL_SYSCFG_DisableMemorySwappingBank(void)
{
CLEAR_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_FB_MODE);
}
#if defined(VREFBUF)
/**
* @brief Configure the internal voltage reference buffer voltage scale.
* @param VoltageScaling: specifies the output voltage to achieve
* This parameter can be one of the following values:
* @arg SYSCFG_VREFBUF_VOLTAGE_SCALE0: VREFBUF_OUT around 2.048 V.
* This requires VDDA equal to or higher than 2.4 V.
* @arg SYSCFG_VREFBUF_VOLTAGE_SCALE1: VREFBUF_OUT around 2.5 V.
* This requires VDDA equal to or higher than 2.8 V.
* @arg SYSCFG_VREFBUF_VOLTAGE_SCALE2: VREFBUF_OUT around 2.9 V.
* This requires VDDA equal to or higher than 3.15 V.
* @retval None
*/
void HAL_SYSCFG_VREFBUF_VoltageScalingConfig(uint32_t VoltageScaling)
{
/* Check the parameters */
assert_param(IS_SYSCFG_VREFBUF_VOLTAGE_SCALE(VoltageScaling));
MODIFY_REG(VREFBUF->CSR, VREFBUF_CSR_VRS, VoltageScaling);
}
/**
* @brief Configure the internal voltage reference buffer high impedance mode.
* @param Mode: specifies the high impedance mode
* This parameter can be one of the following values:
* @arg SYSCFG_VREFBUF_HIGH_IMPEDANCE_DISABLE: VREF+ pin is internally connect to VREFINT output.
* @arg SYSCFG_VREFBUF_HIGH_IMPEDANCE_ENABLE: VREF+ pin is high impedance.
* @retval None
*/
void HAL_SYSCFG_VREFBUF_HighImpedanceConfig(uint32_t Mode)
{
/* Check the parameters */
assert_param(IS_SYSCFG_VREFBUF_HIGH_IMPEDANCE(Mode));
MODIFY_REG(VREFBUF->CSR, VREFBUF_CSR_HIZ, Mode);
}
/**
* @brief Tune the Internal Voltage Reference buffer (VREFBUF).
* @param TrimmingValue specifies trimming code for VREFBUF calibration
* This parameter can be a number between Min_Data = 0x00 and Max_Data = 0x3F
* @retval None
*/
void HAL_SYSCFG_VREFBUF_TrimmingConfig(uint32_t TrimmingValue)
{
/* Check the parameters */
assert_param(IS_SYSCFG_VREFBUF_TRIMMING(TrimmingValue));
MODIFY_REG(VREFBUF->CCR, VREFBUF_CCR_TRIM, TrimmingValue);
}
/**
* @brief Enable the Internal Voltage Reference buffer (VREFBUF).
* @retval HAL_OK/HAL_TIMEOUT
*/
HAL_StatusTypeDef HAL_SYSCFG_EnableVREFBUF(void)
{
uint32_t tickstart;
SET_BIT(VREFBUF->CSR, VREFBUF_CSR_ENVR);
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait for VRR bit */
while (READ_BIT(VREFBUF->CSR, VREFBUF_CSR_VRR) == 0x00U)
{
if ((HAL_GetTick() - tickstart) > VREFBUF_TIMEOUT_VALUE)
{
return HAL_TIMEOUT;
}
}
return HAL_OK;
}
/**
* @brief Disable the Internal Voltage Reference buffer (VREFBUF).
*
* @retval None
*/
void HAL_SYSCFG_DisableVREFBUF(void)
{
CLEAR_BIT(VREFBUF->CSR, VREFBUF_CSR_ENVR);
}
#endif /* VREFBUF */
/**
* @brief Enable the I/O analog switch voltage booster
*
* @retval None
*/
void HAL_SYSCFG_EnableIOSwitchBooster(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_BOOSTEN);
}
/**
* @brief Disable the I/O analog switch voltage booster
*
* @retval None
*/
void HAL_SYSCFG_DisableIOSwitchBooster(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_BOOSTEN);
}
/**
* @brief Enable the I/O analog switch voltage by VDD
*
* @retval None
*/
void HAL_SYSCFG_EnableIOSwitchVDD(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_ANASWVDD);
}
/**
* @brief Disable the I/O analog switch voltage by VDD
*
* @retval None
*/
void HAL_SYSCFG_DisableIOSwitchVDD(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_ANASWVDD);
}
/** @brief CCMSRAM page write protection enable
* @param Page: This parameter is a long 32bit value and can be a value of @ref SYSCFG_CCMSRAMWRP
* @note write protection can only be disabled by a system reset
* @retval None
*/
void HAL_SYSCFG_CCMSRAM_WriteProtectionEnable(uint32_t Page)
{
assert_param(IS_SYSCFG_CCMSRAMWRP_PAGE(Page));
SET_BIT(SYSCFG->SWPR, (uint32_t)(Page));
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 23,899 | C | 28.837703 | 109 | 0.607892 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_crc.c | /**
******************************************************************************
* @file stm32g4xx_hal_crc.c
* @author MCD Application Team
* @brief CRC HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Cyclic Redundancy Check (CRC) peripheral:
* + Initialization and de-initialization functions
* + Peripheral Control functions
* + Peripheral State functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
===============================================================================
##### How to use this driver #####
===============================================================================
[..]
(+) Enable CRC AHB clock using __HAL_RCC_CRC_CLK_ENABLE();
(+) Initialize CRC calculator
(++) specify generating polynomial (peripheral default or non-default one)
(++) specify initialization value (peripheral default or non-default one)
(++) specify input data format
(++) specify input or output data inversion mode if any
(+) Use HAL_CRC_Accumulate() function to compute the CRC value of the
input data buffer starting with the previously computed CRC as
initialization value
(+) Use HAL_CRC_Calculate() function to compute the CRC value of the
input data buffer starting with the defined initialization value
(default or non-default) to initiate CRC calculation
@endverbatim
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup CRC CRC
* @brief CRC HAL module driver.
* @{
*/
#ifdef HAL_CRC_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup CRC_Private_Functions CRC Private Functions
* @{
*/
static uint32_t CRC_Handle_8(CRC_HandleTypeDef *hcrc, uint8_t pBuffer[], uint32_t BufferLength);
static uint32_t CRC_Handle_16(CRC_HandleTypeDef *hcrc, uint16_t pBuffer[], uint32_t BufferLength);
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup CRC_Exported_Functions CRC Exported Functions
* @{
*/
/** @defgroup CRC_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief Initialization and Configuration functions.
*
@verbatim
===============================================================================
##### Initialization and de-initialization functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) Initialize the CRC according to the specified parameters
in the CRC_InitTypeDef and create the associated handle
(+) DeInitialize the CRC peripheral
(+) Initialize the CRC MSP (MCU Specific Package)
(+) DeInitialize the CRC MSP
@endverbatim
* @{
*/
/**
* @brief Initialize the CRC according to the specified
* parameters in the CRC_InitTypeDef and create the associated handle.
* @param hcrc CRC handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRC_Init(CRC_HandleTypeDef *hcrc)
{
/* Check the CRC handle allocation */
if (hcrc == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_CRC_ALL_INSTANCE(hcrc->Instance));
if (hcrc->State == HAL_CRC_STATE_RESET)
{
/* Allocate lock resource and initialize it */
hcrc->Lock = HAL_UNLOCKED;
/* Init the low level hardware */
HAL_CRC_MspInit(hcrc);
}
hcrc->State = HAL_CRC_STATE_BUSY;
/* check whether or not non-default generating polynomial has been
* picked up by user */
assert_param(IS_DEFAULT_POLYNOMIAL(hcrc->Init.DefaultPolynomialUse));
if (hcrc->Init.DefaultPolynomialUse == DEFAULT_POLYNOMIAL_ENABLE)
{
/* initialize peripheral with default generating polynomial */
WRITE_REG(hcrc->Instance->POL, DEFAULT_CRC32_POLY);
MODIFY_REG(hcrc->Instance->CR, CRC_CR_POLYSIZE, CRC_POLYLENGTH_32B);
}
else
{
/* initialize CRC peripheral with generating polynomial defined by user */
if (HAL_CRCEx_Polynomial_Set(hcrc, hcrc->Init.GeneratingPolynomial, hcrc->Init.CRCLength) != HAL_OK)
{
return HAL_ERROR;
}
}
/* check whether or not non-default CRC initial value has been
* picked up by user */
assert_param(IS_DEFAULT_INIT_VALUE(hcrc->Init.DefaultInitValueUse));
if (hcrc->Init.DefaultInitValueUse == DEFAULT_INIT_VALUE_ENABLE)
{
WRITE_REG(hcrc->Instance->INIT, DEFAULT_CRC_INITVALUE);
}
else
{
WRITE_REG(hcrc->Instance->INIT, hcrc->Init.InitValue);
}
/* set input data inversion mode */
assert_param(IS_CRC_INPUTDATA_INVERSION_MODE(hcrc->Init.InputDataInversionMode));
MODIFY_REG(hcrc->Instance->CR, CRC_CR_REV_IN, hcrc->Init.InputDataInversionMode);
/* set output data inversion mode */
assert_param(IS_CRC_OUTPUTDATA_INVERSION_MODE(hcrc->Init.OutputDataInversionMode));
MODIFY_REG(hcrc->Instance->CR, CRC_CR_REV_OUT, hcrc->Init.OutputDataInversionMode);
/* makes sure the input data format (bytes, halfwords or words stream)
* is properly specified by user */
assert_param(IS_CRC_INPUTDATA_FORMAT(hcrc->InputDataFormat));
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief DeInitialize the CRC peripheral.
* @param hcrc CRC handle
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRC_DeInit(CRC_HandleTypeDef *hcrc)
{
/* Check the CRC handle allocation */
if (hcrc == NULL)
{
return HAL_ERROR;
}
/* Check the parameters */
assert_param(IS_CRC_ALL_INSTANCE(hcrc->Instance));
/* Check the CRC peripheral state */
if (hcrc->State == HAL_CRC_STATE_BUSY)
{
return HAL_BUSY;
}
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_BUSY;
/* Reset CRC calculation unit */
__HAL_CRC_DR_RESET(hcrc);
/* Reset IDR register content */
CLEAR_REG(hcrc->Instance->IDR);
/* DeInit the low level hardware */
HAL_CRC_MspDeInit(hcrc);
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_RESET;
/* Process unlocked */
__HAL_UNLOCK(hcrc);
/* Return function status */
return HAL_OK;
}
/**
* @brief Initializes the CRC MSP.
* @param hcrc CRC handle
* @retval None
*/
__weak void HAL_CRC_MspInit(CRC_HandleTypeDef *hcrc)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(hcrc);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_CRC_MspInit can be implemented in the user file
*/
}
/**
* @brief DeInitialize the CRC MSP.
* @param hcrc CRC handle
* @retval None
*/
__weak void HAL_CRC_MspDeInit(CRC_HandleTypeDef *hcrc)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(hcrc);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_CRC_MspDeInit can be implemented in the user file
*/
}
/**
* @}
*/
/** @defgroup CRC_Exported_Functions_Group2 Peripheral Control functions
* @brief management functions.
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..] This section provides functions allowing to:
(+) compute the 7, 8, 16 or 32-bit CRC value of an 8, 16 or 32-bit data buffer
using combination of the previous CRC value and the new one.
[..] or
(+) compute the 7, 8, 16 or 32-bit CRC value of an 8, 16 or 32-bit data buffer
independently of the previous CRC value.
@endverbatim
* @{
*/
/**
* @brief Compute the 7, 8, 16 or 32-bit CRC value of an 8, 16 or 32-bit data buffer
* starting with the previously computed CRC as initialization value.
* @param hcrc CRC handle
* @param pBuffer pointer to the input data buffer, exact input data format is
* provided by hcrc->InputDataFormat.
* @param BufferLength input data buffer length (number of bytes if pBuffer
* type is * uint8_t, number of half-words if pBuffer type is * uint16_t,
* number of words if pBuffer type is * uint32_t).
* @note By default, the API expects a uint32_t pointer as input buffer parameter.
* Input buffer pointers with other types simply need to be cast in uint32_t
* and the API will internally adjust its input data processing based on the
* handle field hcrc->InputDataFormat.
* @retval uint32_t CRC (returned value LSBs for CRC shorter than 32 bits)
*/
uint32_t HAL_CRC_Accumulate(CRC_HandleTypeDef *hcrc, uint32_t pBuffer[], uint32_t BufferLength)
{
uint32_t index; /* CRC input data buffer index */
uint32_t temp = 0U; /* CRC output (read from hcrc->Instance->DR register) */
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_BUSY;
switch (hcrc->InputDataFormat)
{
case CRC_INPUTDATA_FORMAT_WORDS:
/* Enter Data to the CRC calculator */
for (index = 0U; index < BufferLength; index++)
{
hcrc->Instance->DR = pBuffer[index];
}
temp = hcrc->Instance->DR;
break;
case CRC_INPUTDATA_FORMAT_BYTES:
temp = CRC_Handle_8(hcrc, (uint8_t *)pBuffer, BufferLength);
break;
case CRC_INPUTDATA_FORMAT_HALFWORDS:
temp = CRC_Handle_16(hcrc, (uint16_t *)(void *)pBuffer, BufferLength); /* Derogation MisraC2012 R.11.5 */
break;
default:
break;
}
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_READY;
/* Return the CRC computed value */
return temp;
}
/**
* @brief Compute the 7, 8, 16 or 32-bit CRC value of an 8, 16 or 32-bit data buffer
* starting with hcrc->Instance->INIT as initialization value.
* @param hcrc CRC handle
* @param pBuffer pointer to the input data buffer, exact input data format is
* provided by hcrc->InputDataFormat.
* @param BufferLength input data buffer length (number of bytes if pBuffer
* type is * uint8_t, number of half-words if pBuffer type is * uint16_t,
* number of words if pBuffer type is * uint32_t).
* @note By default, the API expects a uint32_t pointer as input buffer parameter.
* Input buffer pointers with other types simply need to be cast in uint32_t
* and the API will internally adjust its input data processing based on the
* handle field hcrc->InputDataFormat.
* @retval uint32_t CRC (returned value LSBs for CRC shorter than 32 bits)
*/
uint32_t HAL_CRC_Calculate(CRC_HandleTypeDef *hcrc, uint32_t pBuffer[], uint32_t BufferLength)
{
uint32_t index; /* CRC input data buffer index */
uint32_t temp = 0U; /* CRC output (read from hcrc->Instance->DR register) */
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_BUSY;
/* Reset CRC Calculation Unit (hcrc->Instance->INIT is
* written in hcrc->Instance->DR) */
__HAL_CRC_DR_RESET(hcrc);
switch (hcrc->InputDataFormat)
{
case CRC_INPUTDATA_FORMAT_WORDS:
/* Enter 32-bit input data to the CRC calculator */
for (index = 0U; index < BufferLength; index++)
{
hcrc->Instance->DR = pBuffer[index];
}
temp = hcrc->Instance->DR;
break;
case CRC_INPUTDATA_FORMAT_BYTES:
/* Specific 8-bit input data handling */
temp = CRC_Handle_8(hcrc, (uint8_t *)pBuffer, BufferLength);
break;
case CRC_INPUTDATA_FORMAT_HALFWORDS:
/* Specific 16-bit input data handling */
temp = CRC_Handle_16(hcrc, (uint16_t *)(void *)pBuffer, BufferLength); /* Derogation MisraC2012 R.11.5 */
break;
default:
break;
}
/* Change CRC peripheral state */
hcrc->State = HAL_CRC_STATE_READY;
/* Return the CRC computed value */
return temp;
}
/**
* @}
*/
/** @defgroup CRC_Exported_Functions_Group3 Peripheral State functions
* @brief Peripheral State functions.
*
@verbatim
===============================================================================
##### Peripheral State functions #####
===============================================================================
[..]
This subsection permits to get in run-time the status of the peripheral.
@endverbatim
* @{
*/
/**
* @brief Return the CRC handle state.
* @param hcrc CRC handle
* @retval HAL state
*/
HAL_CRC_StateTypeDef HAL_CRC_GetState(const CRC_HandleTypeDef *hcrc)
{
/* Return CRC handle state */
return hcrc->State;
}
/**
* @}
*/
/**
* @}
*/
/** @addtogroup CRC_Private_Functions
* @{
*/
/**
* @brief Enter 8-bit input data to the CRC calculator.
* Specific data handling to optimize processing time.
* @param hcrc CRC handle
* @param pBuffer pointer to the input data buffer
* @param BufferLength input data buffer length
* @retval uint32_t CRC (returned value LSBs for CRC shorter than 32 bits)
*/
static uint32_t CRC_Handle_8(CRC_HandleTypeDef *hcrc, uint8_t pBuffer[], uint32_t BufferLength)
{
uint32_t i; /* input data buffer index */
uint16_t data;
__IO uint16_t *pReg;
/* Processing time optimization: 4 bytes are entered in a row with a single word write,
* last bytes must be carefully fed to the CRC calculator to ensure a correct type
* handling by the peripheral */
for (i = 0U; i < (BufferLength / 4U); i++)
{
hcrc->Instance->DR = ((uint32_t)pBuffer[4U * i] << 24U) | \
((uint32_t)pBuffer[(4U * i) + 1U] << 16U) | \
((uint32_t)pBuffer[(4U * i) + 2U] << 8U) | \
(uint32_t)pBuffer[(4U * i) + 3U];
}
/* last bytes specific handling */
if ((BufferLength % 4U) != 0U)
{
if ((BufferLength % 4U) == 1U)
{
*(__IO uint8_t *)(__IO void *)(&hcrc->Instance->DR) = pBuffer[4U * i]; /* Derogation MisraC2012 R.11.5 */
}
if ((BufferLength % 4U) == 2U)
{
data = ((uint16_t)(pBuffer[4U * i]) << 8U) | (uint16_t)pBuffer[(4U * i) + 1U];
pReg = (__IO uint16_t *)(__IO void *)(&hcrc->Instance->DR); /* Derogation MisraC2012 R.11.5 */
*pReg = data;
}
if ((BufferLength % 4U) == 3U)
{
data = ((uint16_t)(pBuffer[4U * i]) << 8U) | (uint16_t)pBuffer[(4U * i) + 1U];
pReg = (__IO uint16_t *)(__IO void *)(&hcrc->Instance->DR); /* Derogation MisraC2012 R.11.5 */
*pReg = data;
*(__IO uint8_t *)(__IO void *)(&hcrc->Instance->DR) = pBuffer[(4U * i) + 2U]; /* Derogation MisraC2012 R.11.5 */
}
}
/* Return the CRC computed value */
return hcrc->Instance->DR;
}
/**
* @brief Enter 16-bit input data to the CRC calculator.
* Specific data handling to optimize processing time.
* @param hcrc CRC handle
* @param pBuffer pointer to the input data buffer
* @param BufferLength input data buffer length
* @retval uint32_t CRC (returned value LSBs for CRC shorter than 32 bits)
*/
static uint32_t CRC_Handle_16(CRC_HandleTypeDef *hcrc, uint16_t pBuffer[], uint32_t BufferLength)
{
uint32_t i; /* input data buffer index */
__IO uint16_t *pReg;
/* Processing time optimization: 2 HalfWords are entered in a row with a single word write,
* in case of odd length, last HalfWord must be carefully fed to the CRC calculator to ensure
* a correct type handling by the peripheral */
for (i = 0U; i < (BufferLength / 2U); i++)
{
hcrc->Instance->DR = ((uint32_t)pBuffer[2U * i] << 16U) | (uint32_t)pBuffer[(2U * i) + 1U];
}
if ((BufferLength % 2U) != 0U)
{
pReg = (__IO uint16_t *)(__IO void *)(&hcrc->Instance->DR); /* Derogation MisraC2012 R.11.5 */
*pReg = pBuffer[2U * i];
}
/* Return the CRC computed value */
return hcrc->Instance->DR;
}
/**
* @}
*/
#endif /* HAL_CRC_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 17,019 | C | 31.920696 | 119 | 0.587344 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_rcc_ex.c | /**
******************************************************************************
* @file stm32g4xx_hal_rcc_ex.c
* @author MCD Application Team
* @brief Extended RCC HAL module driver.
* This file provides firmware functions to manage the following
* functionalities RCC extended peripheral:
* + Extended Peripheral Control functions
* + Extended Clock management functions
* + Extended Clock Recovery System Control functions
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup RCCEx RCCEx
* @brief RCC Extended HAL module driver
* @{
*/
#ifdef HAL_RCC_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private defines -----------------------------------------------------------*/
/** @defgroup RCCEx_Private_Constants RCCEx Private Constants
* @{
*/
#define PLL_TIMEOUT_VALUE 2U /* 2 ms (minimum Tick + 1) */
#define DIVIDER_P_UPDATE 0U
#define DIVIDER_Q_UPDATE 1U
#define DIVIDER_R_UPDATE 2U
#define __LSCO_CLK_ENABLE() __HAL_RCC_GPIOA_CLK_ENABLE()
#define LSCO_GPIO_PORT GPIOA
#define LSCO_PIN GPIO_PIN_2
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup RCCEx_Private_Functions RCCEx Private Functions
* @{
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup RCCEx_Exported_Functions RCCEx Exported Functions
* @{
*/
/** @defgroup RCCEx_Exported_Functions_Group1 Extended Peripheral Control functions
* @brief Extended Peripheral Control functions
*
@verbatim
===============================================================================
##### Extended Peripheral Control functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the RCC Clocks
frequencies.
[..]
(@) Important note: Care must be taken when HAL_RCCEx_PeriphCLKConfig() is used to
select the RTC clock source; in this case the Backup domain will be reset in
order to modify the RTC Clock source, as consequence RTC registers (including
the backup registers) are set to their reset values.
@endverbatim
* @{
*/
/**
* @brief Initialize the RCC extended peripherals clocks according to the specified
* parameters in the RCC_PeriphCLKInitTypeDef.
* @param PeriphClkInit pointer to an RCC_PeriphCLKInitTypeDef structure that
* contains a field PeriphClockSelection which can be a combination of the following values:
* @arg @ref RCC_PERIPHCLK_RTC RTC peripheral clock
* @arg @ref RCC_PERIPHCLK_USART1 USART1 peripheral clock
* @arg @ref RCC_PERIPHCLK_USART2 USART2 peripheral clock
* @arg @ref RCC_PERIPHCLK_USART3 USART3 peripheral clock
* @arg @ref RCC_PERIPHCLK_UART4 UART4 peripheral clock (only for devices with UART4)
* @arg @ref RCC_PERIPHCLK_UART5 UART5 peripheral clock (only for devices with UART5)
* @arg @ref RCC_PERIPHCLK_LPUART1 LPUART1 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C1 I2C1 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C2 I2C2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C3 I2C3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C4 I2C4 peripheral clock (only for devices with I2C4)
* @arg @ref RCC_PERIPHCLK_LPTIM1 LPTIM1 peripheral clock
* @arg @ref RCC_PERIPHCLK_SAI1 SAI1 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S I2S peripheral clock
* @arg @ref RCC_PERIPHCLK_FDCAN FDCAN peripheral clock (only for devices with FDCAN)
* @arg @ref RCC_PERIPHCLK_RNG RNG peripheral clock
* @arg @ref RCC_PERIPHCLK_USB USB peripheral clock (only for devices with USB)
* @arg @ref RCC_PERIPHCLK_ADC12 ADC1 and ADC2 peripheral clock
* @arg @ref RCC_PERIPHCLK_ADC345 ADC3, ADC4 and ADC5 peripheral clock (only for devices with ADC3, ADC4, ADC5)
* @arg @ref RCC_PERIPHCLK_QSPI QuadSPI peripheral clock (only for devices with QuadSPI)
*
* @note Care must be taken when HAL_RCCEx_PeriphCLKConfig() is used to select
* the RTC clock source: in this case the access to Backup domain is enabled.
*
* @retval HAL status
*/
HAL_StatusTypeDef HAL_RCCEx_PeriphCLKConfig(RCC_PeriphCLKInitTypeDef *PeriphClkInit)
{
uint32_t tmpregister;
uint32_t tickstart;
HAL_StatusTypeDef ret = HAL_OK; /* Intermediate status */
HAL_StatusTypeDef status = HAL_OK; /* Final status */
/* Check the parameters */
assert_param(IS_RCC_PERIPHCLOCK(PeriphClkInit->PeriphClockSelection));
/*-------------------------- RTC clock source configuration ----------------------*/
if((PeriphClkInit->PeriphClockSelection & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC)
{
FlagStatus pwrclkchanged = RESET;
/* Check for RTC Parameters used to output RTCCLK */
assert_param(IS_RCC_RTCCLKSOURCE(PeriphClkInit->RTCClockSelection));
/* Enable Power Clock */
if(__HAL_RCC_PWR_IS_CLK_DISABLED())
{
__HAL_RCC_PWR_CLK_ENABLE();
pwrclkchanged = SET;
}
/* Enable write access to Backup domain */
SET_BIT(PWR->CR1, PWR_CR1_DBP);
/* Wait for Backup domain Write protection disable */
tickstart = HAL_GetTick();
while((PWR->CR1 & PWR_CR1_DBP) == 0U)
{
if((HAL_GetTick() - tickstart) > RCC_DBP_TIMEOUT_VALUE)
{
ret = HAL_TIMEOUT;
break;
}
}
if(ret == HAL_OK)
{
/* Reset the Backup domain only if the RTC Clock source selection is modified from default */
tmpregister = READ_BIT(RCC->BDCR, RCC_BDCR_RTCSEL);
if((tmpregister != RCC_RTCCLKSOURCE_NONE) && (tmpregister != PeriphClkInit->RTCClockSelection))
{
/* Store the content of BDCR register before the reset of Backup Domain */
tmpregister = READ_BIT(RCC->BDCR, ~(RCC_BDCR_RTCSEL));
/* RTC Clock selection can be changed only if the Backup Domain is reset */
__HAL_RCC_BACKUPRESET_FORCE();
__HAL_RCC_BACKUPRESET_RELEASE();
/* Restore the Content of BDCR register */
RCC->BDCR = tmpregister;
}
/* Wait for LSE reactivation if LSE was enable prior to Backup Domain reset */
if (HAL_IS_BIT_SET(tmpregister, RCC_BDCR_LSEON))
{
/* Get Start Tick*/
tickstart = HAL_GetTick();
/* Wait till LSE is ready */
while(READ_BIT(RCC->BDCR, RCC_BDCR_LSERDY) == 0U)
{
if((HAL_GetTick() - tickstart) > RCC_LSE_TIMEOUT_VALUE)
{
ret = HAL_TIMEOUT;
break;
}
}
}
if(ret == HAL_OK)
{
/* Apply new RTC clock source selection */
__HAL_RCC_RTC_CONFIG(PeriphClkInit->RTCClockSelection);
}
else
{
/* set overall return value */
status = ret;
}
}
else
{
/* set overall return value */
status = ret;
}
/* Restore clock configuration if changed */
if(pwrclkchanged == SET)
{
__HAL_RCC_PWR_CLK_DISABLE();
}
}
/*-------------------------- USART1 clock source configuration -------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_USART1) == RCC_PERIPHCLK_USART1)
{
/* Check the parameters */
assert_param(IS_RCC_USART1CLKSOURCE(PeriphClkInit->Usart1ClockSelection));
/* Configure the USART1 clock source */
__HAL_RCC_USART1_CONFIG(PeriphClkInit->Usart1ClockSelection);
}
/*-------------------------- USART2 clock source configuration -------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_USART2) == RCC_PERIPHCLK_USART2)
{
/* Check the parameters */
assert_param(IS_RCC_USART2CLKSOURCE(PeriphClkInit->Usart2ClockSelection));
/* Configure the USART2 clock source */
__HAL_RCC_USART2_CONFIG(PeriphClkInit->Usart2ClockSelection);
}
/*-------------------------- USART3 clock source configuration -------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_USART3) == RCC_PERIPHCLK_USART3)
{
/* Check the parameters */
assert_param(IS_RCC_USART3CLKSOURCE(PeriphClkInit->Usart3ClockSelection));
/* Configure the USART3 clock source */
__HAL_RCC_USART3_CONFIG(PeriphClkInit->Usart3ClockSelection);
}
#if defined(UART4)
/*-------------------------- UART4 clock source configuration --------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_UART4) == RCC_PERIPHCLK_UART4)
{
/* Check the parameters */
assert_param(IS_RCC_UART4CLKSOURCE(PeriphClkInit->Uart4ClockSelection));
/* Configure the UART4 clock source */
__HAL_RCC_UART4_CONFIG(PeriphClkInit->Uart4ClockSelection);
}
#endif /* UART4 */
#if defined(UART5)
/*-------------------------- UART5 clock source configuration --------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_UART5) == RCC_PERIPHCLK_UART5)
{
/* Check the parameters */
assert_param(IS_RCC_UART5CLKSOURCE(PeriphClkInit->Uart5ClockSelection));
/* Configure the UART5 clock source */
__HAL_RCC_UART5_CONFIG(PeriphClkInit->Uart5ClockSelection);
}
#endif /* UART5 */
/*-------------------------- LPUART1 clock source configuration ------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_LPUART1) == RCC_PERIPHCLK_LPUART1)
{
/* Check the parameters */
assert_param(IS_RCC_LPUART1CLKSOURCE(PeriphClkInit->Lpuart1ClockSelection));
/* Configure the LPUAR1 clock source */
__HAL_RCC_LPUART1_CONFIG(PeriphClkInit->Lpuart1ClockSelection);
}
/*-------------------------- I2C1 clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_I2C1) == RCC_PERIPHCLK_I2C1)
{
/* Check the parameters */
assert_param(IS_RCC_I2C1CLKSOURCE(PeriphClkInit->I2c1ClockSelection));
/* Configure the I2C1 clock source */
__HAL_RCC_I2C1_CONFIG(PeriphClkInit->I2c1ClockSelection);
}
/*-------------------------- I2C2 clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_I2C2) == RCC_PERIPHCLK_I2C2)
{
/* Check the parameters */
assert_param(IS_RCC_I2C2CLKSOURCE(PeriphClkInit->I2c2ClockSelection));
/* Configure the I2C2 clock source */
__HAL_RCC_I2C2_CONFIG(PeriphClkInit->I2c2ClockSelection);
}
/*-------------------------- I2C3 clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_I2C3) == RCC_PERIPHCLK_I2C3)
{
/* Check the parameters */
assert_param(IS_RCC_I2C3CLKSOURCE(PeriphClkInit->I2c3ClockSelection));
/* Configure the I2C3 clock source */
__HAL_RCC_I2C3_CONFIG(PeriphClkInit->I2c3ClockSelection);
}
#if defined(I2C4)
/*-------------------------- I2C4 clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_I2C4) == RCC_PERIPHCLK_I2C4)
{
/* Check the parameters */
assert_param(IS_RCC_I2C4CLKSOURCE(PeriphClkInit->I2c4ClockSelection));
/* Configure the I2C4 clock source */
__HAL_RCC_I2C4_CONFIG(PeriphClkInit->I2c4ClockSelection);
}
#endif /* I2C4 */
/*-------------------------- LPTIM1 clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_LPTIM1) == RCC_PERIPHCLK_LPTIM1)
{
/* Check the parameters */
assert_param(IS_RCC_LPTIM1CLKSOURCE(PeriphClkInit->Lptim1ClockSelection));
/* Configure the LPTIM1 clock source */
__HAL_RCC_LPTIM1_CONFIG(PeriphClkInit->Lptim1ClockSelection);
}
/*-------------------------- SAI1 clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_SAI1) == RCC_PERIPHCLK_SAI1)
{
/* Check the parameters */
assert_param(IS_RCC_SAI1CLKSOURCE(PeriphClkInit->Sai1ClockSelection));
/* Configure the SAI1 interface clock source */
__HAL_RCC_SAI1_CONFIG(PeriphClkInit->Sai1ClockSelection);
if(PeriphClkInit->Sai1ClockSelection == RCC_SAI1CLKSOURCE_PLL)
{
/* Enable PLL48M1CLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_48M1CLK);
}
}
/*-------------------------- I2S clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_I2S) == RCC_PERIPHCLK_I2S)
{
/* Check the parameters */
assert_param(IS_RCC_I2SCLKSOURCE(PeriphClkInit->I2sClockSelection));
/* Configure the I2S interface clock source */
__HAL_RCC_I2S_CONFIG(PeriphClkInit->I2sClockSelection);
if(PeriphClkInit->I2sClockSelection == RCC_I2SCLKSOURCE_PLL)
{
/* Enable PLL48M1CLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_48M1CLK);
}
}
#if defined(FDCAN1)
/*-------------------------- FDCAN clock source configuration ---------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_FDCAN) == RCC_PERIPHCLK_FDCAN)
{
/* Check the parameters */
assert_param(IS_RCC_FDCANCLKSOURCE(PeriphClkInit->FdcanClockSelection));
/* Configure the FDCAN interface clock source */
__HAL_RCC_FDCAN_CONFIG(PeriphClkInit->FdcanClockSelection);
if(PeriphClkInit->FdcanClockSelection == RCC_FDCANCLKSOURCE_PLL)
{
/* Enable PLL48M1CLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_48M1CLK);
}
}
#endif /* FDCAN1 */
#if defined(USB)
/*-------------------------- USB clock source configuration ----------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_USB) == (RCC_PERIPHCLK_USB))
{
assert_param(IS_RCC_USBCLKSOURCE(PeriphClkInit->UsbClockSelection));
__HAL_RCC_USB_CONFIG(PeriphClkInit->UsbClockSelection);
if(PeriphClkInit->UsbClockSelection == RCC_USBCLKSOURCE_PLL)
{
/* Enable PLL48M1CLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_48M1CLK);
}
}
#endif /* USB */
/*-------------------------- RNG clock source configuration ----------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_RNG) == (RCC_PERIPHCLK_RNG))
{
assert_param(IS_RCC_RNGCLKSOURCE(PeriphClkInit->RngClockSelection));
__HAL_RCC_RNG_CONFIG(PeriphClkInit->RngClockSelection);
if(PeriphClkInit->RngClockSelection == RCC_RNGCLKSOURCE_PLL)
{
/* Enable PLL48M1CLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_48M1CLK);
}
}
/*-------------------------- ADC12 clock source configuration ----------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_ADC12) == RCC_PERIPHCLK_ADC12)
{
/* Check the parameters */
assert_param(IS_RCC_ADC12CLKSOURCE(PeriphClkInit->Adc12ClockSelection));
/* Configure the ADC12 interface clock source */
__HAL_RCC_ADC12_CONFIG(PeriphClkInit->Adc12ClockSelection);
if(PeriphClkInit->Adc12ClockSelection == RCC_ADC12CLKSOURCE_PLL)
{
/* Enable PLLADCCLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_ADCCLK);
}
}
#if defined(ADC345_COMMON)
/*-------------------------- ADC345 clock source configuration ----------------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_ADC345) == RCC_PERIPHCLK_ADC345)
{
/* Check the parameters */
assert_param(IS_RCC_ADC345CLKSOURCE(PeriphClkInit->Adc345ClockSelection));
/* Configure the ADC345 interface clock source */
__HAL_RCC_ADC345_CONFIG(PeriphClkInit->Adc345ClockSelection);
if(PeriphClkInit->Adc345ClockSelection == RCC_ADC345CLKSOURCE_PLL)
{
/* Enable PLLADCCLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_ADCCLK);
}
}
#endif /* ADC345_COMMON */
#if defined(QUADSPI)
/*-------------------------- QuadSPIx clock source configuration ----------------*/
if(((PeriphClkInit->PeriphClockSelection) & RCC_PERIPHCLK_QSPI) == RCC_PERIPHCLK_QSPI)
{
/* Check the parameters */
assert_param(IS_RCC_QSPICLKSOURCE(PeriphClkInit->QspiClockSelection));
/* Configure the QuadSPI clock source */
__HAL_RCC_QSPI_CONFIG(PeriphClkInit->QspiClockSelection);
if(PeriphClkInit->QspiClockSelection == RCC_QSPICLKSOURCE_PLL)
{
/* Enable PLL48M1CLK output */
__HAL_RCC_PLLCLKOUT_ENABLE(RCC_PLL_48M1CLK);
}
}
#endif /* QUADSPI */
return status;
}
/**
* @brief Get the RCC_ClkInitStruct according to the internal RCC configuration registers.
* @param PeriphClkInit pointer to an RCC_PeriphCLKInitTypeDef structure that
* returns the configuration information for the Extended Peripherals
* clocks(USART1, USART2, USART3, UART4, UART5, LPUART1, I2C1, I2C2, I2C3, I2C4,
* LPTIM1, SAI1, I2Sx, FDCANx, USB, RNG, ADCx, RTC, QSPI).
* @retval None
*/
void HAL_RCCEx_GetPeriphCLKConfig(RCC_PeriphCLKInitTypeDef *PeriphClkInit)
{
/* Set all possible values for the extended clock type parameter------------*/
#if defined(STM32G474xx) || defined(STM32G484xx)
PeriphClkInit->PeriphClockSelection = RCC_PERIPHCLK_USART1 | RCC_PERIPHCLK_USART2 | RCC_PERIPHCLK_USART3 | RCC_PERIPHCLK_UART4 | \
RCC_PERIPHCLK_UART5 | \
RCC_PERIPHCLK_LPUART1 | RCC_PERIPHCLK_I2C1 | RCC_PERIPHCLK_I2C2 | RCC_PERIPHCLK_I2C3 | \
RCC_PERIPHCLK_I2C4 | \
RCC_PERIPHCLK_LPTIM1 | RCC_PERIPHCLK_SAI1 | RCC_PERIPHCLK_I2S | RCC_PERIPHCLK_FDCAN | \
RCC_PERIPHCLK_RNG | RCC_PERIPHCLK_USB | RCC_PERIPHCLK_ADC12 | RCC_PERIPHCLK_ADC345 | \
RCC_PERIPHCLK_QSPI | \
RCC_PERIPHCLK_RTC;
#elif defined(STM32G491xx) || defined(STM32G4A1xx)
PeriphClkInit->PeriphClockSelection = RCC_PERIPHCLK_USART1 | RCC_PERIPHCLK_USART2 | RCC_PERIPHCLK_USART3 | RCC_PERIPHCLK_UART4 | \
RCC_PERIPHCLK_UART5 | \
RCC_PERIPHCLK_LPUART1 | RCC_PERIPHCLK_I2C1 | RCC_PERIPHCLK_I2C2 | RCC_PERIPHCLK_I2C3 | \
RCC_PERIPHCLK_LPTIM1 | RCC_PERIPHCLK_SAI1 | RCC_PERIPHCLK_I2S | RCC_PERIPHCLK_FDCAN | \
RCC_PERIPHCLK_RNG | RCC_PERIPHCLK_USB | RCC_PERIPHCLK_ADC12 | RCC_PERIPHCLK_ADC345 | \
RCC_PERIPHCLK_QSPI | \
RCC_PERIPHCLK_RTC;
#elif defined(STM32G473xx) || defined(STM32G483xx)
PeriphClkInit->PeriphClockSelection = RCC_PERIPHCLK_USART1 | RCC_PERIPHCLK_USART2 | RCC_PERIPHCLK_USART3 | RCC_PERIPHCLK_UART4 | \
RCC_PERIPHCLK_UART5 | \
RCC_PERIPHCLK_LPUART1 | RCC_PERIPHCLK_I2C1 | RCC_PERIPHCLK_I2C2 | RCC_PERIPHCLK_I2C3 | \
RCC_PERIPHCLK_I2C4 | \
RCC_PERIPHCLK_LPTIM1 | RCC_PERIPHCLK_SAI1 | RCC_PERIPHCLK_I2S | \
RCC_PERIPHCLK_RNG | RCC_PERIPHCLK_USB | RCC_PERIPHCLK_ADC12 | RCC_PERIPHCLK_ADC345 | \
RCC_PERIPHCLK_QSPI | \
RCC_PERIPHCLK_RTC;
#elif defined(STM32G471xx)
PeriphClkInit->PeriphClockSelection = RCC_PERIPHCLK_USART1 | RCC_PERIPHCLK_USART2 | RCC_PERIPHCLK_USART3 | RCC_PERIPHCLK_UART4 | \
RCC_PERIPHCLK_UART5 | \
RCC_PERIPHCLK_LPUART1 | RCC_PERIPHCLK_I2C1 | RCC_PERIPHCLK_I2C2 | RCC_PERIPHCLK_I2C3 | \
RCC_PERIPHCLK_I2C4 | \
RCC_PERIPHCLK_LPTIM1 | RCC_PERIPHCLK_SAI1 | RCC_PERIPHCLK_I2S | \
RCC_PERIPHCLK_RNG | RCC_PERIPHCLK_USB | RCC_PERIPHCLK_ADC12 | \
RCC_PERIPHCLK_RTC;
#elif defined(STM32G431xx) || defined(STM32G441xx)
PeriphClkInit->PeriphClockSelection = RCC_PERIPHCLK_USART1 | RCC_PERIPHCLK_USART2 | RCC_PERIPHCLK_USART3 | RCC_PERIPHCLK_UART4 | \
RCC_PERIPHCLK_LPUART1 | RCC_PERIPHCLK_I2C1 | RCC_PERIPHCLK_I2C2 | RCC_PERIPHCLK_I2C3 | \
RCC_PERIPHCLK_LPTIM1 | RCC_PERIPHCLK_SAI1 | RCC_PERIPHCLK_I2S | RCC_PERIPHCLK_FDCAN | \
RCC_PERIPHCLK_RNG | RCC_PERIPHCLK_USB | RCC_PERIPHCLK_ADC12 | \
RCC_PERIPHCLK_RTC;
#elif defined(STM32GBK1CB)
PeriphClkInit->PeriphClockSelection = RCC_PERIPHCLK_USART1 | RCC_PERIPHCLK_USART2 | RCC_PERIPHCLK_USART3 | \
RCC_PERIPHCLK_LPUART1 | RCC_PERIPHCLK_I2C1 | RCC_PERIPHCLK_I2C2 | RCC_PERIPHCLK_I2C3 | \
RCC_PERIPHCLK_LPTIM1 | RCC_PERIPHCLK_SAI1 | RCC_PERIPHCLK_I2S | RCC_PERIPHCLK_FDCAN | \
RCC_PERIPHCLK_RNG | RCC_PERIPHCLK_USB | RCC_PERIPHCLK_ADC12 | \
RCC_PERIPHCLK_RTC;
#endif /* STM32G431xx */
/* Get the USART1 clock source ---------------------------------------------*/
PeriphClkInit->Usart1ClockSelection = __HAL_RCC_GET_USART1_SOURCE();
/* Get the USART2 clock source ---------------------------------------------*/
PeriphClkInit->Usart2ClockSelection = __HAL_RCC_GET_USART2_SOURCE();
/* Get the USART3 clock source ---------------------------------------------*/
PeriphClkInit->Usart3ClockSelection = __HAL_RCC_GET_USART3_SOURCE();
#if defined(UART4)
/* Get the UART4 clock source ----------------------------------------------*/
PeriphClkInit->Uart4ClockSelection = __HAL_RCC_GET_UART4_SOURCE();
#endif /* UART4 */
#if defined(UART5)
/* Get the UART5 clock source ----------------------------------------------*/
PeriphClkInit->Uart5ClockSelection = __HAL_RCC_GET_UART5_SOURCE();
#endif /* UART5 */
/* Get the LPUART1 clock source --------------------------------------------*/
PeriphClkInit->Lpuart1ClockSelection = __HAL_RCC_GET_LPUART1_SOURCE();
/* Get the I2C1 clock source -----------------------------------------------*/
PeriphClkInit->I2c1ClockSelection = __HAL_RCC_GET_I2C1_SOURCE();
/* Get the I2C2 clock source ----------------------------------------------*/
PeriphClkInit->I2c2ClockSelection = __HAL_RCC_GET_I2C2_SOURCE();
/* Get the I2C3 clock source -----------------------------------------------*/
PeriphClkInit->I2c3ClockSelection = __HAL_RCC_GET_I2C3_SOURCE();
#if defined(I2C4)
/* Get the I2C4 clock source -----------------------------------------------*/
PeriphClkInit->I2c4ClockSelection = __HAL_RCC_GET_I2C4_SOURCE();
#endif /* I2C4 */
/* Get the LPTIM1 clock source ---------------------------------------------*/
PeriphClkInit->Lptim1ClockSelection = __HAL_RCC_GET_LPTIM1_SOURCE();
/* Get the SAI1 clock source -----------------------------------------------*/
PeriphClkInit->Sai1ClockSelection = __HAL_RCC_GET_SAI1_SOURCE();
/* Get the I2S clock source -----------------------------------------------*/
PeriphClkInit->I2sClockSelection = __HAL_RCC_GET_I2S_SOURCE();
#if defined(FDCAN1)
/* Get the FDCAN clock source -----------------------------------------------*/
PeriphClkInit->FdcanClockSelection = __HAL_RCC_GET_FDCAN_SOURCE();
#endif /* FDCAN1 */
#if defined(USB)
/* Get the USB clock source ------------------------------------------------*/
PeriphClkInit->UsbClockSelection = __HAL_RCC_GET_USB_SOURCE();
#endif /* USB */
/* Get the RNG clock source ------------------------------------------------*/
PeriphClkInit->RngClockSelection = __HAL_RCC_GET_RNG_SOURCE();
/* Get the ADC12 clock source -----------------------------------------------*/
PeriphClkInit->Adc12ClockSelection = __HAL_RCC_GET_ADC12_SOURCE();
#if defined(ADC345_COMMON)
/* Get the ADC345 clock source ----------------------------------------------*/
PeriphClkInit->Adc345ClockSelection = __HAL_RCC_GET_ADC345_SOURCE();
#endif /* ADC345_COMMON */
#if defined(QUADSPI)
/* Get the QuadSPIclock source --------------------------------------------*/
PeriphClkInit->QspiClockSelection = __HAL_RCC_GET_QSPI_SOURCE();
#endif /* QUADSPI */
/* Get the RTC clock source ------------------------------------------------*/
PeriphClkInit->RTCClockSelection = __HAL_RCC_GET_RTC_SOURCE();
}
/**
* @brief Return the peripheral clock frequency for peripherals with clock source from PLL
* @note Return 0 if peripheral clock identifier not managed by this API
* @param PeriphClk Peripheral clock identifier
* This parameter can be one of the following values:
* @arg @ref RCC_PERIPHCLK_USART1 USART1 peripheral clock
* @arg @ref RCC_PERIPHCLK_USART2 USART2 peripheral clock
* @arg @ref RCC_PERIPHCLK_USART3 USART3 peripheral clock
* @arg @ref RCC_PERIPHCLK_UART4 UART4 peripheral clock (only for devices with UART4)
* @arg @ref RCC_PERIPHCLK_UART5 UART5 peripheral clock (only for devices with UART5)
* @arg @ref RCC_PERIPHCLK_LPUART1 LPUART1 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C1 I2C1 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C2 I2C2 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C3 I2C3 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2C4 I2C4 peripheral clock (only for devices with I2C4)
* @arg @ref RCC_PERIPHCLK_LPTIM1 LPTIM1 peripheral clock
* @arg @ref RCC_PERIPHCLK_SAI1 SAI1 peripheral clock
* @arg @ref RCC_PERIPHCLK_I2S SPI peripheral clock
* @arg @ref RCC_PERIPHCLK_FDCAN FDCAN peripheral clock (only for devices with FDCAN)
* @arg @ref RCC_PERIPHCLK_RNG RNG peripheral clock
* @arg @ref RCC_PERIPHCLK_USB USB peripheral clock (only for devices with USB)
* @arg @ref RCC_PERIPHCLK_ADC12 ADC1 and ADC2 peripheral clock
* @arg @ref RCC_PERIPHCLK_ADC345 ADC3, ADC4 and ADC5 peripheral clock (only for devices with ADC3, ADC4, ADC5)
* @arg @ref RCC_PERIPHCLK_QSPI QSPI peripheral clock (only for devices with QSPI)
* @arg @ref RCC_PERIPHCLK_RTC RTC peripheral clock
* @retval Frequency in Hz
*/
uint32_t HAL_RCCEx_GetPeriphCLKFreq(uint32_t PeriphClk)
{
uint32_t frequency = 0U;
uint32_t srcclk;
uint32_t pllvco, plln, pllp;
/* Check the parameters */
assert_param(IS_RCC_PERIPHCLOCK(PeriphClk));
if(PeriphClk == RCC_PERIPHCLK_RTC)
{
/* Get the current RTC source */
srcclk = __HAL_RCC_GET_RTC_SOURCE();
/* Check if LSE is ready and if RTC clock selection is LSE */
if ((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_RTCCLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Check if LSI is ready and if RTC clock selection is LSI */
else if ((HAL_IS_BIT_SET(RCC->CSR, RCC_CSR_LSIRDY)) && (srcclk == RCC_RTCCLKSOURCE_LSI))
{
frequency = LSI_VALUE;
}
/* Check if HSE is ready and if RTC clock selection is HSI_DIV32*/
else if ((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSERDY)) && (srcclk == RCC_RTCCLKSOURCE_HSE_DIV32))
{
frequency = HSE_VALUE / 32U;
}
/* Clock not enabled for RTC*/
else
{
/* nothing to do: frequency already initialized to 0 */
}
}
else
{
/* Other external peripheral clock source than RTC */
/* Compute PLL clock input */
if(__HAL_RCC_GET_PLL_OSCSOURCE() == RCC_PLLSOURCE_HSI) /* HSI ? */
{
if(HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY))
{
pllvco = HSI_VALUE;
}
else
{
pllvco = 0U;
}
}
else if(__HAL_RCC_GET_PLL_OSCSOURCE() == RCC_PLLSOURCE_HSE) /* HSE ? */
{
if(HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSERDY))
{
pllvco = HSE_VALUE;
}
else
{
pllvco = 0U;
}
}
else /* No source */
{
pllvco = 0U;
}
/* f(PLL Source) / PLLM */
pllvco = (pllvco / ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLM) >> RCC_PLLCFGR_PLLM_Pos) + 1U));
switch(PeriphClk)
{
case RCC_PERIPHCLK_USART1:
/* Get the current USART1 source */
srcclk = __HAL_RCC_GET_USART1_SOURCE();
if(srcclk == RCC_USART1CLKSOURCE_PCLK2)
{
frequency = HAL_RCC_GetPCLK2Freq();
}
else if(srcclk == RCC_USART1CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_USART1CLKSOURCE_HSI) )
{
frequency = HSI_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_USART1CLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Clock not enabled for USART1 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_USART2:
/* Get the current USART2 source */
srcclk = __HAL_RCC_GET_USART2_SOURCE();
if(srcclk == RCC_USART2CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_USART2CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_USART2CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_USART2CLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Clock not enabled for USART2 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_USART3:
/* Get the current USART3 source */
srcclk = __HAL_RCC_GET_USART3_SOURCE();
if(srcclk == RCC_USART3CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_USART3CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_USART3CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_USART3CLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Clock not enabled for USART3 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#if defined(UART4)
case RCC_PERIPHCLK_UART4:
/* Get the current UART4 source */
srcclk = __HAL_RCC_GET_UART4_SOURCE();
if(srcclk == RCC_UART4CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_UART4CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_UART4CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_UART4CLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Clock not enabled for UART4 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#endif /* UART4 */
#if defined(UART5)
case RCC_PERIPHCLK_UART5:
/* Get the current UART5 source */
srcclk = __HAL_RCC_GET_UART5_SOURCE();
if(srcclk == RCC_UART5CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_UART5CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_UART5CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_UART5CLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Clock not enabled for UART5 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#endif /* UART5 */
case RCC_PERIPHCLK_LPUART1:
/* Get the current LPUART1 source */
srcclk = __HAL_RCC_GET_LPUART1_SOURCE();
if(srcclk == RCC_LPUART1CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_LPUART1CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_LPUART1CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_LPUART1CLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Clock not enabled for LPUART1 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_I2C1:
/* Get the current I2C1 source */
srcclk = __HAL_RCC_GET_I2C1_SOURCE();
if(srcclk == RCC_I2C1CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_I2C1CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_I2C1CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
/* Clock not enabled for I2C1 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_I2C2:
/* Get the current I2C2 source */
srcclk = __HAL_RCC_GET_I2C2_SOURCE();
if(srcclk == RCC_I2C2CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_I2C2CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_I2C2CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
/* Clock not enabled for I2C2 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_I2C3:
/* Get the current I2C3 source */
srcclk = __HAL_RCC_GET_I2C3_SOURCE();
if(srcclk == RCC_I2C3CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_I2C3CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_I2C3CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
/* Clock not enabled for I2C3 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#if defined(I2C4)
case RCC_PERIPHCLK_I2C4:
/* Get the current I2C4 source */
srcclk = __HAL_RCC_GET_I2C4_SOURCE();
if(srcclk == RCC_I2C4CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_I2C4CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_I2C4CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
/* Clock not enabled for I2C4 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#endif /* I2C4 */
case RCC_PERIPHCLK_LPTIM1:
/* Get the current LPTIM1 source */
srcclk = __HAL_RCC_GET_LPTIM1_SOURCE();
if(srcclk == RCC_LPTIM1CLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if((HAL_IS_BIT_SET(RCC->CSR, RCC_CSR_LSIRDY)) && (srcclk == RCC_LPTIM1CLKSOURCE_LSI))
{
frequency = LSI_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_LPTIM1CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
else if ((HAL_IS_BIT_SET(RCC->BDCR, RCC_BDCR_LSERDY)) && (srcclk == RCC_LPTIM1CLKSOURCE_LSE))
{
frequency = LSE_VALUE;
}
/* Clock not enabled for LPTIM1 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_SAI1:
/* Get the current SAI1 source */
srcclk = __HAL_RCC_GET_SAI1_SOURCE();
if(srcclk == RCC_SAI1CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if(srcclk == RCC_SAI1CLKSOURCE_PLL)
{
if(__HAL_RCC_GET_PLLCLKOUT_CONFIG(RCC_PLL_48M1CLK) != 0U)
{
/* f(PLLQ) = f(VCO input) * PLLN / PLLQ */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
frequency = (pllvco * plln) / (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
}
}
else if(srcclk == RCC_SAI1CLKSOURCE_EXT)
{
/* External clock used.*/
frequency = EXTERNAL_CLOCK_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_SAI1CLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
/* Clock not enabled for SAI1 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_I2S:
/* Get the current I2Sx source */
srcclk = __HAL_RCC_GET_I2S_SOURCE();
if(srcclk == RCC_I2SCLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else if(srcclk == RCC_I2SCLKSOURCE_PLL)
{
if(__HAL_RCC_GET_PLLCLKOUT_CONFIG(RCC_PLL_48M1CLK) != 0U)
{
/* f(PLLQ) = f(VCO input) * PLLN / PLLQ */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
frequency = (pllvco * plln) / (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
}
}
else if(srcclk == RCC_I2SCLKSOURCE_EXT)
{
/* External clock used.*/
frequency = EXTERNAL_CLOCK_VALUE;
}
else if((HAL_IS_BIT_SET(RCC->CR, RCC_CR_HSIRDY)) && (srcclk == RCC_I2SCLKSOURCE_HSI))
{
frequency = HSI_VALUE;
}
/* Clock not enabled for I2S */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#if defined(FDCAN1)
case RCC_PERIPHCLK_FDCAN:
/* Get the current FDCANx source */
srcclk = __HAL_RCC_GET_FDCAN_SOURCE();
if(srcclk == RCC_FDCANCLKSOURCE_PCLK1)
{
frequency = HAL_RCC_GetPCLK1Freq();
}
else if(srcclk == RCC_FDCANCLKSOURCE_HSE)
{
frequency = HSE_VALUE;
}
else if(srcclk == RCC_FDCANCLKSOURCE_PLL)
{
if(__HAL_RCC_GET_PLLCLKOUT_CONFIG(RCC_PLL_48M1CLK) != 0U)
{
/* f(PLLQ) = f(VCO input) * PLLN / PLLQ */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
frequency = (pllvco * plln) / (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
}
}
/* Clock not enabled for FDCAN */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#endif /* FDCAN1 */
#if defined(USB)
case RCC_PERIPHCLK_USB:
/* Get the current USB source */
srcclk = __HAL_RCC_GET_USB_SOURCE();
if(srcclk == RCC_USBCLKSOURCE_PLL) /* PLL ? */
{
/* f(PLLQ) = f(VCO input) * PLLN / PLLQ */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
frequency = (pllvco * plln) / (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
}
else if((HAL_IS_BIT_SET(RCC->CRRCR, RCC_CRRCR_HSI48RDY)) && (srcclk == RCC_USBCLKSOURCE_HSI48)) /* HSI48 ? */
{
frequency = HSI48_VALUE;
}
else /* No clock source */
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#endif /* USB */
case RCC_PERIPHCLK_RNG:
/* Get the current RNG source */
srcclk = __HAL_RCC_GET_RNG_SOURCE();
if(srcclk == RCC_RNGCLKSOURCE_PLL) /* PLL ? */
{
/* f(PLLQ) = f(VCO input) * PLLN / PLLQ */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
frequency = (pllvco * plln) / (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
}
else if( (HAL_IS_BIT_SET(RCC->CRRCR, RCC_CRRCR_HSI48RDY)) && (srcclk == RCC_RNGCLKSOURCE_HSI48)) /* HSI48 ? */
{
frequency = HSI48_VALUE;
}
else /* No clock source */
{
/* nothing to do: frequency already initialized to 0 */
}
break;
case RCC_PERIPHCLK_ADC12:
/* Get the current ADC12 source */
srcclk = __HAL_RCC_GET_ADC12_SOURCE();
if(srcclk == RCC_ADC12CLKSOURCE_PLL)
{
if(__HAL_RCC_GET_PLLCLKOUT_CONFIG(RCC_PLL_ADCCLK) != 0U)
{
/* f(PLLP) = f(VCO input) * PLLN / PLLP */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
pllp = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPDIV) >> RCC_PLLCFGR_PLLPDIV_Pos;
if(pllp == 0U)
{
if(READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLP) != 0U)
{
pllp = 17U;
}
else
{
pllp = 7U;
}
}
frequency = (pllvco * plln) / pllp;
}
}
else if(srcclk == RCC_ADC12CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
/* Clock not enabled for ADC12 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#if defined(ADC345_COMMON)
case RCC_PERIPHCLK_ADC345:
/* Get the current ADC345 source */
srcclk = __HAL_RCC_GET_ADC345_SOURCE();
if(srcclk == RCC_ADC345CLKSOURCE_PLL)
{
if(__HAL_RCC_GET_PLLCLKOUT_CONFIG(RCC_PLL_ADCCLK) != 0U)
{
/* f(PLLP) = f(VCO input) * PLLN / PLLP */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
pllp = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPDIV) >> RCC_PLLCFGR_PLLPDIV_Pos;
if(pllp == 0U)
{
if(READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLP) != 0U)
{
pllp = 17U;
}
else
{
pllp = 7U;
}
}
frequency = (pllvco * plln) / pllp;
}
}
else if(srcclk == RCC_ADC345CLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
/* Clock not enabled for ADC345 */
else
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#endif /* ADC345_COMMON */
#if defined(QUADSPI)
case RCC_PERIPHCLK_QSPI:
/* Get the current QSPI source */
srcclk = __HAL_RCC_GET_QSPI_SOURCE();
if(srcclk == RCC_QSPICLKSOURCE_PLL) /* PLL ? */
{
/* f(PLLQ) = f(VCO input) * PLLN / PLLQ */
plln = READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos;
frequency = (pllvco * plln) / (((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U);
}
else if(srcclk == RCC_QSPICLKSOURCE_HSI)
{
frequency = HSI_VALUE;
}
else if(srcclk == RCC_QSPICLKSOURCE_SYSCLK)
{
frequency = HAL_RCC_GetSysClockFreq();
}
else /* No clock source */
{
/* nothing to do: frequency already initialized to 0 */
}
break;
#endif /* QUADSPI */
default:
break;
}
}
return(frequency);
}
/**
* @}
*/
/** @defgroup RCCEx_Exported_Functions_Group2 Extended Clock management functions
* @brief Extended Clock management functions
*
@verbatim
===============================================================================
##### Extended clock management functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the
activation or deactivation of LSE CSS,
Low speed clock output and clock after wake-up from STOP mode.
@endverbatim
* @{
*/
/**
* @brief Enable the LSE Clock Security System.
* @note Prior to enable the LSE Clock Security System, LSE oscillator is to be enabled
* with HAL_RCC_OscConfig() and the LSE oscillator clock is to be selected as RTC
* clock with HAL_RCCEx_PeriphCLKConfig().
* @retval None
*/
void HAL_RCCEx_EnableLSECSS(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_LSECSSON) ;
}
/**
* @brief Disable the LSE Clock Security System.
* @note LSE Clock Security System can only be disabled after a LSE failure detection.
* @retval None
*/
void HAL_RCCEx_DisableLSECSS(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSECSSON) ;
/* Disable LSE CSS IT if any */
__HAL_RCC_DISABLE_IT(RCC_IT_LSECSS);
}
/**
* @brief Enable the LSE Clock Security System Interrupt & corresponding EXTI line.
* @note LSE Clock Security System Interrupt is mapped on RTC EXTI line 19
* @retval None
*/
void HAL_RCCEx_EnableLSECSS_IT(void)
{
/* Enable LSE CSS */
SET_BIT(RCC->BDCR, RCC_BDCR_LSECSSON) ;
/* Enable LSE CSS IT */
__HAL_RCC_ENABLE_IT(RCC_IT_LSECSS);
/* Enable IT on EXTI Line 19 */
__HAL_RCC_LSECSS_EXTI_ENABLE_IT();
__HAL_RCC_LSECSS_EXTI_ENABLE_RISING_EDGE();
}
/**
* @brief Handle the RCC LSE Clock Security System interrupt request.
* @retval None
*/
void HAL_RCCEx_LSECSS_IRQHandler(void)
{
/* Check RCC LSE CSSF flag */
if(__HAL_RCC_GET_IT(RCC_IT_LSECSS))
{
/* RCC LSE Clock Security System interrupt user callback */
HAL_RCCEx_LSECSS_Callback();
/* Clear RCC LSE CSS pending bit */
__HAL_RCC_CLEAR_IT(RCC_IT_LSECSS);
}
}
/**
* @brief RCCEx LSE Clock Security System interrupt callback.
* @retval none
*/
__weak void HAL_RCCEx_LSECSS_Callback(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the @ref HAL_RCCEx_LSECSS_Callback should be implemented in the user file
*/
}
/**
* @brief Select the Low Speed clock source to output on LSCO pin (PA2).
* @param LSCOSource specifies the Low Speed clock source to output.
* This parameter can be one of the following values:
* @arg @ref RCC_LSCOSOURCE_LSI LSI clock selected as LSCO source
* @arg @ref RCC_LSCOSOURCE_LSE LSE clock selected as LSCO source
* @retval None
*/
void HAL_RCCEx_EnableLSCO(uint32_t LSCOSource)
{
GPIO_InitTypeDef GPIO_InitStruct;
FlagStatus pwrclkchanged = RESET;
FlagStatus backupchanged = RESET;
/* Check the parameters */
assert_param(IS_RCC_LSCOSOURCE(LSCOSource));
/* LSCO Pin Clock Enable */
__LSCO_CLK_ENABLE();
/* Configure the LSCO pin in analog mode */
GPIO_InitStruct.Pin = LSCO_PIN;
GPIO_InitStruct.Mode = GPIO_MODE_ANALOG;
GPIO_InitStruct.Speed = GPIO_SPEED_FREQ_HIGH;
GPIO_InitStruct.Pull = GPIO_NOPULL;
HAL_GPIO_Init(LSCO_GPIO_PORT, &GPIO_InitStruct);
/* Update LSCOSEL clock source in Backup Domain control register */
if(__HAL_RCC_PWR_IS_CLK_DISABLED())
{
__HAL_RCC_PWR_CLK_ENABLE();
pwrclkchanged = SET;
}
if(HAL_IS_BIT_CLR(PWR->CR1, PWR_CR1_DBP))
{
HAL_PWR_EnableBkUpAccess();
backupchanged = SET;
}
MODIFY_REG(RCC->BDCR, RCC_BDCR_LSCOSEL | RCC_BDCR_LSCOEN, LSCOSource | RCC_BDCR_LSCOEN);
if(backupchanged == SET)
{
HAL_PWR_DisableBkUpAccess();
}
if(pwrclkchanged == SET)
{
__HAL_RCC_PWR_CLK_DISABLE();
}
}
/**
* @brief Disable the Low Speed clock output.
* @retval None
*/
void HAL_RCCEx_DisableLSCO(void)
{
FlagStatus pwrclkchanged = RESET;
FlagStatus backupchanged = RESET;
/* Update LSCOEN bit in Backup Domain control register */
if(__HAL_RCC_PWR_IS_CLK_DISABLED())
{
__HAL_RCC_PWR_CLK_ENABLE();
pwrclkchanged = SET;
}
if(HAL_IS_BIT_CLR(PWR->CR1, PWR_CR1_DBP))
{
/* Enable access to the backup domain */
HAL_PWR_EnableBkUpAccess();
backupchanged = SET;
}
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSCOEN);
/* Restore previous configuration */
if(backupchanged == SET)
{
/* Disable access to the backup domain */
HAL_PWR_DisableBkUpAccess();
}
if(pwrclkchanged == SET)
{
__HAL_RCC_PWR_CLK_DISABLE();
}
}
/**
* @}
*/
#if defined(CRS)
/** @defgroup RCCEx_Exported_Functions_Group3 Extended Clock Recovery System Control functions
* @brief Extended Clock Recovery System Control functions
*
@verbatim
===============================================================================
##### Extended Clock Recovery System Control functions #####
===============================================================================
[..]
For devices with Clock Recovery System feature (CRS), RCC Extension HAL driver can be used as follows:
(#) In System clock config, HSI48 needs to be enabled
(#) Enable CRS clock in IP MSP init which will use CRS functions
(#) Call CRS functions as follows:
(##) Prepare synchronization configuration necessary for HSI48 calibration
(+++) Default values can be set for frequency Error Measurement (reload and error limit)
and also HSI48 oscillator smooth trimming.
(+++) Macro __HAL_RCC_CRS_RELOADVALUE_CALCULATE can be also used to calculate
directly reload value with target and sychronization frequencies values
(##) Call function HAL_RCCEx_CRSConfig which
(+++) Resets CRS registers to their default values.
(+++) Configures CRS registers with synchronization configuration
(+++) Enables automatic calibration and frequency error counter feature
Note: When using USB LPM (Link Power Management) and the device is in Sleep mode, the
periodic USB SOF will not be generated by the host. No SYNC signal will therefore be
provided to the CRS to calibrate the HSI48 on the run. To guarantee the required clock
precision after waking up from Sleep mode, the LSE or reference clock on the GPIOs
should be used as SYNC signal.
(##) A polling function is provided to wait for complete synchronization
(+++) Call function HAL_RCCEx_CRSWaitSynchronization()
(+++) According to CRS status, user can decide to adjust again the calibration or continue
application if synchronization is OK
(#) User can retrieve information related to synchronization in calling function
HAL_RCCEx_CRSGetSynchronizationInfo()
(#) Regarding synchronization status and synchronization information, user can try a new calibration
in changing synchronization configuration and call again HAL_RCCEx_CRSConfig.
Note: When the SYNC event is detected during the downcounting phase (before reaching the zero value),
it means that the actual frequency is lower than the target (and so, that the TRIM value should be
incremented), while when it is detected during the upcounting phase it means that the actual frequency
is higher (and that the TRIM value should be decremented).
(#) In interrupt mode, user can resort to the available macros (__HAL_RCC_CRS_XXX_IT). Interrupts will go
through CRS Handler (CRS_IRQn/CRS_IRQHandler)
(++) Call function HAL_RCCEx_CRSConfig()
(++) Enable CRS_IRQn (thanks to NVIC functions)
(++) Enable CRS interrupt (__HAL_RCC_CRS_ENABLE_IT)
(++) Implement CRS status management in the following user callbacks called from
HAL_RCCEx_CRS_IRQHandler():
(+++) HAL_RCCEx_CRS_SyncOkCallback()
(+++) HAL_RCCEx_CRS_SyncWarnCallback()
(+++) HAL_RCCEx_CRS_ExpectedSyncCallback()
(+++) HAL_RCCEx_CRS_ErrorCallback()
(#) To force a SYNC EVENT, user can use the function HAL_RCCEx_CRSSoftwareSynchronizationGenerate().
This function can be called before calling HAL_RCCEx_CRSConfig (for instance in Systick handler)
@endverbatim
* @{
*/
/**
* @brief Start automatic synchronization for polling mode
* @param pInit Pointer on RCC_CRSInitTypeDef structure
* @retval None
*/
void HAL_RCCEx_CRSConfig(RCC_CRSInitTypeDef *pInit)
{
uint32_t value;
/* Check the parameters */
assert_param(IS_RCC_CRS_SYNC_DIV(pInit->Prescaler));
assert_param(IS_RCC_CRS_SYNC_SOURCE(pInit->Source));
assert_param(IS_RCC_CRS_SYNC_POLARITY(pInit->Polarity));
assert_param(IS_RCC_CRS_RELOADVALUE(pInit->ReloadValue));
assert_param(IS_RCC_CRS_ERRORLIMIT(pInit->ErrorLimitValue));
assert_param(IS_RCC_CRS_HSI48CALIBRATION(pInit->HSI48CalibrationValue));
/* CONFIGURATION */
/* Before configuration, reset CRS registers to their default values*/
__HAL_RCC_CRS_FORCE_RESET();
__HAL_RCC_CRS_RELEASE_RESET();
/* Set the SYNCDIV[2:0] bits according to Prescaler value */
/* Set the SYNCSRC[1:0] bits according to Source value */
/* Set the SYNCSPOL bit according to Polarity value */
value = (pInit->Prescaler | pInit->Source | pInit->Polarity);
/* Set the RELOAD[15:0] bits according to ReloadValue value */
value |= pInit->ReloadValue;
/* Set the FELIM[7:0] bits according to ErrorLimitValue value */
value |= (pInit->ErrorLimitValue << CRS_CFGR_FELIM_Pos);
WRITE_REG(CRS->CFGR, value);
/* Adjust HSI48 oscillator smooth trimming */
/* Set the TRIM[6:0] bits according to RCC_CRS_HSI48CalibrationValue value */
MODIFY_REG(CRS->CR, CRS_CR_TRIM, (pInit->HSI48CalibrationValue << CRS_CR_TRIM_Pos));
/* START AUTOMATIC SYNCHRONIZATION*/
/* Enable Automatic trimming & Frequency error counter */
SET_BIT(CRS->CR, CRS_CR_AUTOTRIMEN | CRS_CR_CEN);
}
/**
* @brief Generate the software synchronization event
* @retval None
*/
void HAL_RCCEx_CRSSoftwareSynchronizationGenerate(void)
{
SET_BIT(CRS->CR, CRS_CR_SWSYNC);
}
/**
* @brief Return synchronization info
* @param pSynchroInfo Pointer on RCC_CRSSynchroInfoTypeDef structure
* @retval None
*/
void HAL_RCCEx_CRSGetSynchronizationInfo(RCC_CRSSynchroInfoTypeDef *pSynchroInfo)
{
/* Check the parameter */
assert_param(pSynchroInfo != (void *)NULL);
/* Get the reload value */
pSynchroInfo->ReloadValue = (READ_BIT(CRS->CFGR, CRS_CFGR_RELOAD));
/* Get HSI48 oscillator smooth trimming */
pSynchroInfo->HSI48CalibrationValue = (READ_BIT(CRS->CR, CRS_CR_TRIM) >> CRS_CR_TRIM_Pos);
/* Get Frequency error capture */
pSynchroInfo->FreqErrorCapture = (READ_BIT(CRS->ISR, CRS_ISR_FECAP) >> CRS_ISR_FECAP_Pos);
/* Get Frequency error direction */
pSynchroInfo->FreqErrorDirection = (READ_BIT(CRS->ISR, CRS_ISR_FEDIR));
}
/**
* @brief Wait for CRS Synchronization status.
* @param Timeout Duration of the timeout
* @note Timeout is based on the maximum time to receive a SYNC event based on synchronization
* frequency.
* @note If Timeout set to HAL_MAX_DELAY, HAL_TIMEOUT will be never returned.
* @retval Combination of Synchronization status
* This parameter can be a combination of the following values:
* @arg @ref RCC_CRS_TIMEOUT
* @arg @ref RCC_CRS_SYNCOK
* @arg @ref RCC_CRS_SYNCWARN
* @arg @ref RCC_CRS_SYNCERR
* @arg @ref RCC_CRS_SYNCMISS
* @arg @ref RCC_CRS_TRIMOVF
*/
uint32_t HAL_RCCEx_CRSWaitSynchronization(uint32_t Timeout)
{
uint32_t crsstatus = RCC_CRS_NONE;
uint32_t tickstart;
/* Get timeout */
tickstart = HAL_GetTick();
/* Wait for CRS flag or timeout detection */
do
{
if(Timeout != HAL_MAX_DELAY)
{
if(((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
crsstatus = RCC_CRS_TIMEOUT;
}
}
/* Check CRS SYNCOK flag */
if(__HAL_RCC_CRS_GET_FLAG(RCC_CRS_FLAG_SYNCOK))
{
/* CRS SYNC event OK */
crsstatus |= RCC_CRS_SYNCOK;
/* Clear CRS SYNC event OK bit */
__HAL_RCC_CRS_CLEAR_FLAG(RCC_CRS_FLAG_SYNCOK);
}
/* Check CRS SYNCWARN flag */
if(__HAL_RCC_CRS_GET_FLAG(RCC_CRS_FLAG_SYNCWARN))
{
/* CRS SYNC warning */
crsstatus |= RCC_CRS_SYNCWARN;
/* Clear CRS SYNCWARN bit */
__HAL_RCC_CRS_CLEAR_FLAG(RCC_CRS_FLAG_SYNCWARN);
}
/* Check CRS TRIM overflow flag */
if(__HAL_RCC_CRS_GET_FLAG(RCC_CRS_FLAG_TRIMOVF))
{
/* CRS SYNC Error */
crsstatus |= RCC_CRS_TRIMOVF;
/* Clear CRS Error bit */
__HAL_RCC_CRS_CLEAR_FLAG(RCC_CRS_FLAG_TRIMOVF);
}
/* Check CRS Error flag */
if(__HAL_RCC_CRS_GET_FLAG(RCC_CRS_FLAG_SYNCERR))
{
/* CRS SYNC Error */
crsstatus |= RCC_CRS_SYNCERR;
/* Clear CRS Error bit */
__HAL_RCC_CRS_CLEAR_FLAG(RCC_CRS_FLAG_SYNCERR);
}
/* Check CRS SYNC Missed flag */
if(__HAL_RCC_CRS_GET_FLAG(RCC_CRS_FLAG_SYNCMISS))
{
/* CRS SYNC Missed */
crsstatus |= RCC_CRS_SYNCMISS;
/* Clear CRS SYNC Missed bit */
__HAL_RCC_CRS_CLEAR_FLAG(RCC_CRS_FLAG_SYNCMISS);
}
/* Check CRS Expected SYNC flag */
if(__HAL_RCC_CRS_GET_FLAG(RCC_CRS_FLAG_ESYNC))
{
/* frequency error counter reached a zero value */
__HAL_RCC_CRS_CLEAR_FLAG(RCC_CRS_FLAG_ESYNC);
}
} while(RCC_CRS_NONE == crsstatus);
return crsstatus;
}
/**
* @brief Handle the Clock Recovery System interrupt request.
* @retval None
*/
void HAL_RCCEx_CRS_IRQHandler(void)
{
uint32_t crserror = RCC_CRS_NONE;
/* Get current IT flags and IT sources values */
uint32_t itflags = READ_REG(CRS->ISR);
uint32_t itsources = READ_REG(CRS->CR);
/* Check CRS SYNCOK flag */
if(((itflags & RCC_CRS_FLAG_SYNCOK) != 0U) && ((itsources & RCC_CRS_IT_SYNCOK) != 0U))
{
/* Clear CRS SYNC event OK flag */
WRITE_REG(CRS->ICR, CRS_ICR_SYNCOKC);
/* user callback */
HAL_RCCEx_CRS_SyncOkCallback();
}
/* Check CRS SYNCWARN flag */
else if(((itflags & RCC_CRS_FLAG_SYNCWARN) != 0U) && ((itsources & RCC_CRS_IT_SYNCWARN) != 0U))
{
/* Clear CRS SYNCWARN flag */
WRITE_REG(CRS->ICR, CRS_ICR_SYNCWARNC);
/* user callback */
HAL_RCCEx_CRS_SyncWarnCallback();
}
/* Check CRS Expected SYNC flag */
else if(((itflags & RCC_CRS_FLAG_ESYNC) != 0U) && ((itsources & RCC_CRS_IT_ESYNC) != 0U))
{
/* frequency error counter reached a zero value */
WRITE_REG(CRS->ICR, CRS_ICR_ESYNCC);
/* user callback */
HAL_RCCEx_CRS_ExpectedSyncCallback();
}
/* Check CRS Error flags */
else
{
if(((itflags & RCC_CRS_FLAG_ERR) != 0U) && ((itsources & RCC_CRS_IT_ERR) != 0U))
{
if((itflags & RCC_CRS_FLAG_SYNCERR) != 0U)
{
crserror |= RCC_CRS_SYNCERR;
}
if((itflags & RCC_CRS_FLAG_SYNCMISS) != 0U)
{
crserror |= RCC_CRS_SYNCMISS;
}
if((itflags & RCC_CRS_FLAG_TRIMOVF) != 0U)
{
crserror |= RCC_CRS_TRIMOVF;
}
/* Clear CRS Error flags */
WRITE_REG(CRS->ICR, CRS_ICR_ERRC);
/* user error callback */
HAL_RCCEx_CRS_ErrorCallback(crserror);
}
}
}
/**
* @brief RCCEx Clock Recovery System SYNCOK interrupt callback.
* @retval none
*/
__weak void HAL_RCCEx_CRS_SyncOkCallback(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the @ref HAL_RCCEx_CRS_SyncOkCallback should be implemented in the user file
*/
}
/**
* @brief RCCEx Clock Recovery System SYNCWARN interrupt callback.
* @retval none
*/
__weak void HAL_RCCEx_CRS_SyncWarnCallback(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the @ref HAL_RCCEx_CRS_SyncWarnCallback should be implemented in the user file
*/
}
/**
* @brief RCCEx Clock Recovery System Expected SYNC interrupt callback.
* @retval none
*/
__weak void HAL_RCCEx_CRS_ExpectedSyncCallback(void)
{
/* NOTE : This function should not be modified, when the callback is needed,
the @ref HAL_RCCEx_CRS_ExpectedSyncCallback should be implemented in the user file
*/
}
/**
* @brief RCCEx Clock Recovery System Error interrupt callback.
* @param Error Combination of Error status.
* This parameter can be a combination of the following values:
* @arg @ref RCC_CRS_SYNCERR
* @arg @ref RCC_CRS_SYNCMISS
* @arg @ref RCC_CRS_TRIMOVF
* @retval none
*/
__weak void HAL_RCCEx_CRS_ErrorCallback(uint32_t Error)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(Error);
/* NOTE : This function should not be modified, when the callback is needed,
the @ref HAL_RCCEx_CRS_ErrorCallback should be implemented in the user file
*/
}
/**
* @}
*/
#endif /* CRS */
/**
* @}
*/
/** @addtogroup RCCEx_Private_Functions
* @{
*/
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_RCC_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 62,528 | C | 33.243702 | 136 | 0.581771 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_flash.c | /**
******************************************************************************
* @file stm32g4xx_hal_flash.c
* @author MCD Application Team
* @brief FLASH HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the internal FLASH memory:
* + Program operations functions
* + Memory Control functions
* + Peripheral Errors functions
*
@verbatim
==============================================================================
##### FLASH peripheral features #####
==============================================================================
[..] The Flash memory interface manages CPU AHB I-Code and D-Code accesses
to the Flash memory. It implements the erase and program Flash memory operations
and the read and write protection mechanisms.
[..] The Flash memory interface accelerates code execution with a system of instruction
prefetch and cache lines.
[..] The FLASH main features are:
(+) Flash memory read operations
(+) Flash memory program/erase operations
(+) Read / write protections
(+) Option bytes programming
(+) Prefetch on I-Code
(+) 32 cache lines of 4*64 or 2*128 bits on I-Code
(+) 8 cache lines of 4*64 or 2*128 bits on D-Code
(+) Error code correction (ECC) : Data in flash are 72-bits word
(8 bits added per double word)
##### How to use this driver #####
==============================================================================
[..]
This driver provides functions and macros to configure and program the FLASH
memory of all STM32G4xx devices.
(#) Flash Memory IO Programming functions:
(++) Lock and Unlock the FLASH interface using HAL_FLASH_Unlock() and
HAL_FLASH_Lock() functions
(++) Program functions: double word and fast program (full row programming)
(++) There are two modes of programming :
(+++) Polling mode using HAL_FLASH_Program() function
(+++) Interrupt mode using HAL_FLASH_Program_IT() function
(#) Interrupts and flags management functions:
(++) Handle FLASH interrupts by calling HAL_FLASH_IRQHandler()
(++) Callback functions are called when the flash operations are finished :
HAL_FLASH_EndOfOperationCallback() when everything is ok, otherwise
HAL_FLASH_OperationErrorCallback()
(++) Get error flag status by calling HAL_GetError()
(#) Option bytes management functions:
(++) Lock and Unlock the option bytes using HAL_FLASH_OB_Unlock() and
HAL_FLASH_OB_Lock() functions
(++) Launch the reload of the option bytes using HAL_FLASH_Launch() function.
In this case, a reset is generated
[..]
In addition to these functions, this driver includes a set of macros allowing
to handle the following operations:
(+) Set the latency
(+) Enable/Disable the prefetch buffer
(+) Enable/Disable the Instruction cache and the Data cache
(+) Reset the Instruction cache and the Data cache
(+) Enable/Disable the Flash power-down during low-power run and sleep modes
(+) Enable/Disable the Flash interrupts
(+) Monitor the Flash flags status
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup FLASH FLASH
* @brief FLASH HAL module driver
* @{
*/
#ifdef HAL_FLASH_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private defines -----------------------------------------------------------*/
/** @defgroup FLASH_Private_Constants FLASH Private Constants
* @{
*/
#define FLASH_NB_DOUBLE_WORDS_IN_ROW 32
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup FLASH_Private_Variables FLASH Private Variables
* @{
*/
/**
* @brief Variable used for Program/Erase sectors under interruption
*/
FLASH_ProcessTypeDef pFlash = {.Lock = HAL_UNLOCKED,
.ErrorCode = HAL_FLASH_ERROR_NONE,
.ProcedureOnGoing = FLASH_PROC_NONE,
.Address = 0U,
.Bank = FLASH_BANK_1,
.Page = 0U,
.NbPagesToErase = 0U,
.CacheToReactivate = FLASH_CACHE_DISABLED};
/**
* @}
*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup FLASH_Private_Functions FLASH Private Functions
* @{
*/
static void FLASH_Program_DoubleWord(uint32_t Address, uint64_t Data);
static void FLASH_Program_Fast(uint32_t Address, uint32_t DataAddress);
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup FLASH_Exported_Functions FLASH Exported Functions
* @{
*/
/** @defgroup FLASH_Exported_Functions_Group1 Programming operation functions
* @brief Programming operation functions
*
@verbatim
===============================================================================
##### Programming operation functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to manage the FLASH
program operations.
@endverbatim
* @{
*/
/**
* @brief Program double word or fast program of a row at a specified address.
* @param TypeProgram Indicate the way to program at a specified address.
* This parameter can be a value of @ref FLASH_Type_Program.
* @param Address specifies the address to be programmed.
* @param Data specifies the data to be programmed.
* This parameter is the data for the double word program and the address where
* are stored the data for the row fast program.
*
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASH_Program(uint32_t TypeProgram, uint32_t Address, uint64_t Data)
{
HAL_StatusTypeDef status;
uint32_t prog_bit = 0;
/* Check the parameters */
assert_param(IS_FLASH_TYPEPROGRAM(TypeProgram));
/* Process Locked */
__HAL_LOCK(&pFlash);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
pFlash.ErrorCode = HAL_FLASH_ERROR_NONE;
/* Deactivate the data cache if they are activated to avoid data misbehavior */
if(READ_BIT(FLASH->ACR, FLASH_ACR_DCEN) != 0U)
{
/* Disable data cache */
__HAL_FLASH_DATA_CACHE_DISABLE();
pFlash.CacheToReactivate = FLASH_CACHE_DCACHE_ENABLED;
}
else
{
pFlash.CacheToReactivate = FLASH_CACHE_DISABLED;
}
if (TypeProgram == FLASH_TYPEPROGRAM_DOUBLEWORD)
{
/* Program double-word (64-bit) at a specified address */
FLASH_Program_DoubleWord(Address, Data);
prog_bit = FLASH_CR_PG;
}
else if ((TypeProgram == FLASH_TYPEPROGRAM_FAST) || (TypeProgram == FLASH_TYPEPROGRAM_FAST_AND_LAST))
{
/* Fast program a 32 row double-word (64-bit) at a specified address */
FLASH_Program_Fast(Address, (uint32_t)Data);
/* If it is the last row, the bit will be cleared at the end of the operation */
if (TypeProgram == FLASH_TYPEPROGRAM_FAST_AND_LAST)
{
prog_bit = FLASH_CR_FSTPG;
}
}
else
{
/* Nothing to do */
}
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
/* If the program operation is completed, disable the PG or FSTPG Bit */
if (prog_bit != 0U)
{
CLEAR_BIT(FLASH->CR, prog_bit);
}
/* Flush the caches to be sure of the data consistency */
FLASH_FlushCaches();
}
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
/* return status */
return status;
}
/**
* @brief Program double word or fast program of a row at a specified address with interrupt enabled.
* @param TypeProgram Indicate the way to program at a specified address.
* This parameter can be a value of @ref FLASH_Type_Program.
* @param Address specifies the address to be programmed.
* @param Data specifies the data to be programmed.
* This parameter is the data for the double word program and the address where
* are stored the data for the row fast program.
*
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASH_Program_IT(uint32_t TypeProgram, uint32_t Address, uint64_t Data)
{
HAL_StatusTypeDef status;
/* Check the parameters */
assert_param(IS_FLASH_TYPEPROGRAM(TypeProgram));
/* Process Locked */
__HAL_LOCK(&pFlash);
/* Reset error code */
pFlash.ErrorCode = HAL_FLASH_ERROR_NONE;
/* Deactivate the data cache if they are activated to avoid data misbehavior */
if(READ_BIT(FLASH->ACR, FLASH_ACR_DCEN) != 0U)
{
/* Disable data cache */
__HAL_FLASH_DATA_CACHE_DISABLE();
pFlash.CacheToReactivate = FLASH_CACHE_DCACHE_ENABLED;
}
else
{
pFlash.CacheToReactivate = FLASH_CACHE_DISABLED;
}
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation(FLASH_TIMEOUT_VALUE);
if (status != HAL_OK)
{
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
}
else
{
/* Set internal variables used by the IRQ handler */
if (TypeProgram == FLASH_TYPEPROGRAM_FAST_AND_LAST)
{
pFlash.ProcedureOnGoing = FLASH_PROC_PROGRAM_LAST;
}
else
{
pFlash.ProcedureOnGoing = FLASH_PROC_PROGRAM;
}
pFlash.Address = Address;
/* Enable End of Operation and Error interrupts */
__HAL_FLASH_ENABLE_IT(FLASH_IT_EOP | FLASH_IT_OPERR);
if (TypeProgram == FLASH_TYPEPROGRAM_DOUBLEWORD)
{
/* Program double-word (64-bit) at a specified address */
FLASH_Program_DoubleWord(Address, Data);
}
else if ((TypeProgram == FLASH_TYPEPROGRAM_FAST) || (TypeProgram == FLASH_TYPEPROGRAM_FAST_AND_LAST))
{
/* Fast program a 32 row double-word (64-bit) at a specified address */
FLASH_Program_Fast(Address, (uint32_t)Data);
}
else
{
/* Nothing to do */
}
}
return status;
}
/**
* @brief Handle FLASH interrupt request.
* @retval None
*/
void HAL_FLASH_IRQHandler(void)
{
uint32_t tmp_page;
uint32_t error;
FLASH_ProcedureTypeDef procedure;
/* If the operation is completed, disable the PG, PNB, MER1, MER2 and PER Bit */
CLEAR_BIT(FLASH->CR, (FLASH_CR_PG | FLASH_CR_MER1 | FLASH_CR_PER | FLASH_CR_PNB));
#if defined (FLASH_OPTR_DBANK)
CLEAR_BIT(FLASH->CR, FLASH_CR_MER2);
#endif
/* Disable the FSTPG Bit only if it is the last row programmed */
if (pFlash.ProcedureOnGoing == FLASH_PROC_PROGRAM_LAST)
{
CLEAR_BIT(FLASH->CR, FLASH_CR_FSTPG);
}
/* Check FLASH operation error flags */
error = (FLASH->SR & FLASH_FLAG_SR_ERRORS);
if (error != 0U)
{
/* Save the error code */
pFlash.ErrorCode |= error;
/* Clear error programming flags */
__HAL_FLASH_CLEAR_FLAG(error);
/* Flush the caches to be sure of the data consistency */
FLASH_FlushCaches();
/* FLASH error interrupt user callback */
procedure = pFlash.ProcedureOnGoing;
if (procedure == FLASH_PROC_PAGE_ERASE)
{
HAL_FLASH_OperationErrorCallback(pFlash.Page);
}
else if (procedure == FLASH_PROC_MASS_ERASE)
{
HAL_FLASH_OperationErrorCallback(pFlash.Bank);
}
else if ((procedure == FLASH_PROC_PROGRAM) ||
(procedure == FLASH_PROC_PROGRAM_LAST))
{
HAL_FLASH_OperationErrorCallback(pFlash.Address);
}
else
{
/* Nothing to do */
}
/*Stop the procedure ongoing*/
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
}
/* Check FLASH End of Operation flag */
if (__HAL_FLASH_GET_FLAG(FLASH_FLAG_EOP))
{
/* Clear FLASH End of Operation pending bit */
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_EOP);
if (pFlash.ProcedureOnGoing == FLASH_PROC_PAGE_ERASE)
{
/* Nb of pages to erased can be decreased */
pFlash.NbPagesToErase--;
/* Check if there are still pages to erase*/
if (pFlash.NbPagesToErase != 0U)
{
/* Indicate user which page has been erased*/
HAL_FLASH_EndOfOperationCallback(pFlash.Page);
/* Increment page number */
pFlash.Page++;
tmp_page = pFlash.Page;
FLASH_PageErase(tmp_page, pFlash.Bank);
}
else
{
/* No more pages to Erase */
/* Reset Address and stop Erase pages procedure */
pFlash.Page = 0xFFFFFFFFU;
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
/* Flush the caches to be sure of the data consistency */
FLASH_FlushCaches();
/* FLASH EOP interrupt user callback */
HAL_FLASH_EndOfOperationCallback(pFlash.Page);
}
}
else
{
/* Flush the caches to be sure of the data consistency */
FLASH_FlushCaches();
procedure = pFlash.ProcedureOnGoing;
if (procedure == FLASH_PROC_MASS_ERASE)
{
/* MassErase ended. Return the selected bank */
/* FLASH EOP interrupt user callback */
HAL_FLASH_EndOfOperationCallback(pFlash.Bank);
}
else if ((procedure == FLASH_PROC_PROGRAM) ||
(procedure == FLASH_PROC_PROGRAM_LAST))
{
/* Program ended. Return the selected address */
/* FLASH EOP interrupt user callback */
HAL_FLASH_EndOfOperationCallback(pFlash.Address);
}
else
{
/* Nothing to do */
}
/*Clear the procedure ongoing*/
pFlash.ProcedureOnGoing = FLASH_PROC_NONE;
}
}
if (pFlash.ProcedureOnGoing == FLASH_PROC_NONE)
{
/* Disable End of Operation and Error interrupts */
__HAL_FLASH_DISABLE_IT(FLASH_IT_EOP | FLASH_IT_OPERR);
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
}
}
/**
* @brief FLASH end of operation interrupt callback.
* @param ReturnValue The value saved in this parameter depends on the ongoing procedure:
* @arg Mass Erase: Bank number which has been requested to erase
* @arg Page Erase: Page which has been erased
* (if 0xFFFFFFFF, it means that all the selected pages have been erased)
* @arg Program: Address which was selected for data program
* @retval None
*/
__weak void HAL_FLASH_EndOfOperationCallback(uint32_t ReturnValue)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(ReturnValue);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_FLASH_EndOfOperationCallback could be implemented in the user file
*/
}
/**
* @brief FLASH operation error interrupt callback.
* @param ReturnValue The value saved in this parameter depends on the ongoing procedure:
* @arg Mass Erase: Bank number which has been requested to erase
* @arg Page Erase: Page number which returned an error
* @arg Program: Address which was selected for data program
* @retval None
*/
__weak void HAL_FLASH_OperationErrorCallback(uint32_t ReturnValue)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(ReturnValue);
/* NOTE : This function should not be modified, when the callback is needed,
the HAL_FLASH_OperationErrorCallback could be implemented in the user file
*/
}
/**
* @}
*/
/** @defgroup FLASH_Exported_Functions_Group2 Peripheral Control functions
* @brief Management functions
*
@verbatim
===============================================================================
##### Peripheral Control functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to control the FLASH
memory operations.
@endverbatim
* @{
*/
/**
* @brief Unlock the FLASH control register access.
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASH_Unlock(void)
{
HAL_StatusTypeDef status = HAL_OK;
if (READ_BIT(FLASH->CR, FLASH_CR_LOCK) != 0U)
{
/* Authorize the FLASH Registers access */
WRITE_REG(FLASH->KEYR, FLASH_KEY1);
WRITE_REG(FLASH->KEYR, FLASH_KEY2);
/* verify Flash is unlocked */
if (READ_BIT(FLASH->CR, FLASH_CR_LOCK) != 0U)
{
status = HAL_ERROR;
}
}
return status;
}
/**
* @brief Lock the FLASH control register access.
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASH_Lock(void)
{
HAL_StatusTypeDef status = HAL_ERROR;
/* Set the LOCK Bit to lock the FLASH Registers access */
SET_BIT(FLASH->CR, FLASH_CR_LOCK);
/* verify Flash is locked */
if (READ_BIT(FLASH->CR, FLASH_CR_LOCK) != 0U)
{
status = HAL_OK;
}
return status;
}
/**
* @brief Unlock the FLASH Option Bytes Registers access.
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASH_OB_Unlock(void)
{
HAL_StatusTypeDef status = HAL_OK;
if (READ_BIT(FLASH->CR, FLASH_CR_OPTLOCK) != 0U)
{
/* Authorizes the Option Byte register programming */
WRITE_REG(FLASH->OPTKEYR, FLASH_OPTKEY1);
WRITE_REG(FLASH->OPTKEYR, FLASH_OPTKEY2);
/* verify option bytes are unlocked */
if (READ_BIT(FLASH->CR, FLASH_CR_OPTLOCK) != 0U)
{
status = HAL_ERROR;
}
}
return status;
}
/**
* @brief Lock the FLASH Option Bytes Registers access.
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASH_OB_Lock(void)
{
HAL_StatusTypeDef status = HAL_ERROR;
/* Set the OPTLOCK Bit to lock the FLASH Option Byte Registers access */
SET_BIT(FLASH->CR, FLASH_CR_OPTLOCK);
/* Verify option bytes are locked */
if (READ_BIT(FLASH->CR, FLASH_CR_OPTLOCK) != 0U)
{
status = HAL_OK;
}
return status;
}
/**
* @brief Launch the option byte loading.
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASH_OB_Launch(void)
{
/* Set the bit to force the option byte reloading */
SET_BIT(FLASH->CR, FLASH_CR_OBL_LAUNCH);
/* Wait for last operation to be completed */
return (FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE));
}
/**
* @}
*/
/** @defgroup FLASH_Exported_Functions_Group3 Peripheral State and Errors functions
* @brief Peripheral Errors functions
*
@verbatim
===============================================================================
##### Peripheral Errors functions #####
===============================================================================
[..]
This subsection permits to get in run-time Errors of the FLASH peripheral.
@endverbatim
* @{
*/
/**
* @brief Get the specific FLASH error flag.
* @retval FLASH_ErrorCode. The returned value can be:
* @arg HAL_FLASH_ERROR_RD: FLASH Read Protection error flag (PCROP)
* @arg HAL_FLASH_ERROR_PGS: FLASH Programming Sequence error flag
* @arg HAL_FLASH_ERROR_PGP: FLASH Programming Parallelism error flag
* @arg HAL_FLASH_ERROR_PGA: FLASH Programming Alignment error flag
* @arg HAL_FLASH_ERROR_WRP: FLASH Write protected error flag
* @arg HAL_FLASH_ERROR_OPERATION: FLASH operation Error flag
* @arg HAL_FLASH_ERROR_NONE: No error set
* @arg HAL_FLASH_ERROR_OP: FLASH Operation error
* @arg HAL_FLASH_ERROR_PROG: FLASH Programming error
* @arg HAL_FLASH_ERROR_WRP: FLASH Write protection error
* @arg HAL_FLASH_ERROR_PGA: FLASH Programming alignment error
* @arg HAL_FLASH_ERROR_SIZ: FLASH Size error
* @arg HAL_FLASH_ERROR_PGS: FLASH Programming sequence error
* @arg HAL_FLASH_ERROR_MIS: FLASH Fast programming data miss error
* @arg HAL_FLASH_ERROR_FAST: FLASH Fast programming error
* @arg HAL_FLASH_ERROR_RD: FLASH PCROP read error
* @arg HAL_FLASH_ERROR_OPTV: FLASH Option validity error
*/
uint32_t HAL_FLASH_GetError(void)
{
return pFlash.ErrorCode;
}
/**
* @}
*/
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/** @addtogroup FLASH_Private_Functions
* @{
*/
/**
* @brief Wait for a FLASH operation to complete.
* @param Timeout maximum flash operation timeout.
* @retval HAL_Status
*/
HAL_StatusTypeDef FLASH_WaitForLastOperation(uint32_t Timeout)
{
/* Wait for the FLASH operation to complete by polling on BUSY flag to be reset.
Even if the FLASH operation fails, the BUSY flag will be reset and an error
flag will be set */
uint32_t tickstart = HAL_GetTick();
uint32_t error;
while (__HAL_FLASH_GET_FLAG(FLASH_FLAG_BSY))
{
if ((HAL_GetTick() - tickstart) > Timeout)
{
return HAL_TIMEOUT;
}
}
/* Check FLASH operation error flags */
error = (FLASH->SR & FLASH_FLAG_SR_ERRORS);
if (error != 0u)
{
/* Save the error code */
pFlash.ErrorCode |= error;
/* Clear error programming flags */
__HAL_FLASH_CLEAR_FLAG(error);
return HAL_ERROR;
}
/* Check FLASH End of Operation flag */
if (__HAL_FLASH_GET_FLAG(FLASH_FLAG_EOP))
{
/* Clear FLASH End of Operation pending bit */
__HAL_FLASH_CLEAR_FLAG(FLASH_FLAG_EOP);
}
/* If there is an error flag set */
return HAL_OK;
}
/**
* @brief Program double-word (64-bit) at a specified address.
* @param Address specifies the address to be programmed.
* @param Data specifies the data to be programmed.
* @retval None
*/
static void FLASH_Program_DoubleWord(uint32_t Address, uint64_t Data)
{
/* Check the parameters */
assert_param(IS_FLASH_PROGRAM_ADDRESS(Address));
/* Set PG bit */
SET_BIT(FLASH->CR, FLASH_CR_PG);
/* Program first word */
*(uint32_t *)Address = (uint32_t)Data;
/* Barrier to ensure programming is performed in 2 steps, in right order
(independently of compiler optimization behavior) */
__ISB();
/* Program second word */
*(uint32_t *)(Address + 4U) = (uint32_t)(Data >> 32U);
}
/**
* @brief Fast program a row double-word (64-bit) at a specified address.
* @param Address specifies the address to be programmed.
* @param DataAddress specifies the address where the data are stored.
* @retval None
*/
static void FLASH_Program_Fast(uint32_t Address, uint32_t DataAddress)
{
uint8_t row_index = (2 * FLASH_NB_DOUBLE_WORDS_IN_ROW);
uint32_t *dest_addr = (uint32_t *)Address;
uint32_t *src_addr = (uint32_t *)DataAddress;
uint32_t primask_bit;
/* Check the parameters */
assert_param(IS_FLASH_MAIN_MEM_ADDRESS(Address));
/* Set FSTPG bit */
SET_BIT(FLASH->CR, FLASH_CR_FSTPG);
/* Enter critical section: Disable interrupts to avoid any interruption during the loop */
primask_bit = __get_PRIMASK();
__disable_irq();
/* Program the double words of the row */
do
{
*dest_addr = *src_addr;
dest_addr++;
src_addr++;
row_index--;
}
while (row_index != 0U);
/* Exit critical section: restore previous priority mask */
__set_PRIMASK(primask_bit);
}
/**
* @}
*/
#endif /* HAL_FLASH_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 24,008 | C | 29.2 | 105 | 0.598134 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Src/stm32g4xx_hal_flash_ex.c | /**
******************************************************************************
* @file stm32g4xx_hal_flash_ex.c
* @author MCD Application Team
* @brief Extended FLASH HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the FLASH extended peripheral:
* + Extended programming operations functions
*
@verbatim
==============================================================================
##### Flash Extended features #####
==============================================================================
[..] Comparing to other previous devices, the FLASH interface for STM32G4xx
devices contains the following additional features
(+) Capacity up to 512 Kbytes with dual bank architecture supporting read-while-write
capability (RWW)
(+) Dual bank 64-bits memory organization with possibility of single bank 128-bits
(+) Protected areas including WRP, PCROP and Securable memory
##### How to use this driver #####
==============================================================================
[..] This driver provides functions to configure and program the FLASH memory
of all STM32G4xx devices. It includes
(#) Flash Memory Erase functions:
(++) Lock and Unlock the FLASH interface using HAL_FLASH_Unlock() and
HAL_FLASH_Lock() functions
(++) Erase function: Erase pages, or mass erase banks
(++) There are two modes of erase :
(+++) Polling Mode using HAL_FLASHEx_Erase()
(+++) Interrupt Mode using HAL_FLASHEx_Erase_IT()
(#) Option Bytes Programming function: Use HAL_FLASHEx_OBProgram() to:
(++) Configure the write protection areas (WRP)
(++) Set the Read protection Level (RDP)
(++) Program the user Option Bytes
(++) Configure the Proprietary Code ReadOut protection areas (PCROP)
(++) Configure the Securable memory areas
(++) Configure the Boot Lock
(#) Get Option Bytes Configuration function: Use HAL_FLASHEx_OBGetConfig() to:
(++) Get the configuration of write protection areas (WRP)
(++) Get the level of read protection (RDP)
(++) Get the value of the user Option Bytes
(++) Get the configuration of Proprietary Code ReadOut Protection areas (PCROP)
(++) Get the configuration of Securable memory areas
(++) Get the status of Boot Lock
(#) Activation of Securable memory area: Use HAL_FLASHEx_EnableSecMemProtection()
(++) Deny the access to securable memory area
(#) Enable or disable debugger: Use HAL_FLASHEx_EnableDebugger() or
HAL_FLASHEx_DisableDebugger()
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup FLASHEx FLASHEx
* @brief FLASH Extended HAL module driver
* @{
*/
#ifdef HAL_FLASH_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @defgroup FLASHEx_Private_Functions FLASHEx Private Functions
* @{
*/
static void FLASH_MassErase(uint32_t Banks);
static HAL_StatusTypeDef FLASH_OB_WRPConfig(uint32_t WRPArea, uint32_t WRPStartOffset, uint32_t WRDPEndOffset);
static HAL_StatusTypeDef FLASH_OB_RDPConfig(uint32_t RDPLevel);
static HAL_StatusTypeDef FLASH_OB_UserConfig(uint32_t UserType, uint32_t UserConfig);
static HAL_StatusTypeDef FLASH_OB_PCROPConfig(uint32_t PCROPConfig, uint32_t PCROPStartAddr, uint32_t PCROPEndAddr);
static void FLASH_OB_GetWRP(uint32_t WRPArea, uint32_t *WRPStartOffset, uint32_t *WRDPEndOffset);
static uint32_t FLASH_OB_GetRDP(void);
static uint32_t FLASH_OB_GetUser(void);
static void FLASH_OB_GetPCROP(uint32_t *PCROPConfig, uint32_t *PCROPStartAddr, uint32_t *PCROPEndAddr);
static HAL_StatusTypeDef FLASH_OB_SecMemConfig(uint32_t SecMemBank, uint32_t SecMemSize);
static void FLASH_OB_GetSecMem(uint32_t SecMemBank, uint32_t *SecMemSize);
static HAL_StatusTypeDef FLASH_OB_BootLockConfig(uint32_t BootLockConfig);
static uint32_t FLASH_OB_GetBootLock(void);
/**
* @}
*/
/* Exported functions -------------------------------------------------------*/
/** @defgroup FLASHEx_Exported_Functions FLASHEx Exported Functions
* @{
*/
/** @defgroup FLASHEx_Exported_Functions_Group1 Extended IO operation functions
* @brief Extended IO operation functions
*
@verbatim
===============================================================================
##### Extended programming operation functions #####
===============================================================================
[..]
This subsection provides a set of functions allowing to manage the Extended FLASH
programming operations Operations.
@endverbatim
* @{
*/
/**
* @brief Perform a mass erase or erase the specified FLASH memory pages.
* @param[in] pEraseInit pointer to an FLASH_EraseInitTypeDef structure that
* contains the configuration information for the erasing.
* @param[out] PageError pointer to variable that contains the configuration
* information on faulty page in case of error (0xFFFFFFFF means that all
* the pages have been correctly erased).
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASHEx_Erase(FLASH_EraseInitTypeDef *pEraseInit, uint32_t *PageError)
{
HAL_StatusTypeDef status;
uint32_t page_index;
/* Check the parameters */
assert_param(IS_FLASH_TYPEERASE(pEraseInit->TypeErase));
/* Process Locked */
__HAL_LOCK(&pFlash);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
pFlash.ErrorCode = HAL_FLASH_ERROR_NONE;
/* Deactivate the cache if they are activated to avoid data misbehavior */
if (READ_BIT(FLASH->ACR, FLASH_ACR_ICEN) != 0U)
{
if (READ_BIT(FLASH->ACR, FLASH_ACR_DCEN) != 0U)
{
/* Disable data cache */
__HAL_FLASH_DATA_CACHE_DISABLE();
pFlash.CacheToReactivate = FLASH_CACHE_ICACHE_DCACHE_ENABLED;
}
else
{
pFlash.CacheToReactivate = FLASH_CACHE_ICACHE_ENABLED;
}
}
else if (READ_BIT(FLASH->ACR, FLASH_ACR_DCEN) != 0U)
{
/* Disable data cache */
__HAL_FLASH_DATA_CACHE_DISABLE();
pFlash.CacheToReactivate = FLASH_CACHE_DCACHE_ENABLED;
}
else
{
pFlash.CacheToReactivate = FLASH_CACHE_DISABLED;
}
if (pEraseInit->TypeErase == FLASH_TYPEERASE_MASSERASE)
{
/* Mass erase to be done */
FLASH_MassErase(pEraseInit->Banks);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
#if defined (FLASH_OPTR_DBANK)
/* If the erase operation is completed, disable the MER1 and MER2 Bits */
CLEAR_BIT(FLASH->CR, (FLASH_CR_MER1 | FLASH_CR_MER2));
#else
/* If the erase operation is completed, disable the MER1 Bit */
CLEAR_BIT(FLASH->CR, (FLASH_CR_MER1));
#endif
}
else
{
/*Initialization of PageError variable*/
*PageError = 0xFFFFFFFFU;
for (page_index = pEraseInit->Page; page_index < (pEraseInit->Page + pEraseInit->NbPages); page_index++)
{
FLASH_PageErase(page_index, pEraseInit->Banks);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
/* If the erase operation is completed, disable the PER Bit */
CLEAR_BIT(FLASH->CR, (FLASH_CR_PER | FLASH_CR_PNB));
if (status != HAL_OK)
{
/* In case of error, stop erase procedure and return the faulty page */
*PageError = page_index;
break;
}
}
}
/* Flush the caches to be sure of the data consistency */
FLASH_FlushCaches();
}
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
return status;
}
/**
* @brief Perform a mass erase or erase the specified FLASH memory pages with interrupt enabled.
* @param pEraseInit pointer to an FLASH_EraseInitTypeDef structure that
* contains the configuration information for the erasing.
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASHEx_Erase_IT(FLASH_EraseInitTypeDef *pEraseInit)
{
HAL_StatusTypeDef status = HAL_OK;
/* Process Locked */
__HAL_LOCK(&pFlash);
/* Check the parameters */
assert_param(IS_FLASH_TYPEERASE(pEraseInit->TypeErase));
pFlash.ErrorCode = HAL_FLASH_ERROR_NONE;
/* Deactivate the cache if they are activated to avoid data misbehavior */
if (READ_BIT(FLASH->ACR, FLASH_ACR_ICEN) != 0U)
{
if (READ_BIT(FLASH->ACR, FLASH_ACR_DCEN) != 0U)
{
/* Disable data cache */
__HAL_FLASH_DATA_CACHE_DISABLE();
pFlash.CacheToReactivate = FLASH_CACHE_ICACHE_DCACHE_ENABLED;
}
else
{
pFlash.CacheToReactivate = FLASH_CACHE_ICACHE_ENABLED;
}
}
else if (READ_BIT(FLASH->ACR, FLASH_ACR_DCEN) != 0U)
{
/* Disable data cache */
__HAL_FLASH_DATA_CACHE_DISABLE();
pFlash.CacheToReactivate = FLASH_CACHE_DCACHE_ENABLED;
}
else
{
pFlash.CacheToReactivate = FLASH_CACHE_DISABLED;
}
/* Enable End of Operation and Error interrupts */
__HAL_FLASH_ENABLE_IT(FLASH_IT_EOP | FLASH_IT_OPERR);
pFlash.Bank = pEraseInit->Banks;
if (pEraseInit->TypeErase == FLASH_TYPEERASE_MASSERASE)
{
/* Mass erase to be done */
pFlash.ProcedureOnGoing = FLASH_PROC_MASS_ERASE;
FLASH_MassErase(pEraseInit->Banks);
}
else
{
/* Erase by page to be done */
pFlash.ProcedureOnGoing = FLASH_PROC_PAGE_ERASE;
pFlash.NbPagesToErase = pEraseInit->NbPages;
pFlash.Page = pEraseInit->Page;
/*Erase 1st page and wait for IT */
FLASH_PageErase(pEraseInit->Page, pEraseInit->Banks);
}
return status;
}
/**
* @brief Program Option bytes.
* @param pOBInit pointer to an FLASH_OBInitStruct structure that
* contains the configuration information for the programming.
* @note To configure any option bytes, the option lock bit OPTLOCK must be
* cleared with the call of HAL_FLASH_OB_Unlock() function.
* @note New option bytes configuration will be taken into account in two cases:
* - after an option bytes launch through the call of HAL_FLASH_OB_Launch()
* - after a power reset (BOR reset or exit from Standby/Shutdown modes)
* @retval HAL_Status
*/
HAL_StatusTypeDef HAL_FLASHEx_OBProgram(FLASH_OBProgramInitTypeDef *pOBInit)
{
HAL_StatusTypeDef status = HAL_OK;
/* Check the parameters */
assert_param(IS_OPTIONBYTE(pOBInit->OptionType));
/* Process Locked */
__HAL_LOCK(&pFlash);
pFlash.ErrorCode = HAL_FLASH_ERROR_NONE;
/* Write protection configuration */
if ((pOBInit->OptionType & OPTIONBYTE_WRP) != 0U)
{
/* Configure of Write protection on the selected area */
if (FLASH_OB_WRPConfig(pOBInit->WRPArea, pOBInit->WRPStartOffset, pOBInit->WRPEndOffset) != HAL_OK)
{
status = HAL_ERROR;
}
}
/* Read protection configuration */
if ((pOBInit->OptionType & OPTIONBYTE_RDP) != 0U)
{
/* Configure the Read protection level */
if (FLASH_OB_RDPConfig(pOBInit->RDPLevel) != HAL_OK)
{
status = HAL_ERROR;
}
}
/* User Configuration */
if ((pOBInit->OptionType & OPTIONBYTE_USER) != 0U)
{
/* Configure the user option bytes */
if (FLASH_OB_UserConfig(pOBInit->USERType, pOBInit->USERConfig) != HAL_OK)
{
status = HAL_ERROR;
}
}
/* PCROP Configuration */
if ((pOBInit->OptionType & OPTIONBYTE_PCROP) != 0U)
{
if (pOBInit->PCROPStartAddr != pOBInit->PCROPEndAddr)
{
/* Configure the Proprietary code readout protection */
if (FLASH_OB_PCROPConfig(pOBInit->PCROPConfig, pOBInit->PCROPStartAddr, pOBInit->PCROPEndAddr) != HAL_OK)
{
status = HAL_ERROR;
}
}
}
/* Securable memory Configuration */
if ((pOBInit->OptionType & OPTIONBYTE_SEC) != 0U)
{
/* Configure the securable memory area */
if (FLASH_OB_SecMemConfig(pOBInit->SecBank, pOBInit->SecSize) != HAL_OK)
{
status = HAL_ERROR;
}
}
/* Boot Entry Point Configuration */
if ((pOBInit->OptionType & OPTIONBYTE_BOOT_LOCK) != 0U)
{
/* Configure the boot unique entry point option */
if (FLASH_OB_BootLockConfig(pOBInit->BootEntryPoint) != HAL_OK)
{
status = HAL_ERROR;
}
}
/* Process Unlocked */
__HAL_UNLOCK(&pFlash);
return status;
}
/**
* @brief Get the Option bytes configuration.
* @param pOBInit pointer to an FLASH_OBInitStruct structure that contains the
* configuration information.
* @note The fields pOBInit->WRPArea and pOBInit->PCROPConfig should indicate
* which area is requested for the WRP and PCROP, else no information will be returned.
* @retval None
*/
void HAL_FLASHEx_OBGetConfig(FLASH_OBProgramInitTypeDef *pOBInit)
{
pOBInit->OptionType = (OPTIONBYTE_RDP | OPTIONBYTE_USER);
#if defined (FLASH_OPTR_DBANK)
if ((pOBInit->WRPArea == OB_WRPAREA_BANK1_AREAA) || (pOBInit->WRPArea == OB_WRPAREA_BANK1_AREAB) ||
(pOBInit->WRPArea == OB_WRPAREA_BANK2_AREAA) || (pOBInit->WRPArea == OB_WRPAREA_BANK2_AREAB))
#else
if ((pOBInit->WRPArea == OB_WRPAREA_BANK1_AREAA) || (pOBInit->WRPArea == OB_WRPAREA_BANK1_AREAB))
#endif
{
pOBInit->OptionType |= OPTIONBYTE_WRP;
/* Get write protection on the selected area */
FLASH_OB_GetWRP(pOBInit->WRPArea, &(pOBInit->WRPStartOffset), &(pOBInit->WRPEndOffset));
}
/* Get Read protection level */
pOBInit->RDPLevel = FLASH_OB_GetRDP();
/* Get the user option bytes */
pOBInit->USERConfig = FLASH_OB_GetUser();
#if defined (FLASH_OPTR_DBANK)
if ((pOBInit->PCROPConfig == FLASH_BANK_1) || (pOBInit->PCROPConfig == FLASH_BANK_2))
#else
if (pOBInit->PCROPConfig == FLASH_BANK_1)
#endif
{
pOBInit->OptionType |= OPTIONBYTE_PCROP;
/* Get the Proprietary code readout protection */
FLASH_OB_GetPCROP(&(pOBInit->PCROPConfig), &(pOBInit->PCROPStartAddr), &(pOBInit->PCROPEndAddr));
}
pOBInit->OptionType |= OPTIONBYTE_BOOT_LOCK;
/* Get the boot entry point */
pOBInit->BootEntryPoint = FLASH_OB_GetBootLock();
/* Get the securable memory area configuration */
#if defined (FLASH_OPTR_DBANK)
if ((pOBInit->SecBank == FLASH_BANK_1) || (pOBInit->SecBank == FLASH_BANK_2))
#else
if (pOBInit->SecBank == FLASH_BANK_1)
#endif
{
pOBInit->OptionType |= OPTIONBYTE_SEC;
FLASH_OB_GetSecMem(pOBInit->SecBank, &(pOBInit->SecSize));
}
}
/**
* @brief Enable the FLASH Securable Memory protection.
* @param Bank: Bank to be protected
* This parameter can be one of the following values:
* @arg FLASH_BANK_1: Bank1 to be protected
* @arg FLASH_BANK_2: Bank2 to be protected (*)
* @arg FLASH_BANK_BOTH: Bank1 and Bank2 to be protected (*)
* @note (*) availability depends on devices
* @retval HAL Status
*/
HAL_StatusTypeDef HAL_FLASHEx_EnableSecMemProtection(uint32_t Bank)
{
#if defined (FLASH_OPTR_DBANK)
if (READ_BIT(FLASH->OPTR, FLASH_OPTR_DBANK) != 0U)
{
/* Check the parameters */
assert_param(IS_FLASH_BANK(Bank));
/* Enable the Securable Memory Protection Bit for the bank 1 if requested */
if ((Bank & FLASH_BANK_1) != 0U)
{
SET_BIT(FLASH->CR, FLASH_CR_SEC_PROT1);
}
/* Enable the Securable Memory Protection Bit for the bank 2 if requested */
if ((Bank & FLASH_BANK_2) != 0U)
{
SET_BIT(FLASH->CR, FLASH_CR_SEC_PROT2);
}
}
else
{
SET_BIT(FLASH->CR, FLASH_CR_SEC_PROT1);
}
#else
/* Prevent unused argument(s) compilation warning */
UNUSED(Bank);
SET_BIT(FLASH->CR, FLASH_CR_SEC_PROT1);
#endif /* FLASH_OPTR_DBANK */
return HAL_OK;
}
/**
* @brief Enable Debugger.
* @note After calling this API, flash interface allow debugger intrusion.
* @retval None
*/
void HAL_FLASHEx_EnableDebugger(void)
{
FLASH->ACR |= FLASH_ACR_DBG_SWEN;
}
/**
* @brief Disable Debugger.
* @note After calling this API, Debugger is disabled: it's no more possible to
* break, see CPU register, etc...
* @retval None
*/
void HAL_FLASHEx_DisableDebugger(void)
{
FLASH->ACR &= ~FLASH_ACR_DBG_SWEN;
}
/**
* @}
*/
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/** @addtogroup FLASHEx_Private_Functions
* @{
*/
/**
* @brief Mass erase of FLASH memory.
* @param Banks Banks to be erased.
* This parameter can be one of the following values:
* @arg FLASH_BANK_1: Bank1 to be erased
* @arg FLASH_BANK_2: Bank2 to be erased (*)
* @arg FLASH_BANK_BOTH: Bank1 and Bank2 to be erased (*)
* @note (*) availability depends on devices
* @retval None
*/
static void FLASH_MassErase(uint32_t Banks)
{
#if defined (FLASH_OPTR_DBANK)
if (READ_BIT(FLASH->OPTR, FLASH_OPTR_DBANK) != 0U)
#endif
{
/* Check the parameters */
assert_param(IS_FLASH_BANK(Banks));
/* Set the Mass Erase Bit for the bank 1 if requested */
if ((Banks & FLASH_BANK_1) != 0U)
{
SET_BIT(FLASH->CR, FLASH_CR_MER1);
}
#if defined (FLASH_OPTR_DBANK)
/* Set the Mass Erase Bit for the bank 2 if requested */
if ((Banks & FLASH_BANK_2) != 0U)
{
SET_BIT(FLASH->CR, FLASH_CR_MER2);
}
#endif
}
#if defined (FLASH_OPTR_DBANK)
else
{
SET_BIT(FLASH->CR, (FLASH_CR_MER1 | FLASH_CR_MER2));
}
#endif
/* Proceed to erase all sectors */
SET_BIT(FLASH->CR, FLASH_CR_STRT);
}
/**
* @brief Erase the specified FLASH memory page.
* @param Page FLASH page to erase.
* This parameter must be a value between 0 and (max number of pages in the bank - 1).
* @param Banks Bank where the page will be erased.
* This parameter can be one of the following values:
* @arg FLASH_BANK_1: Page in bank 1 to be erased
* @arg FLASH_BANK_2: Page in bank 2 to be erased (*)
* @note (*) availability depends on devices
* @retval None
*/
void FLASH_PageErase(uint32_t Page, uint32_t Banks)
{
/* Check the parameters */
assert_param(IS_FLASH_PAGE(Page));
#if defined (FLASH_OPTR_DBANK)
if (READ_BIT(FLASH->OPTR, FLASH_OPTR_DBANK) == 0U)
{
CLEAR_BIT(FLASH->CR, FLASH_CR_BKER);
}
else
{
assert_param(IS_FLASH_BANK_EXCLUSIVE(Banks));
if ((Banks & FLASH_BANK_1) != 0U)
{
CLEAR_BIT(FLASH->CR, FLASH_CR_BKER);
}
else
{
SET_BIT(FLASH->CR, FLASH_CR_BKER);
}
}
#else
/* Prevent unused argument(s) compilation warning */
UNUSED(Banks);
#endif /* FLASH_OPTR_DBANK */
/* Proceed to erase the page */
MODIFY_REG(FLASH->CR, FLASH_CR_PNB, ((Page & 0xFFU) << FLASH_CR_PNB_Pos));
SET_BIT(FLASH->CR, FLASH_CR_PER);
SET_BIT(FLASH->CR, FLASH_CR_STRT);
}
/**
* @brief Flush the instruction and data caches.
* @retval None
*/
void FLASH_FlushCaches(void)
{
FLASH_CacheTypeDef cache = pFlash.CacheToReactivate;
/* Flush instruction cache */
if ((cache == FLASH_CACHE_ICACHE_ENABLED) ||
(cache == FLASH_CACHE_ICACHE_DCACHE_ENABLED))
{
/* Disable instruction cache */
__HAL_FLASH_INSTRUCTION_CACHE_DISABLE();
/* Reset instruction cache */
__HAL_FLASH_INSTRUCTION_CACHE_RESET();
/* Enable instruction cache */
__HAL_FLASH_INSTRUCTION_CACHE_ENABLE();
}
/* Flush data cache */
if ((cache == FLASH_CACHE_DCACHE_ENABLED) ||
(cache == FLASH_CACHE_ICACHE_DCACHE_ENABLED))
{
/* Reset data cache */
__HAL_FLASH_DATA_CACHE_RESET();
/* Enable data cache */
__HAL_FLASH_DATA_CACHE_ENABLE();
}
/* Reset internal variable */
pFlash.CacheToReactivate = FLASH_CACHE_DISABLED;
}
/**
* @brief Configure the write protection area into Option Bytes.
* @note When the memory read protection level is selected (RDP level = 1),
* it is not possible to program or erase Flash memory if the CPU debug
* features are connected (JTAG or single wire) or boot code is being
* executed from RAM or System flash, even if WRP is not activated.
* @note To configure any option bytes, the option lock bit OPTLOCK must be
* cleared with the call of HAL_FLASH_OB_Unlock() function.
* @note New option bytes configuration will be taken into account in two cases:
* - after an option bytes launch through the call of HAL_FLASH_OB_Launch()
* - after a power reset (BOR reset or exit from Standby/Shutdown modes)
* @param WRPArea specifies the area to be configured.
* This parameter can be one of the following values:
* @arg OB_WRPAREA_BANK1_AREAA: Flash Bank 1 Area A
* @arg OB_WRPAREA_BANK1_AREAB: Flash Bank 1 Area B
* @arg OB_WRPAREA_BANK2_AREAA: Flash Bank 2 Area A (*)
* @arg OB_WRPAREA_BANK2_AREAB: Flash Bank 2 Area B (*)
* @note (*) availability depends on devices
* @param WRPStartOffset specifies the start page of the write protected area.
* This parameter can be page number between 0 and (max number of pages in the bank - 1).
* @param WRDPEndOffset specifies the end page of the write protected area.
* This parameter can be page number between WRPStartOffset and (max number of pages in the bank - 1).
* @retval HAL_Status
*/
static HAL_StatusTypeDef FLASH_OB_WRPConfig(uint32_t WRPArea, uint32_t WRPStartOffset, uint32_t WRDPEndOffset)
{
HAL_StatusTypeDef status;
/* Check the parameters */
assert_param(IS_OB_WRPAREA(WRPArea));
assert_param(IS_FLASH_PAGE(WRPStartOffset));
assert_param(IS_FLASH_PAGE(WRDPEndOffset));
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
/* Configure the write protected area */
if (WRPArea == OB_WRPAREA_BANK1_AREAA)
{
FLASH->WRP1AR = ((WRDPEndOffset << FLASH_WRP1AR_WRP1A_END_Pos) | WRPStartOffset);
}
else if (WRPArea == OB_WRPAREA_BANK1_AREAB)
{
FLASH->WRP1BR = ((WRDPEndOffset << FLASH_WRP1BR_WRP1B_END_Pos) | WRPStartOffset);
}
#if defined (FLASH_OPTR_DBANK)
else if (WRPArea == OB_WRPAREA_BANK2_AREAA)
{
FLASH->WRP2AR = ((WRDPEndOffset << FLASH_WRP2AR_WRP2A_END_Pos) | WRPStartOffset);
}
else if (WRPArea == OB_WRPAREA_BANK2_AREAB)
{
FLASH->WRP2BR = ((WRDPEndOffset << FLASH_WRP2BR_WRP2B_END_Pos) | WRPStartOffset);
}
#endif
else
{
/* Nothing to do */
}
/* Set OPTSTRT Bit */
SET_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
}
return status;
}
/**
* @brief Set the read protection level into Option Bytes.
* @note To configure any option bytes, the option lock bit OPTLOCK must be
* cleared with the call of HAL_FLASH_OB_Unlock() function.
* @note New option bytes configuration will be taken into account in two cases:
* - after an option bytes launch through the call of HAL_FLASH_OB_Launch()
* - after a power reset (BOR reset or exit from Standby/Shutdown modes)
* @note !!! Warning : When enabling OB_RDP level 2 it's no more possible
* to go back to level 1 or 0 !!!
* @param RDPLevel specifies the read protection level.
* This parameter can be one of the following values:
* @arg OB_RDP_LEVEL_0: No protection
* @arg OB_RDP_LEVEL_1: Memory Read protection
* @arg OB_RDP_LEVEL_2: Full chip protection
*
* @retval HAL_Status
*/
static HAL_StatusTypeDef FLASH_OB_RDPConfig(uint32_t RDPLevel)
{
HAL_StatusTypeDef status;
/* Check the parameters */
assert_param(IS_OB_RDP_LEVEL(RDPLevel));
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
/* Configure the RDP level in the option bytes register */
MODIFY_REG(FLASH->OPTR, FLASH_OPTR_RDP, RDPLevel);
/* Set OPTSTRT Bit */
SET_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
}
return status;
}
/**
* @brief Program the FLASH User Option Bytes.
* @note To configure any option bytes, the option lock bit OPTLOCK must be
* cleared with the call of HAL_FLASH_OB_Unlock() function.
* @note New option bytes configuration will be taken into account in two cases:
* - after an option bytes launch through the call of HAL_FLASH_OB_Launch()
* - after a power reset (BOR reset or exit from Standby/Shutdown modes)
* @param UserType The FLASH User Option Bytes to be modified.
* This parameter can be a combination of @ref FLASH_OB_USER_Type.
* @param UserConfig The selected User Option Bytes values:
* This parameter can be a combination of @ref FLASH_OB_USER_BOR_LEVEL,
* @ref FLASH_OB_USER_nRST_STOP, @ref FLASH_OB_USER_nRST_STANDBY ,
* @ref FLASH_OB_USER_nRST_SHUTDOWN, @ref FLASH_OB_USER_IWDG_SW,
* @ref FLASH_OB_USER_IWDG_STOP, @ref FLASH_OB_USER_IWDG_STANDBY,
* @ref FLASH_OB_USER_WWDG_SW, @ref FLASH_OB_USER_WWDG_SW,
* @ref FLASH_OB_USER_BFB2 (*), @ref FLASH_OB_USER_nBOOT1,
* @ref FLASH_OB_USER_SRAM_PE, @ref FLASH_OB_USER_CCMSRAM_RST,
* @ref FLASH_OB_USER_nSWBOOT0, @ref FLASH_OB_USER_nBOOT0,
* @ref FLASH_OB_USER_NRST_MODE, @ref FLASH_OB_USER_INTERNAL_RESET_HOLDER
* @note (*) availability depends on devices
* @retval HAL_Status
*/
static HAL_StatusTypeDef FLASH_OB_UserConfig(uint32_t UserType, uint32_t UserConfig)
{
uint32_t optr_reg_val = 0;
uint32_t optr_reg_mask = 0;
HAL_StatusTypeDef status;
/* Check the parameters */
assert_param(IS_OB_USER_TYPE(UserType));
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
#if defined(FLASH_OPTR_PB4_PUPEN)
if ((UserType & OB_USER_PB4_PUPEN) != 0U)
{
/* PB4_PUPEN option byte should be modified */
assert_param(IS_OB_USER_PB4_PUPEN(UserConfig & FLASH_OPTR_PB4_PUPEN));
/* Set value and mask for PB4_PUPEN option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_PB4_PUPEN);
optr_reg_mask |= FLASH_OPTR_PB4_PUPEN;
}
#endif /* FLASH_OPTR_PB4_PUPEN */
if ((UserType & OB_USER_BOR_LEV) != 0U)
{
/* BOR level option byte should be modified */
assert_param(IS_OB_USER_BOR_LEVEL(UserConfig & FLASH_OPTR_BOR_LEV));
/* Set value and mask for BOR level option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_BOR_LEV);
optr_reg_mask |= FLASH_OPTR_BOR_LEV;
}
if ((UserType & OB_USER_nRST_STOP) != 0U)
{
/* nRST_STOP option byte should be modified */
assert_param(IS_OB_USER_STOP(UserConfig & FLASH_OPTR_nRST_STOP));
/* Set value and mask for nRST_STOP option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_nRST_STOP);
optr_reg_mask |= FLASH_OPTR_nRST_STOP;
}
if ((UserType & OB_USER_nRST_STDBY) != 0U)
{
/* nRST_STDBY option byte should be modified */
assert_param(IS_OB_USER_STANDBY(UserConfig & FLASH_OPTR_nRST_STDBY));
/* Set value and mask for nRST_STDBY option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_nRST_STDBY);
optr_reg_mask |= FLASH_OPTR_nRST_STDBY;
}
if ((UserType & OB_USER_nRST_SHDW) != 0U)
{
/* nRST_SHDW option byte should be modified */
assert_param(IS_OB_USER_SHUTDOWN(UserConfig & FLASH_OPTR_nRST_SHDW));
/* Set value and mask for nRST_SHDW option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_nRST_SHDW);
optr_reg_mask |= FLASH_OPTR_nRST_SHDW;
}
if ((UserType & OB_USER_IWDG_SW) != 0U)
{
/* IWDG_SW option byte should be modified */
assert_param(IS_OB_USER_IWDG(UserConfig & FLASH_OPTR_IWDG_SW));
/* Set value and mask for IWDG_SW option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_IWDG_SW);
optr_reg_mask |= FLASH_OPTR_IWDG_SW;
}
if ((UserType & OB_USER_IWDG_STOP) != 0U)
{
/* IWDG_STOP option byte should be modified */
assert_param(IS_OB_USER_IWDG_STOP(UserConfig & FLASH_OPTR_IWDG_STOP));
/* Set value and mask for IWDG_STOP option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_IWDG_STOP);
optr_reg_mask |= FLASH_OPTR_IWDG_STOP;
}
if ((UserType & OB_USER_IWDG_STDBY) != 0U)
{
/* IWDG_STDBY option byte should be modified */
assert_param(IS_OB_USER_IWDG_STDBY(UserConfig & FLASH_OPTR_IWDG_STDBY));
/* Set value and mask for IWDG_STDBY option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_IWDG_STDBY);
optr_reg_mask |= FLASH_OPTR_IWDG_STDBY;
}
if ((UserType & OB_USER_WWDG_SW) != 0U)
{
/* WWDG_SW option byte should be modified */
assert_param(IS_OB_USER_WWDG(UserConfig & FLASH_OPTR_WWDG_SW));
/* Set value and mask for WWDG_SW option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_WWDG_SW);
optr_reg_mask |= FLASH_OPTR_WWDG_SW;
}
#if defined (FLASH_OPTR_BFB2)
if ((UserType & OB_USER_BFB2) != 0U)
{
/* BFB2 option byte should be modified */
assert_param(IS_OB_USER_BFB2(UserConfig & FLASH_OPTR_BFB2));
/* Set value and mask for BFB2 option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_BFB2);
optr_reg_mask |= FLASH_OPTR_BFB2;
}
#endif
if ((UserType & OB_USER_nBOOT1) != 0U)
{
/* nBOOT1 option byte should be modified */
assert_param(IS_OB_USER_BOOT1(UserConfig & FLASH_OPTR_nBOOT1));
/* Set value and mask for nBOOT1 option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_nBOOT1);
optr_reg_mask |= FLASH_OPTR_nBOOT1;
}
if ((UserType & OB_USER_SRAM_PE) != 0U)
{
/* SRAM_PE option byte should be modified */
assert_param(IS_OB_USER_SRAM_PARITY(UserConfig & FLASH_OPTR_SRAM_PE));
/* Set value and mask for SRAM_PE option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_SRAM_PE);
optr_reg_mask |= FLASH_OPTR_SRAM_PE;
}
if ((UserType & OB_USER_CCMSRAM_RST) != 0U)
{
/* CCMSRAM_RST option byte should be modified */
assert_param(IS_OB_USER_CCMSRAM_RST(UserConfig & FLASH_OPTR_CCMSRAM_RST));
/* Set value and mask for CCMSRAM_RST option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_CCMSRAM_RST);
optr_reg_mask |= FLASH_OPTR_CCMSRAM_RST;
}
if ((UserType & OB_USER_nSWBOOT0) != 0U)
{
/* nSWBOOT0 option byte should be modified */
assert_param(IS_OB_USER_SWBOOT0(UserConfig & FLASH_OPTR_nSWBOOT0));
/* Set value and mask for nSWBOOT0 option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_nSWBOOT0);
optr_reg_mask |= FLASH_OPTR_nSWBOOT0;
}
if ((UserType & OB_USER_nBOOT0) != 0U)
{
/* nBOOT0 option byte should be modified */
assert_param(IS_OB_USER_BOOT0(UserConfig & FLASH_OPTR_nBOOT0));
/* Set value and mask for nBOOT0 option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_nBOOT0);
optr_reg_mask |= FLASH_OPTR_nBOOT0;
}
if ((UserType & OB_USER_NRST_MODE) != 0U)
{
/* Reset Configuration option byte should be modified */
assert_param(IS_OB_USER_NRST_MODE(UserConfig & FLASH_OPTR_NRST_MODE));
/* Set value and mask for Reset Configuration option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_NRST_MODE);
optr_reg_mask |= FLASH_OPTR_NRST_MODE;
}
if ((UserType & OB_USER_IRHEN) != 0U)
{
/* IRH option byte should be modified */
assert_param(IS_OB_USER_IRHEN(UserConfig & FLASH_OPTR_IRHEN));
/* Set value and mask for IRH option byte */
optr_reg_val |= (UserConfig & FLASH_OPTR_IRHEN);
optr_reg_mask |= FLASH_OPTR_IRHEN;
}
/* Configure the option bytes register */
MODIFY_REG(FLASH->OPTR, optr_reg_mask, optr_reg_val);
/* Set OPTSTRT Bit */
SET_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
}
return status;
}
/**
* @brief Configure the Proprietary code readout protection area into Option Bytes.
* @note To configure any option bytes, the option lock bit OPTLOCK must be
* cleared with the call of HAL_FLASH_OB_Unlock() function.
* @note New option bytes configuration will be taken into account in two cases:
* - after an option bytes launch through the call of HAL_FLASH_OB_Launch()
* - after a power reset (BOR reset or exit from Standby/Shutdown modes)
* @param PCROPConfig specifies the configuration (Bank to be configured and PCROP_RDP option).
* This parameter must be a combination of FLASH_BANK_1 or FLASH_BANK_2 (*)
* with OB_PCROP_RDP_NOT_ERASE or OB_PCROP_RDP_ERASE.
* @note (*) availability depends on devices
* @param PCROPStartAddr specifies the start address of the Proprietary code readout protection.
* This parameter can be an address between begin and end of the bank.
* @param PCROPEndAddr specifies the end address of the Proprietary code readout protection.
* This parameter can be an address between PCROPStartAddr and end of the bank.
* @retval HAL_Status
*/
static HAL_StatusTypeDef FLASH_OB_PCROPConfig(uint32_t PCROPConfig, uint32_t PCROPStartAddr, uint32_t PCROPEndAddr)
{
HAL_StatusTypeDef status;
uint32_t reg_value;
uint32_t bank1_addr;
#if defined (FLASH_OPTR_DBANK)
uint32_t bank2_addr;
#endif
/* Check the parameters */
assert_param(IS_FLASH_BANK_EXCLUSIVE(PCROPConfig & FLASH_BANK_BOTH));
assert_param(IS_OB_PCROP_RDP(PCROPConfig & FLASH_PCROP1ER_PCROP_RDP));
assert_param(IS_FLASH_MAIN_MEM_ADDRESS(PCROPStartAddr));
assert_param(IS_FLASH_MAIN_MEM_ADDRESS(PCROPEndAddr));
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
#if defined (FLASH_OPTR_DBANK)
/* Get the information about the bank swapping */
if (READ_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_FB_MODE) == 0U)
{
bank1_addr = FLASH_BASE;
bank2_addr = FLASH_BASE + FLASH_BANK_SIZE;
}
else
{
bank1_addr = FLASH_BASE + FLASH_BANK_SIZE;
bank2_addr = FLASH_BASE;
}
#else
bank1_addr = FLASH_BASE;
#endif
#if defined (FLASH_OPTR_DBANK)
if (READ_BIT(FLASH->OPTR, FLASH_OPTR_DBANK) == 0U)
{
/* Configure the Proprietary code readout protection */
if ((PCROPConfig & FLASH_BANK_BOTH) == FLASH_BANK_1)
{
reg_value = ((PCROPStartAddr - FLASH_BASE) >> 4);
MODIFY_REG(FLASH->PCROP1SR, FLASH_PCROP1SR_PCROP1_STRT, reg_value);
reg_value = ((PCROPEndAddr - FLASH_BASE) >> 4);
MODIFY_REG(FLASH->PCROP1ER, FLASH_PCROP1ER_PCROP1_END, reg_value);
}
else if ((PCROPConfig & FLASH_BANK_BOTH) == FLASH_BANK_2)
{
reg_value = ((PCROPStartAddr - FLASH_BASE) >> 4);
MODIFY_REG(FLASH->PCROP2SR, FLASH_PCROP2SR_PCROP2_STRT, reg_value);
reg_value = ((PCROPEndAddr - FLASH_BASE) >> 4);
MODIFY_REG(FLASH->PCROP2ER, FLASH_PCROP2ER_PCROP2_END, reg_value);
}
else
{
/* Nothing to do */
}
}
else
#endif
{
/* Configure the Proprietary code readout protection */
if ((PCROPConfig & FLASH_BANK_BOTH) == FLASH_BANK_1)
{
reg_value = ((PCROPStartAddr - bank1_addr) >> 3);
MODIFY_REG(FLASH->PCROP1SR, FLASH_PCROP1SR_PCROP1_STRT, reg_value);
reg_value = ((PCROPEndAddr - bank1_addr) >> 3);
MODIFY_REG(FLASH->PCROP1ER, FLASH_PCROP1ER_PCROP1_END, reg_value);
}
#if defined (FLASH_OPTR_DBANK)
else if ((PCROPConfig & FLASH_BANK_BOTH) == FLASH_BANK_2)
{
reg_value = ((PCROPStartAddr - bank2_addr) >> 3);
MODIFY_REG(FLASH->PCROP2SR, FLASH_PCROP2SR_PCROP2_STRT, reg_value);
reg_value = ((PCROPEndAddr - bank2_addr) >> 3);
MODIFY_REG(FLASH->PCROP2ER, FLASH_PCROP2ER_PCROP2_END, reg_value);
}
#endif
else
{
/* Nothing to do */
}
}
MODIFY_REG(FLASH->PCROP1ER, FLASH_PCROP1ER_PCROP_RDP, (PCROPConfig & FLASH_PCROP1ER_PCROP_RDP));
/* Set OPTSTRT Bit */
SET_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
}
return status;
}
/**
* @brief Configure the Securable memory area into Option Bytes.
* @note To configure any option bytes, the option lock bit OPTLOCK must be
* cleared with the call of HAL_FLASH_OB_Unlock() function.
* @note New option bytes configuration will be taken into account in two cases:
* - after an option bytes launch through the call of HAL_FLASH_OB_Launch()
* - after a power reset (BOR reset or exit from Standby/Shutdown modes)
* @param SecBank specifies bank of securable memory area to be configured.
* This parameter can be one of the following values:
* @arg FLASH_BANK_1: Securable memory in Bank1 to be configured
* @arg FLASH_BANK_2: Securable memory in Bank2 to be configured (*)
* @note (*) availability depends on devices
* @param SecSize specifies the number of pages of the Securable memory area,
* starting from first page of the bank.
* This parameter can be page number between 0 and (max number of pages in the bank - 1)
* @retval HAL Status
*/
static HAL_StatusTypeDef FLASH_OB_SecMemConfig(uint32_t SecBank, uint32_t SecSize)
{
HAL_StatusTypeDef status;
/* Check the parameters */
assert_param(IS_FLASH_BANK_EXCLUSIVE(SecBank));
assert_param(IS_OB_SECMEM_SIZE(SecSize));
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
/* Configure the write protected area */
if (SecBank == FLASH_BANK_1)
{
MODIFY_REG(FLASH->SEC1R, FLASH_SEC1R_SEC_SIZE1, SecSize);
}
#if defined (FLASH_OPTR_DBANK)
else if (SecBank == FLASH_BANK_2)
{
MODIFY_REG(FLASH->SEC2R, FLASH_SEC2R_SEC_SIZE2, SecSize);
}
else
{
/* Nothing to do */
}
#endif
/* Set OPTSTRT Bit */
SET_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
}
return status;
}
/**
* @brief Configure the Boot Lock into Option Bytes.
* @note To configure any option bytes, the option lock bit OPTLOCK must be
* cleared with the call of HAL_FLASH_OB_Unlock() function.
* @note New option bytes configuration will be taken into account in two cases:
* - after an option bytes launch through the call of HAL_FLASH_OB_Launch()
* - after a power reset (BOR reset or exit from Standby/Shutdown modes)
* @param BootLockConfig specifies the boot lock configuration.
* This parameter can be one of the following values:
* @arg OB_BOOT_LOCK_ENABLE: Enable Boot Lock
* @arg OB_BOOT_LOCK_DISABLE: Disable Boot Lock
*
* @retval HAL_Status
*/
static HAL_StatusTypeDef FLASH_OB_BootLockConfig(uint32_t BootLockConfig)
{
HAL_StatusTypeDef status;
/* Check the parameters */
assert_param(IS_OB_BOOT_LOCK(BootLockConfig));
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
if (status == HAL_OK)
{
MODIFY_REG(FLASH->SEC1R, FLASH_SEC1R_BOOT_LOCK, BootLockConfig);
/* Set OPTSTRT Bit */
SET_BIT(FLASH->CR, FLASH_CR_OPTSTRT);
/* Wait for last operation to be completed */
status = FLASH_WaitForLastOperation((uint32_t)FLASH_TIMEOUT_VALUE);
}
return status;
}
/**
* @brief Return the Securable memory area configuration into Option Bytes.
* @param[in] SecBank specifies the bank where securable memory area is located.
* This parameter can be one of the following values:
* @arg FLASH_BANK_1: Securable memory in Bank1
* @arg FLASH_BANK_2: Securable memory in Bank2 (*)
* @note (*) availability depends on devices
* @param[out] SecSize specifies the number of pages used in the securable
memory area of the bank.
* @retval None
*/
static void FLASH_OB_GetSecMem(uint32_t SecBank, uint32_t *SecSize)
{
/* Get the configuration of the securable memory area */
if (SecBank == FLASH_BANK_1)
{
*SecSize = READ_BIT(FLASH->SEC1R, FLASH_SEC1R_SEC_SIZE1);
}
#if defined (FLASH_OPTR_DBANK)
else if (SecBank == FLASH_BANK_2)
{
*SecSize = READ_BIT(FLASH->SEC2R, FLASH_SEC2R_SEC_SIZE2);
}
else
{
/* Nothing to do */
}
#endif
}
/**
* @brief Return the Boot Lock configuration into Option Byte.
* @retval BootLockConfig.
* This return value can be one of the following values:
* @arg OB_BOOT_LOCK_ENABLE: Boot lock enabled
* @arg OB_BOOT_LOCK_DISABLE: Boot lock disabled
*/
static uint32_t FLASH_OB_GetBootLock(void)
{
return (READ_REG(FLASH->SEC1R) & FLASH_SEC1R_BOOT_LOCK);
}
/**
* @brief Return the Write Protection configuration into Option Bytes.
* @param[in] WRPArea specifies the area to be returned.
* This parameter can be one of the following values:
* @arg OB_WRPAREA_BANK1_AREAA: Flash Bank 1 Area A
* @arg OB_WRPAREA_BANK1_AREAB: Flash Bank 1 Area B
* @arg OB_WRPAREA_BANK2_AREAA: Flash Bank 2 Area A (don't apply to STM32G43x/STM32G44x devices)
* @arg OB_WRPAREA_BANK2_AREAB: Flash Bank 2 Area B (don't apply to STM32G43x/STM32G44x devices)
* @param[out] WRPStartOffset specifies the address where to copied the start page
* of the write protected area.
* @param[out] WRDPEndOffset specifies the address where to copied the end page of
* the write protected area.
* @retval None
*/
static void FLASH_OB_GetWRP(uint32_t WRPArea, uint32_t *WRPStartOffset, uint32_t *WRDPEndOffset)
{
/* Get the configuration of the write protected area */
if (WRPArea == OB_WRPAREA_BANK1_AREAA)
{
*WRPStartOffset = READ_BIT(FLASH->WRP1AR, FLASH_WRP1AR_WRP1A_STRT);
*WRDPEndOffset = (READ_BIT(FLASH->WRP1AR, FLASH_WRP1AR_WRP1A_END) >> FLASH_WRP1AR_WRP1A_END_Pos);
}
else if (WRPArea == OB_WRPAREA_BANK1_AREAB)
{
*WRPStartOffset = READ_BIT(FLASH->WRP1BR, FLASH_WRP1BR_WRP1B_STRT);
*WRDPEndOffset = (READ_BIT(FLASH->WRP1BR, FLASH_WRP1BR_WRP1B_END) >> FLASH_WRP1BR_WRP1B_END_Pos);
}
#if defined (FLASH_OPTR_DBANK)
else if (WRPArea == OB_WRPAREA_BANK2_AREAA)
{
*WRPStartOffset = READ_BIT(FLASH->WRP2AR, FLASH_WRP2AR_WRP2A_STRT);
*WRDPEndOffset = (READ_BIT(FLASH->WRP2AR, FLASH_WRP2AR_WRP2A_END) >> FLASH_WRP2AR_WRP2A_END_Pos);
}
else if (WRPArea == OB_WRPAREA_BANK2_AREAB)
{
*WRPStartOffset = READ_BIT(FLASH->WRP2BR, FLASH_WRP2BR_WRP2B_STRT);
*WRDPEndOffset = (READ_BIT(FLASH->WRP2BR, FLASH_WRP2BR_WRP2B_END) >> FLASH_WRP2BR_WRP2B_END_Pos);
}
#endif
else
{
/* Nothing to do */
}
}
/**
* @brief Return the FLASH Read Protection level into Option Bytes.
* @retval RDP_Level
* This return value can be one of the following values:
* @arg OB_RDP_LEVEL_0: No protection
* @arg OB_RDP_LEVEL_1: Read protection of the memory
* @arg OB_RDP_LEVEL_2: Full chip protection
*/
static uint32_t FLASH_OB_GetRDP(void)
{
uint32_t rdp_level = READ_BIT(FLASH->OPTR, FLASH_OPTR_RDP);
if ((rdp_level != OB_RDP_LEVEL_0) && (rdp_level != OB_RDP_LEVEL_2))
{
return (OB_RDP_LEVEL_1);
}
else
{
return rdp_level;
}
}
/**
* @brief Return the FLASH User Option Byte value.
* @retval OB_user_config
* This return value is a combination of @ref FLASH_OB_USER_BOR_LEVEL,
* @ref FLASH_OB_USER_nRST_STOP, @ref FLASH_OB_USER_nRST_STANDBY,
* @ref FLASH_OB_USER_nRST_SHUTDOWN, @ref FLASH_OB_USER_IWDG_SW,
* @ref FLASH_OB_USER_IWDG_STOP, @ref FLASH_OB_USER_IWDG_STANDBY,
* @ref FLASH_OB_USER_WWDG_SW, @ref FLASH_OB_USER_WWDG_SW,
* @ref FLASH_OB_USER_BFB2 (*), @ref FLASH_OB_USER_DBANK (*),
* @ref FLASH_OB_USER_nBOOT1, @ref FLASH_OB_USER_SRAM_PE,
* @ref FLASH_OB_USER_CCMSRAM_RST, @ref OB_USER_nSWBOOT0,@ref FLASH_OB_USER_nBOOT0,
* @ref FLASH_OB_USER_NRST_MODE, @ref FLASH_OB_USER_INTERNAL_RESET_HOLDER
* @note (*) availability depends on devices
*/
static uint32_t FLASH_OB_GetUser(void)
{
uint32_t user_config = READ_REG(FLASH->OPTR);
CLEAR_BIT(user_config, FLASH_OPTR_RDP);
return user_config;
}
/**
* @brief Return the FLASH PCROP configuration into Option Bytes.
* @param[in,out] PCROPConfig specifies the configuration (Bank to be configured and PCROP_RDP option).
* This parameter must be a combination of FLASH_BANK_1 or FLASH_BANK_2
* with OB_PCROP_RDP_NOT_ERASE or OB_PCROP_RDP_ERASE.
* @param[out] PCROPStartAddr specifies the address where to copied the start address
* of the Proprietary code readout protection.
* @param[out] PCROPEndAddr specifies the address where to copied the end address of
* the Proprietary code readout protection.
* @retval None
*/
static void FLASH_OB_GetPCROP(uint32_t *PCROPConfig, uint32_t *PCROPStartAddr, uint32_t *PCROPEndAddr)
{
uint32_t reg_value;
uint32_t bank1_addr;
#if defined (FLASH_OPTR_DBANK)
uint32_t bank2_addr;
/* Get the information about the bank swapping */
if (READ_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_FB_MODE) == 0U)
{
bank1_addr = FLASH_BASE;
bank2_addr = FLASH_BASE + FLASH_BANK_SIZE;
}
else
{
bank1_addr = FLASH_BASE + FLASH_BANK_SIZE;
bank2_addr = FLASH_BASE;
}
#else
bank1_addr = FLASH_BASE;
#endif
#if defined (FLASH_OPTR_DBANK)
if (READ_BIT(FLASH->OPTR, FLASH_OPTR_DBANK) == 0U)
{
if (((*PCROPConfig) & FLASH_BANK_BOTH) == FLASH_BANK_1)
{
reg_value = (READ_REG(FLASH->PCROP1SR) & FLASH_PCROP1SR_PCROP1_STRT);
*PCROPStartAddr = (reg_value << 4) + FLASH_BASE;
reg_value = (READ_REG(FLASH->PCROP1ER) & FLASH_PCROP1ER_PCROP1_END);
*PCROPEndAddr = (reg_value << 4) + FLASH_BASE;
}
else if (((*PCROPConfig) & FLASH_BANK_BOTH) == FLASH_BANK_2)
{
reg_value = (READ_REG(FLASH->PCROP2SR) & FLASH_PCROP2SR_PCROP2_STRT);
*PCROPStartAddr = (reg_value << 4) + FLASH_BASE;
reg_value = (READ_REG(FLASH->PCROP2ER) & FLASH_PCROP2ER_PCROP2_END);
*PCROPEndAddr = (reg_value << 4) + FLASH_BASE;
}
else
{
/* Nothing to do */
}
}
else
#endif
{
if (((*PCROPConfig) & FLASH_BANK_BOTH) == FLASH_BANK_1)
{
reg_value = (READ_REG(FLASH->PCROP1SR) & FLASH_PCROP1SR_PCROP1_STRT);
*PCROPStartAddr = (reg_value << 3) + bank1_addr;
reg_value = (READ_REG(FLASH->PCROP1ER) & FLASH_PCROP1ER_PCROP1_END);
*PCROPEndAddr = (reg_value << 3) + bank1_addr;
}
#if defined (FLASH_OPTR_DBANK)
else if (((*PCROPConfig) & FLASH_BANK_BOTH) == FLASH_BANK_2)
{
reg_value = (READ_REG(FLASH->PCROP2SR) & FLASH_PCROP2SR_PCROP2_STRT);
*PCROPStartAddr = (reg_value << 3) + bank2_addr;
reg_value = (READ_REG(FLASH->PCROP2ER) & FLASH_PCROP2ER_PCROP2_END);
*PCROPEndAddr = (reg_value << 3) + bank2_addr;
}
#endif
else
{
/* Nothing to do */
}
}
*PCROPConfig |= (READ_REG(FLASH->PCROP1ER) & FLASH_PCROP1ER_PCROP_RDP);
}
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_FLASH_MODULE_ENABLED */
/**
* @}
*/
/**
* @}
*/
| 48,968 | C | 33.148536 | 116 | 0.632576 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_pwr_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_pwr_ex.h
* @author MCD Application Team
* @brief Header file of PWR HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_PWR_EX_H
#define STM32G4xx_HAL_PWR_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup PWREx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup PWREx_Exported_Types PWR Extended Exported Types
* @{
*/
/**
* @brief PWR PVM configuration structure definition
*/
typedef struct
{
uint32_t PVMType; /*!< PVMType: Specifies which voltage is monitored and against which threshold.
This parameter can be a value of @ref PWREx_PVM_Type. */
uint32_t Mode; /*!< Mode: Specifies the operating mode for the selected pins.
This parameter can be a value of @ref PWREx_PVM_Mode. */
}PWR_PVMTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup PWREx_Exported_Constants PWR Extended Exported Constants
* @{
*/
/** @defgroup PWREx_WUP_Polarity Shift to apply to retrieve polarity information from PWR_WAKEUP_PINy_xxx constants
* @{
*/
#define PWR_WUP_POLARITY_SHIFT 0x05U /*!< Internal constant used to retrieve wakeup pin polariry */
/**
* @}
*/
/** @defgroup PWREx_WakeUp_Pins PWR wake-up pins
* @{
*/
#define PWR_WAKEUP_PIN1 PWR_CR3_EWUP1 /*!< Wakeup pin 1 (with high level polarity) */
#define PWR_WAKEUP_PIN2 PWR_CR3_EWUP2 /*!< Wakeup pin 2 (with high level polarity) */
#define PWR_WAKEUP_PIN3 PWR_CR3_EWUP3 /*!< Wakeup pin 3 (with high level polarity) */
#define PWR_WAKEUP_PIN4 PWR_CR3_EWUP4 /*!< Wakeup pin 4 (with high level polarity) */
#define PWR_WAKEUP_PIN5 PWR_CR3_EWUP5 /*!< Wakeup pin 5 (with high level polarity) */
#define PWR_WAKEUP_PIN1_HIGH PWR_CR3_EWUP1 /*!< Wakeup pin 1 (with high level polarity) */
#define PWR_WAKEUP_PIN2_HIGH PWR_CR3_EWUP2 /*!< Wakeup pin 2 (with high level polarity) */
#define PWR_WAKEUP_PIN3_HIGH PWR_CR3_EWUP3 /*!< Wakeup pin 3 (with high level polarity) */
#define PWR_WAKEUP_PIN4_HIGH PWR_CR3_EWUP4 /*!< Wakeup pin 4 (with high level polarity) */
#define PWR_WAKEUP_PIN5_HIGH PWR_CR3_EWUP5 /*!< Wakeup pin 5 (with high level polarity) */
#define PWR_WAKEUP_PIN1_LOW (uint32_t)((PWR_CR4_WP1<<PWR_WUP_POLARITY_SHIFT) | PWR_CR3_EWUP1) /*!< Wakeup pin 1 (with low level polarity) */
#define PWR_WAKEUP_PIN2_LOW (uint32_t)((PWR_CR4_WP2<<PWR_WUP_POLARITY_SHIFT) | PWR_CR3_EWUP2) /*!< Wakeup pin 2 (with low level polarity) */
#define PWR_WAKEUP_PIN3_LOW (uint32_t)((PWR_CR4_WP3<<PWR_WUP_POLARITY_SHIFT) | PWR_CR3_EWUP3) /*!< Wakeup pin 3 (with low level polarity) */
#define PWR_WAKEUP_PIN4_LOW (uint32_t)((PWR_CR4_WP4<<PWR_WUP_POLARITY_SHIFT) | PWR_CR3_EWUP4) /*!< Wakeup pin 4 (with low level polarity) */
#define PWR_WAKEUP_PIN5_LOW (uint32_t)((PWR_CR4_WP5<<PWR_WUP_POLARITY_SHIFT) | PWR_CR3_EWUP5) /*!< Wakeup pin 5 (with low level polarity) */
/**
* @}
*/
/** @defgroup PWREx_PVM_Type Peripheral Voltage Monitoring type
* @{
*/
#if defined(PWR_CR2_PVME1)
#define PWR_PVM_1 PWR_CR2_PVME1 /*!< Peripheral Voltage Monitoring 1 enable: VDDUSB versus 1.2 V (applicable when USB feature is supported) */
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
#define PWR_PVM_2 PWR_CR2_PVME2 /*!< Peripheral Voltage Monitoring 2 enable: VDDIO2 versus 0.9 V (applicable when VDDIO2 is present on device) */
#endif /* PWR_CR2_PVME2 */
#define PWR_PVM_3 PWR_CR2_PVME3 /*!< Peripheral Voltage Monitoring 3 enable: VDDA versus 1.62 V */
#define PWR_PVM_4 PWR_CR2_PVME4 /*!< Peripheral Voltage Monitoring 4 enable: VDDA versus 2.2 V */
/**
* @}
*/
/** @defgroup PWREx_PVM_Mode PWR PVM interrupt and event mode
* @{
*/
#define PWR_PVM_MODE_NORMAL 0x00000000U /*!< basic mode is used */
#define PWR_PVM_MODE_IT_RISING 0x00010001U /*!< External Interrupt Mode with Rising edge trigger detection */
#define PWR_PVM_MODE_IT_FALLING 0x00010002U /*!< External Interrupt Mode with Falling edge trigger detection */
#define PWR_PVM_MODE_IT_RISING_FALLING 0x00010003U /*!< External Interrupt Mode with Rising/Falling edge trigger detection */
#define PWR_PVM_MODE_EVENT_RISING 0x00020001U /*!< Event Mode with Rising edge trigger detection */
#define PWR_PVM_MODE_EVENT_FALLING 0x00020002U /*!< Event Mode with Falling edge trigger detection */
#define PWR_PVM_MODE_EVENT_RISING_FALLING 0x00020003U /*!< Event Mode with Rising/Falling edge trigger detection */
/**
* @}
*/
/** @defgroup PWREx_Regulator_Voltage_Scale PWR Regulator voltage scale
* @{
*/
#if defined(PWR_CR5_R1MODE)
#define PWR_REGULATOR_VOLTAGE_SCALE1_BOOST ((uint32_t)0x00000000) /*!< Voltage scaling range 1 boost mode */
#endif /*PWR_CR5_R1MODE */
#define PWR_REGULATOR_VOLTAGE_SCALE1 PWR_CR1_VOS_0 /*!< Voltage scaling range 1 normal mode */
#define PWR_REGULATOR_VOLTAGE_SCALE2 PWR_CR1_VOS_1 /*!< Voltage scaling range 2 */
/**
* @}
*/
/** @defgroup PWREx_VBAT_Battery_Charging_Selection PWR battery charging resistor selection
* @{
*/
#define PWR_BATTERY_CHARGING_RESISTOR_5 0x00000000U /*!< VBAT charging through a 5 kOhms resistor */
#define PWR_BATTERY_CHARGING_RESISTOR_1_5 PWR_CR4_VBRS /*!< VBAT charging through a 1.5 kOhms resistor */
/**
* @}
*/
/** @defgroup PWREx_VBAT_Battery_Charging PWR battery charging
* @{
*/
#define PWR_BATTERY_CHARGING_DISABLE 0x00000000U
#define PWR_BATTERY_CHARGING_ENABLE PWR_CR4_VBE
/**
* @}
*/
/** @defgroup PWREx_GPIO_Bit_Number GPIO bit number for I/O setting in standby/shutdown mode
* @{
*/
#define PWR_GPIO_BIT_0 PWR_PUCRA_PA0 /*!< GPIO port I/O pin 0 */
#define PWR_GPIO_BIT_1 PWR_PUCRA_PA1 /*!< GPIO port I/O pin 1 */
#define PWR_GPIO_BIT_2 PWR_PUCRA_PA2 /*!< GPIO port I/O pin 2 */
#define PWR_GPIO_BIT_3 PWR_PUCRA_PA3 /*!< GPIO port I/O pin 3 */
#define PWR_GPIO_BIT_4 PWR_PUCRA_PA4 /*!< GPIO port I/O pin 4 */
#define PWR_GPIO_BIT_5 PWR_PUCRA_PA5 /*!< GPIO port I/O pin 5 */
#define PWR_GPIO_BIT_6 PWR_PUCRA_PA6 /*!< GPIO port I/O pin 6 */
#define PWR_GPIO_BIT_7 PWR_PUCRA_PA7 /*!< GPIO port I/O pin 7 */
#define PWR_GPIO_BIT_8 PWR_PUCRA_PA8 /*!< GPIO port I/O pin 8 */
#define PWR_GPIO_BIT_9 PWR_PUCRA_PA9 /*!< GPIO port I/O pin 9 */
#define PWR_GPIO_BIT_10 PWR_PUCRA_PA10 /*!< GPIO port I/O pin 10 */
#define PWR_GPIO_BIT_11 PWR_PUCRA_PA11 /*!< GPIO port I/O pin 11 */
#define PWR_GPIO_BIT_12 PWR_PUCRA_PA12 /*!< GPIO port I/O pin 12 */
#define PWR_GPIO_BIT_13 PWR_PUCRA_PA13 /*!< GPIO port I/O pin 13 */
#define PWR_GPIO_BIT_14 PWR_PDCRA_PA14 /*!< GPIO port I/O pin 14 */
#define PWR_GPIO_BIT_15 PWR_PUCRA_PA15 /*!< GPIO port I/O pin 15 */
/**
* @}
*/
/** @defgroup PWREx_GPIO GPIO port
* @{
*/
#define PWR_GPIO_A 0x00000000U /*!< GPIO port A */
#define PWR_GPIO_B 0x00000001U /*!< GPIO port B */
#define PWR_GPIO_C 0x00000002U /*!< GPIO port C */
#define PWR_GPIO_D 0x00000003U /*!< GPIO port D */
#define PWR_GPIO_E 0x00000004U /*!< GPIO port E */
#define PWR_GPIO_F 0x00000005U /*!< GPIO port F */
#define PWR_GPIO_G 0x00000006U /*!< GPIO port G */
/**
* @}
*/
/** @defgroup PWREx_PVM_EXTI_LINE PWR PVM external interrupts lines
* @{
*/
#if defined(PWR_CR2_PVME1)
#define PWR_EXTI_LINE_PVM1 0x00000008U /*!< External interrupt line 35 Connected to the PVM1 EXTI Line */
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
#define PWR_EXTI_LINE_PVM2 0x00000010U /*!< External interrupt line 36 Connected to the PVM2 EXTI Line */
#endif /* PWR_CR2_PVME2 */
#define PWR_EXTI_LINE_PVM3 0x00000020U /*!< External interrupt line 37 Connected to the PVM3 EXTI Line */
#define PWR_EXTI_LINE_PVM4 0x00000040U /*!< External interrupt line 38 Connected to the PVM4 EXTI Line */
/**
* @}
*/
/** @defgroup PWREx_PVM_EVENT_LINE PWR PVM event lines
* @{
*/
#if defined(PWR_CR2_PVME1)
#define PWR_EVENT_LINE_PVM1 0x00000008U /*!< Event line 35 Connected to the PVM1 EXTI Line */
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
#define PWR_EVENT_LINE_PVM2 0x00000010U /*!< Event line 36 Connected to the PVM2 EXTI Line */
#endif /* PWR_CR2_PVME2 */
#define PWR_EVENT_LINE_PVM3 0x00000020U /*!< Event line 37 Connected to the PVM3 EXTI Line */
#define PWR_EVENT_LINE_PVM4 0x00000040U /*!< Event line 38 Connected to the PVM4 EXTI Line */
/**
* @}
*/
/** @defgroup PWREx_Flag PWR Status Flags
* Elements values convention: 0000 0000 0XXY YYYYb
* - Y YYYY : Flag position in the XX register (5 bits)
* - XX : Status register (2 bits)
* - 01: SR1 register
* - 10: SR2 register
* The only exception is PWR_FLAG_WU, encompassing all
* wake-up flags and set to PWR_SR1_WUF.
* @{
*/
#define PWR_FLAG_WUF1 0x0020U /*!< Wakeup event on wakeup pin 1 */
#define PWR_FLAG_WUF2 0x0021U /*!< Wakeup event on wakeup pin 2 */
#define PWR_FLAG_WUF3 0x0022U /*!< Wakeup event on wakeup pin 3 */
#define PWR_FLAG_WUF4 0x0023U /*!< Wakeup event on wakeup pin 4 */
#define PWR_FLAG_WUF5 0x0024U /*!< Wakeup event on wakeup pin 5 */
#define PWR_FLAG_WU PWR_SR1_WUF /*!< Encompass wakeup event on all wakeup pins */
#define PWR_FLAG_SB 0x0028U /*!< Standby flag */
#define PWR_FLAG_WUFI 0x002FU /*!< Wakeup on internal wakeup line */
#define PWR_FLAG_REGLPS 0x0048U /*!< Low-power regulator start flag */
#define PWR_FLAG_REGLPF 0x0049U /*!< Low-power regulator flag */
#define PWR_FLAG_VOSF 0x004AU /*!< Voltage scaling flag */
#define PWR_FLAG_PVDO 0x004BU /*!< Power Voltage Detector output flag */
#if defined(PWR_CR2_PVME1)
#define PWR_FLAG_PVMO1 0x004CU /*!< Power Voltage Monitoring 1 output flag */
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
#define PWR_FLAG_PVMO2 0x004DU /*!< Power Voltage Monitoring 2 output flag */
#endif /* PWR_CR2_PVME2 */
#define PWR_FLAG_PVMO3 0x004EU /*!< Power Voltage Monitoring 3 output flag */
#define PWR_FLAG_PVMO4 0x004FU /*!< Power Voltage Monitoring 4 output flag */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup PWREx_Exported_Macros PWR Extended Exported Macros
* @{
*/
#if defined(PWR_CR2_PVME1)
/**
* @brief Enable the PVM1 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_ENABLE_IT() SET_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM1)
/**
* @brief Disable the PVM1 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_DISABLE_IT() CLEAR_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM1)
/**
* @brief Enable the PVM1 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_ENABLE_EVENT() SET_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM1)
/**
* @brief Disable the PVM1 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_DISABLE_EVENT() CLEAR_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM1)
/**
* @brief Enable the PVM1 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_ENABLE_RISING_EDGE() SET_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM1)
/**
* @brief Disable the PVM1 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_DISABLE_RISING_EDGE() CLEAR_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM1)
/**
* @brief Enable the PVM1 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_ENABLE_FALLING_EDGE() SET_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM1)
/**
* @brief Disable the PVM1 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_DISABLE_FALLING_EDGE() CLEAR_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM1)
/**
* @brief PVM1 EXTI line configuration: set rising & falling edge trigger.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_ENABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM1_EXTI_ENABLE_RISING_EDGE(); \
__HAL_PWR_PVM1_EXTI_ENABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Disable the PVM1 Extended Interrupt Rising & Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_DISABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM1_EXTI_DISABLE_RISING_EDGE(); \
__HAL_PWR_PVM1_EXTI_DISABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Generate a Software interrupt on selected EXTI line.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_GENERATE_SWIT() SET_BIT(EXTI->SWIER2, PWR_EXTI_LINE_PVM1)
/**
* @brief Check whether the specified PVM1 EXTI interrupt flag is set or not.
* @retval EXTI PVM1 Line Status.
*/
#define __HAL_PWR_PVM1_EXTI_GET_FLAG() (EXTI->PR2 & PWR_EXTI_LINE_PVM1)
/**
* @brief Clear the PVM1 EXTI flag.
* @retval None
*/
#define __HAL_PWR_PVM1_EXTI_CLEAR_FLAG() WRITE_REG(EXTI->PR2, PWR_EXTI_LINE_PVM1)
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
/**
* @brief Enable the PVM2 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_ENABLE_IT() SET_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM2)
/**
* @brief Disable the PVM2 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_DISABLE_IT() CLEAR_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM2)
/**
* @brief Enable the PVM2 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_ENABLE_EVENT() SET_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM2)
/**
* @brief Disable the PVM2 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_DISABLE_EVENT() CLEAR_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM2)
/**
* @brief Enable the PVM2 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_ENABLE_RISING_EDGE() SET_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM2)
/**
* @brief Disable the PVM2 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_DISABLE_RISING_EDGE() CLEAR_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM2)
/**
* @brief Enable the PVM2 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_ENABLE_FALLING_EDGE() SET_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM2)
/**
* @brief Disable the PVM2 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_DISABLE_FALLING_EDGE() CLEAR_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM2)
/**
* @brief PVM2 EXTI line configuration: set rising & falling edge trigger.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_ENABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM2_EXTI_ENABLE_RISING_EDGE(); \
__HAL_PWR_PVM2_EXTI_ENABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Disable the PVM2 Extended Interrupt Rising & Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_DISABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM2_EXTI_DISABLE_RISING_EDGE(); \
__HAL_PWR_PVM2_EXTI_DISABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Generate a Software interrupt on selected EXTI line.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_GENERATE_SWIT() SET_BIT(EXTI->SWIER2, PWR_EXTI_LINE_PVM2)
/**
* @brief Check whether the specified PVM2 EXTI interrupt flag is set or not.
* @retval EXTI PVM2 Line Status.
*/
#define __HAL_PWR_PVM2_EXTI_GET_FLAG() (EXTI->PR2 & PWR_EXTI_LINE_PVM2)
/**
* @brief Clear the PVM2 EXTI flag.
* @retval None
*/
#define __HAL_PWR_PVM2_EXTI_CLEAR_FLAG() WRITE_REG(EXTI->PR2, PWR_EXTI_LINE_PVM2)
#endif /* PWR_CR2_PVME2 */
/**
* @brief Enable the PVM3 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_ENABLE_IT() SET_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM3)
/**
* @brief Disable the PVM3 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_DISABLE_IT() CLEAR_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM3)
/**
* @brief Enable the PVM3 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_ENABLE_EVENT() SET_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM3)
/**
* @brief Disable the PVM3 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_DISABLE_EVENT() CLEAR_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM3)
/**
* @brief Enable the PVM3 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_ENABLE_RISING_EDGE() SET_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM3)
/**
* @brief Disable the PVM3 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_DISABLE_RISING_EDGE() CLEAR_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM3)
/**
* @brief Enable the PVM3 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_ENABLE_FALLING_EDGE() SET_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM3)
/**
* @brief Disable the PVM3 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_DISABLE_FALLING_EDGE() CLEAR_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM3)
/**
* @brief PVM3 EXTI line configuration: set rising & falling edge trigger.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_ENABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM3_EXTI_ENABLE_RISING_EDGE(); \
__HAL_PWR_PVM3_EXTI_ENABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Disable the PVM3 Extended Interrupt Rising & Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_DISABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM3_EXTI_DISABLE_RISING_EDGE(); \
__HAL_PWR_PVM3_EXTI_DISABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Generate a Software interrupt on selected EXTI line.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_GENERATE_SWIT() SET_BIT(EXTI->SWIER2, PWR_EXTI_LINE_PVM3)
/**
* @brief Check whether the specified PVM3 EXTI interrupt flag is set or not.
* @retval EXTI PVM3 Line Status.
*/
#define __HAL_PWR_PVM3_EXTI_GET_FLAG() (EXTI->PR2 & PWR_EXTI_LINE_PVM3)
/**
* @brief Clear the PVM3 EXTI flag.
* @retval None
*/
#define __HAL_PWR_PVM3_EXTI_CLEAR_FLAG() WRITE_REG(EXTI->PR2, PWR_EXTI_LINE_PVM3)
/**
* @brief Enable the PVM4 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_ENABLE_IT() SET_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM4)
/**
* @brief Disable the PVM4 Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_DISABLE_IT() CLEAR_BIT(EXTI->IMR2, PWR_EXTI_LINE_PVM4)
/**
* @brief Enable the PVM4 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_ENABLE_EVENT() SET_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM4)
/**
* @brief Disable the PVM4 Event Line.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_DISABLE_EVENT() CLEAR_BIT(EXTI->EMR2, PWR_EVENT_LINE_PVM4)
/**
* @brief Enable the PVM4 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_ENABLE_RISING_EDGE() SET_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM4)
/**
* @brief Disable the PVM4 Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_DISABLE_RISING_EDGE() CLEAR_BIT(EXTI->RTSR2, PWR_EXTI_LINE_PVM4)
/**
* @brief Enable the PVM4 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_ENABLE_FALLING_EDGE() SET_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM4)
/**
* @brief Disable the PVM4 Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_DISABLE_FALLING_EDGE() CLEAR_BIT(EXTI->FTSR2, PWR_EXTI_LINE_PVM4)
/**
* @brief PVM4 EXTI line configuration: set rising & falling edge trigger.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_ENABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM4_EXTI_ENABLE_RISING_EDGE(); \
__HAL_PWR_PVM4_EXTI_ENABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Disable the PVM4 Extended Interrupt Rising & Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_DISABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVM4_EXTI_DISABLE_RISING_EDGE(); \
__HAL_PWR_PVM4_EXTI_DISABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Generate a Software interrupt on selected EXTI line.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_GENERATE_SWIT() SET_BIT(EXTI->SWIER2, PWR_EXTI_LINE_PVM4)
/**
* @brief Check whether or not the specified PVM4 EXTI interrupt flag is set.
* @retval EXTI PVM4 Line Status.
*/
#define __HAL_PWR_PVM4_EXTI_GET_FLAG() (EXTI->PR2 & PWR_EXTI_LINE_PVM4)
/**
* @brief Clear the PVM4 EXTI flag.
* @retval None
*/
#define __HAL_PWR_PVM4_EXTI_CLEAR_FLAG() WRITE_REG(EXTI->PR2, PWR_EXTI_LINE_PVM4)
/**
* @brief Configure the main internal regulator output voltage.
* @param __REGULATOR__: specifies the regulator output voltage to achieve
* a tradeoff between performance and power consumption.
* This parameter can be one of the following values:
* @arg @ref PWR_REGULATOR_VOLTAGE_SCALE1_BOOST Regulator voltage output range 1 mode,
* typical output voltage at 1.28 V,
* system frequency up to 170 MHz.
* @arg @ref PWR_REGULATOR_VOLTAGE_SCALE1 Regulator voltage output range 1 mode,
* typical output voltage at 1.2 V,
* system frequency up to 150 MHz.
* @arg @ref PWR_REGULATOR_VOLTAGE_SCALE2 Regulator voltage output range 2 mode,
* typical output voltage at 1.0 V,
* system frequency up to 26 MHz.
* @note This macro is similar to HAL_PWREx_ControlVoltageScaling() API but doesn't check
* whether or not VOSF flag is cleared when moving from range 2 to range 1. User
* may resort to __HAL_PWR_GET_FLAG() macro to check VOSF bit resetting.
* @retval None
*/
#define __HAL_PWR_VOLTAGESCALING_CONFIG(__REGULATOR__) do { \
__IO uint32_t tmpreg; \
MODIFY_REG(PWR->CR1, PWR_CR1_VOS, (__REGULATOR__)); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(PWR->CR1, PWR_CR1_VOS); \
UNUSED(tmpreg); \
} while(0)
/**
* @}
*/
/* Private macros --------------------------------------------------------*/
/** @addtogroup PWREx_Private_Macros PWR Extended Private Macros
* @{
*/
#define IS_PWR_WAKEUP_PIN(PIN) (((PIN) == PWR_WAKEUP_PIN1) || \
((PIN) == PWR_WAKEUP_PIN2) || \
((PIN) == PWR_WAKEUP_PIN3) || \
((PIN) == PWR_WAKEUP_PIN4) || \
((PIN) == PWR_WAKEUP_PIN5) || \
((PIN) == PWR_WAKEUP_PIN1_HIGH) || \
((PIN) == PWR_WAKEUP_PIN2_HIGH) || \
((PIN) == PWR_WAKEUP_PIN3_HIGH) || \
((PIN) == PWR_WAKEUP_PIN4_HIGH) || \
((PIN) == PWR_WAKEUP_PIN5_HIGH) || \
((PIN) == PWR_WAKEUP_PIN1_LOW) || \
((PIN) == PWR_WAKEUP_PIN2_LOW) || \
((PIN) == PWR_WAKEUP_PIN3_LOW) || \
((PIN) == PWR_WAKEUP_PIN4_LOW) || \
((PIN) == PWR_WAKEUP_PIN5_LOW))
#define IS_PWR_PVM_TYPE(TYPE) (((TYPE) == PWR_PVM_1) ||\
((TYPE) == PWR_PVM_2) ||\
((TYPE) == PWR_PVM_3) ||\
((TYPE) == PWR_PVM_4))
#define IS_PWR_PVM_MODE(MODE) (((MODE) == PWR_PVM_MODE_NORMAL) ||\
((MODE) == PWR_PVM_MODE_IT_RISING) ||\
((MODE) == PWR_PVM_MODE_IT_FALLING) ||\
((MODE) == PWR_PVM_MODE_IT_RISING_FALLING) ||\
((MODE) == PWR_PVM_MODE_EVENT_RISING) ||\
((MODE) == PWR_PVM_MODE_EVENT_FALLING) ||\
((MODE) == PWR_PVM_MODE_EVENT_RISING_FALLING))
#if defined(PWR_CR5_R1MODE)
#define IS_PWR_VOLTAGE_SCALING_RANGE(RANGE) (((RANGE) == PWR_REGULATOR_VOLTAGE_SCALE1_BOOST) || \
((RANGE) == PWR_REGULATOR_VOLTAGE_SCALE1) || \
((RANGE) == PWR_REGULATOR_VOLTAGE_SCALE2))
#else
#define IS_PWR_VOLTAGE_SCALING_RANGE(RANGE) (((RANGE) == PWR_REGULATOR_VOLTAGE_SCALE1) || \
((RANGE) == PWR_REGULATOR_VOLTAGE_SCALE2))
#endif
#define IS_PWR_BATTERY_RESISTOR_SELECT(RESISTOR) (((RESISTOR) == PWR_BATTERY_CHARGING_RESISTOR_5) ||\
((RESISTOR) == PWR_BATTERY_CHARGING_RESISTOR_1_5))
#define IS_PWR_BATTERY_CHARGING(CHARGING) (((CHARGING) == PWR_BATTERY_CHARGING_DISABLE) ||\
((CHARGING) == PWR_BATTERY_CHARGING_ENABLE))
#define IS_PWR_GPIO_BIT_NUMBER(BIT_NUMBER) (((BIT_NUMBER) & GPIO_PIN_MASK) != (uint32_t)0x00U)
#define IS_PWR_GPIO(GPIO) (((GPIO) == PWR_GPIO_A) ||\
((GPIO) == PWR_GPIO_B) ||\
((GPIO) == PWR_GPIO_C) ||\
((GPIO) == PWR_GPIO_D) ||\
((GPIO) == PWR_GPIO_E) ||\
((GPIO) == PWR_GPIO_F) ||\
((GPIO) == PWR_GPIO_G))
/**
* @}
*/
/** @addtogroup PWREx_Exported_Functions PWR Extended Exported Functions
* @{
*/
/** @addtogroup PWREx_Exported_Functions_Group1 Extended Peripheral Control functions
* @{
*/
/* Peripheral Control functions **********************************************/
uint32_t HAL_PWREx_GetVoltageRange(void);
HAL_StatusTypeDef HAL_PWREx_ControlVoltageScaling(uint32_t VoltageScaling);
void HAL_PWREx_EnableBatteryCharging(uint32_t ResistorSelection);
void HAL_PWREx_DisableBatteryCharging(void);
void HAL_PWREx_EnableInternalWakeUpLine(void);
void HAL_PWREx_DisableInternalWakeUpLine(void);
HAL_StatusTypeDef HAL_PWREx_EnableGPIOPullUp(uint32_t GPIO, uint32_t GPIONumber);
HAL_StatusTypeDef HAL_PWREx_DisableGPIOPullUp(uint32_t GPIO, uint32_t GPIONumber);
HAL_StatusTypeDef HAL_PWREx_EnableGPIOPullDown(uint32_t GPIO, uint32_t GPIONumber);
HAL_StatusTypeDef HAL_PWREx_DisableGPIOPullDown(uint32_t GPIO, uint32_t GPIONumber);
void HAL_PWREx_EnablePullUpPullDownConfig(void);
void HAL_PWREx_DisablePullUpPullDownConfig(void);
void HAL_PWREx_EnableSRAM2ContentRetention(void);
void HAL_PWREx_DisableSRAM2ContentRetention(void);
#if defined(PWR_CR2_PVME1)
void HAL_PWREx_EnablePVM1(void);
void HAL_PWREx_DisablePVM1(void);
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
void HAL_PWREx_EnablePVM2(void);
void HAL_PWREx_DisablePVM2(void);
#endif /* PWR_CR2_PVME2 */
void HAL_PWREx_EnablePVM3(void);
void HAL_PWREx_DisablePVM3(void);
void HAL_PWREx_EnablePVM4(void);
void HAL_PWREx_DisablePVM4(void);
HAL_StatusTypeDef HAL_PWREx_ConfigPVM(PWR_PVMTypeDef *sConfigPVM);
/* Low Power modes configuration functions ************************************/
void HAL_PWREx_EnableLowPowerRunMode(void);
HAL_StatusTypeDef HAL_PWREx_DisableLowPowerRunMode(void);
void HAL_PWREx_EnterSTOP0Mode(uint8_t STOPEntry);
void HAL_PWREx_EnterSTOP1Mode(uint8_t STOPEntry);
void HAL_PWREx_EnterSHUTDOWNMode(void);
void HAL_PWREx_PVD_PVM_IRQHandler(void);
#if defined(PWR_CR2_PVME1)
void HAL_PWREx_PVM1Callback(void);
#endif /* PWR_CR2_PVME1 */
#if defined(PWR_CR2_PVME2)
void HAL_PWREx_PVM2Callback(void);
#endif /* PWR_CR2_PVME2 */
void HAL_PWREx_PVM3Callback(void);
void HAL_PWREx_PVM4Callback(void);
#if defined(PWR_CR3_UCPD_STDBY)
void HAL_PWREx_EnableUCPDStandbyMode(void);
void HAL_PWREx_DisableUCPDStandbyMode(void);
#endif /* PWR_CR3_UCPD_STDBY */
#if defined(PWR_CR3_UCPD_DBDIS)
void HAL_PWREx_EnableUCPDDeadBattery(void);
void HAL_PWREx_DisableUCPDDeadBattery(void);
#endif /* PWR_CR3_UCPD_DBDIS */
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_PWR_EX_H */
| 30,700 | C | 36.531785 | 163 | 0.578697 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_uart.h | /**
******************************************************************************
* @file stm32g4xx_hal_uart.h
* @author MCD Application Team
* @brief Header file of UART HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_UART_H
#define STM32G4xx_HAL_UART_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup UART
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup UART_Exported_Types UART Exported Types
* @{
*/
/**
* @brief UART Init Structure definition
*/
typedef struct
{
uint32_t BaudRate; /*!< This member configures the UART communication baud rate.
The baud rate register is computed using the following formula:
LPUART:
=======
Baud Rate Register = ((256 * lpuart_ker_ckpres) / ((huart->Init.BaudRate)))
where lpuart_ker_ck_pres is the UART input clock divided by a prescaler
UART:
=====
- If oversampling is 16 or in LIN mode,
Baud Rate Register = ((uart_ker_ckpres) / ((huart->Init.BaudRate)))
- If oversampling is 8,
Baud Rate Register[15:4] = ((2 * uart_ker_ckpres) /
((huart->Init.BaudRate)))[15:4]
Baud Rate Register[3] = 0
Baud Rate Register[2:0] = (((2 * uart_ker_ckpres) /
((huart->Init.BaudRate)))[3:0]) >> 1
where uart_ker_ck_pres is the UART input clock divided by a prescaler */
uint32_t WordLength; /*!< Specifies the number of data bits transmitted or received in a frame.
This parameter can be a value of @ref UARTEx_Word_Length. */
uint32_t StopBits; /*!< Specifies the number of stop bits transmitted.
This parameter can be a value of @ref UART_Stop_Bits. */
uint32_t Parity; /*!< Specifies the parity mode.
This parameter can be a value of @ref UART_Parity
@note When parity is enabled, the computed parity is inserted
at the MSB position of the transmitted data (9th bit when
the word length is set to 9 data bits; 8th bit when the
word length is set to 8 data bits). */
uint32_t Mode; /*!< Specifies whether the Receive or Transmit mode is enabled or disabled.
This parameter can be a value of @ref UART_Mode. */
uint32_t HwFlowCtl; /*!< Specifies whether the hardware flow control mode is enabled
or disabled.
This parameter can be a value of @ref UART_Hardware_Flow_Control. */
uint32_t OverSampling; /*!< Specifies whether the Over sampling 8 is enabled or disabled,
to achieve higher speed (up to f_PCLK/8).
This parameter can be a value of @ref UART_Over_Sampling. */
uint32_t OneBitSampling; /*!< Specifies whether a single sample or three samples' majority vote is selected.
Selecting the single sample method increases the receiver tolerance to clock
deviations. This parameter can be a value of @ref UART_OneBit_Sampling. */
uint32_t ClockPrescaler; /*!< Specifies the prescaler value used to divide the UART clock source.
This parameter can be a value of @ref UART_ClockPrescaler. */
} UART_InitTypeDef;
/**
* @brief UART Advanced Features initialization structure definition
*/
typedef struct
{
uint32_t AdvFeatureInit; /*!< Specifies which advanced UART features is initialized. Several
Advanced Features may be initialized at the same time .
This parameter can be a value of
@ref UART_Advanced_Features_Initialization_Type. */
uint32_t TxPinLevelInvert; /*!< Specifies whether the TX pin active level is inverted.
This parameter can be a value of @ref UART_Tx_Inv. */
uint32_t RxPinLevelInvert; /*!< Specifies whether the RX pin active level is inverted.
This parameter can be a value of @ref UART_Rx_Inv. */
uint32_t DataInvert; /*!< Specifies whether data are inverted (positive/direct logic
vs negative/inverted logic).
This parameter can be a value of @ref UART_Data_Inv. */
uint32_t Swap; /*!< Specifies whether TX and RX pins are swapped.
This parameter can be a value of @ref UART_Rx_Tx_Swap. */
uint32_t OverrunDisable; /*!< Specifies whether the reception overrun detection is disabled.
This parameter can be a value of @ref UART_Overrun_Disable. */
uint32_t DMADisableonRxError; /*!< Specifies whether the DMA is disabled in case of reception error.
This parameter can be a value of @ref UART_DMA_Disable_on_Rx_Error. */
uint32_t AutoBaudRateEnable; /*!< Specifies whether auto Baud rate detection is enabled.
This parameter can be a value of @ref UART_AutoBaudRate_Enable. */
uint32_t AutoBaudRateMode; /*!< If auto Baud rate detection is enabled, specifies how the rate
detection is carried out.
This parameter can be a value of @ref UART_AutoBaud_Rate_Mode. */
uint32_t MSBFirst; /*!< Specifies whether MSB is sent first on UART line.
This parameter can be a value of @ref UART_MSB_First. */
} UART_AdvFeatureInitTypeDef;
/**
* @brief HAL UART State definition
* @note HAL UART State value is a combination of 2 different substates:
* gState and RxState (see @ref UART_State_Definition).
* - gState contains UART state information related to global Handle management
* and also information related to Tx operations.
* gState value coding follow below described bitmap :
* b7-b6 Error information
* 00 : No Error
* 01 : (Not Used)
* 10 : Timeout
* 11 : Error
* b5 Peripheral initialization status
* 0 : Reset (Peripheral not initialized)
* 1 : Init done (Peripheral initialized. HAL UART Init function already called)
* b4-b3 (not used)
* xx : Should be set to 00
* b2 Intrinsic process state
* 0 : Ready
* 1 : Busy (Peripheral busy with some configuration or internal operations)
* b1 (not used)
* x : Should be set to 0
* b0 Tx state
* 0 : Ready (no Tx operation ongoing)
* 1 : Busy (Tx operation ongoing)
* - RxState contains information related to Rx operations.
* RxState value coding follow below described bitmap :
* b7-b6 (not used)
* xx : Should be set to 00
* b5 Peripheral initialization status
* 0 : Reset (Peripheral not initialized)
* 1 : Init done (Peripheral initialized)
* b4-b2 (not used)
* xxx : Should be set to 000
* b1 Rx state
* 0 : Ready (no Rx operation ongoing)
* 1 : Busy (Rx operation ongoing)
* b0 (not used)
* x : Should be set to 0.
*/
typedef uint32_t HAL_UART_StateTypeDef;
/**
* @brief UART clock sources definition
*/
typedef enum
{
UART_CLOCKSOURCE_PCLK1 = 0x00U, /*!< PCLK1 clock source */
UART_CLOCKSOURCE_PCLK2 = 0x01U, /*!< PCLK2 clock source */
UART_CLOCKSOURCE_HSI = 0x02U, /*!< HSI clock source */
UART_CLOCKSOURCE_SYSCLK = 0x04U, /*!< SYSCLK clock source */
UART_CLOCKSOURCE_LSE = 0x08U, /*!< LSE clock source */
UART_CLOCKSOURCE_UNDEFINED = 0x10U /*!< Undefined clock source */
} UART_ClockSourceTypeDef;
/**
* @brief HAL UART Reception type definition
* @note HAL UART Reception type value aims to identify which type of Reception is ongoing.
* This parameter can be a value of @ref UART_Reception_Type_Values :
* HAL_UART_RECEPTION_STANDARD = 0x00U,
* HAL_UART_RECEPTION_TOIDLE = 0x01U,
* HAL_UART_RECEPTION_TORTO = 0x02U,
* HAL_UART_RECEPTION_TOCHARMATCH = 0x03U,
*/
typedef uint32_t HAL_UART_RxTypeTypeDef;
/**
* @brief HAL UART Rx Event type definition
* @note HAL UART Rx Event type value aims to identify which type of Event has occurred
* leading to call of the RxEvent callback.
* This parameter can be a value of @ref UART_RxEvent_Type_Values :
* HAL_UART_RXEVENT_TC = 0x00U,
* HAL_UART_RXEVENT_HT = 0x01U,
* HAL_UART_RXEVENT_IDLE = 0x02U,
*/
typedef uint32_t HAL_UART_RxEventTypeTypeDef;
/**
* @brief UART handle Structure definition
*/
typedef struct __UART_HandleTypeDef
{
USART_TypeDef *Instance; /*!< UART registers base address */
UART_InitTypeDef Init; /*!< UART communication parameters */
UART_AdvFeatureInitTypeDef AdvancedInit; /*!< UART Advanced Features initialization parameters */
const uint8_t *pTxBuffPtr; /*!< Pointer to UART Tx transfer Buffer */
uint16_t TxXferSize; /*!< UART Tx Transfer size */
__IO uint16_t TxXferCount; /*!< UART Tx Transfer Counter */
uint8_t *pRxBuffPtr; /*!< Pointer to UART Rx transfer Buffer */
uint16_t RxXferSize; /*!< UART Rx Transfer size */
__IO uint16_t RxXferCount; /*!< UART Rx Transfer Counter */
uint16_t Mask; /*!< UART Rx RDR register mask */
uint32_t FifoMode; /*!< Specifies if the FIFO mode is being used.
This parameter can be a value of @ref UARTEx_FIFO_mode. */
uint16_t NbRxDataToProcess; /*!< Number of data to process during RX ISR execution */
uint16_t NbTxDataToProcess; /*!< Number of data to process during TX ISR execution */
__IO HAL_UART_RxTypeTypeDef ReceptionType; /*!< Type of ongoing reception */
__IO HAL_UART_RxEventTypeTypeDef RxEventType; /*!< Type of Rx Event */
void (*RxISR)(struct __UART_HandleTypeDef *huart); /*!< Function pointer on Rx IRQ handler */
void (*TxISR)(struct __UART_HandleTypeDef *huart); /*!< Function pointer on Tx IRQ handler */
DMA_HandleTypeDef *hdmatx; /*!< UART Tx DMA Handle parameters */
DMA_HandleTypeDef *hdmarx; /*!< UART Rx DMA Handle parameters */
HAL_LockTypeDef Lock; /*!< Locking object */
__IO HAL_UART_StateTypeDef gState; /*!< UART state information related to global Handle management
and also related to Tx operations. This parameter
can be a value of @ref HAL_UART_StateTypeDef */
__IO HAL_UART_StateTypeDef RxState; /*!< UART state information related to Rx operations. This
parameter can be a value of @ref HAL_UART_StateTypeDef */
__IO uint32_t ErrorCode; /*!< UART Error code */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
void (* TxHalfCpltCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Tx Half Complete Callback */
void (* TxCpltCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Tx Complete Callback */
void (* RxHalfCpltCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Rx Half Complete Callback */
void (* RxCpltCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Rx Complete Callback */
void (* ErrorCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Error Callback */
void (* AbortCpltCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Abort Complete Callback */
void (* AbortTransmitCpltCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Abort Transmit Complete Callback */
void (* AbortReceiveCpltCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Abort Receive Complete Callback */
void (* WakeupCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Wakeup Callback */
void (* RxFifoFullCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Rx Fifo Full Callback */
void (* TxFifoEmptyCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Tx Fifo Empty Callback */
void (* RxEventCallback)(struct __UART_HandleTypeDef *huart, uint16_t Pos); /*!< UART Reception Event Callback */
void (* MspInitCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Msp Init callback */
void (* MspDeInitCallback)(struct __UART_HandleTypeDef *huart); /*!< UART Msp DeInit callback */
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
} UART_HandleTypeDef;
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
/**
* @brief HAL UART Callback ID enumeration definition
*/
typedef enum
{
HAL_UART_TX_HALFCOMPLETE_CB_ID = 0x00U, /*!< UART Tx Half Complete Callback ID */
HAL_UART_TX_COMPLETE_CB_ID = 0x01U, /*!< UART Tx Complete Callback ID */
HAL_UART_RX_HALFCOMPLETE_CB_ID = 0x02U, /*!< UART Rx Half Complete Callback ID */
HAL_UART_RX_COMPLETE_CB_ID = 0x03U, /*!< UART Rx Complete Callback ID */
HAL_UART_ERROR_CB_ID = 0x04U, /*!< UART Error Callback ID */
HAL_UART_ABORT_COMPLETE_CB_ID = 0x05U, /*!< UART Abort Complete Callback ID */
HAL_UART_ABORT_TRANSMIT_COMPLETE_CB_ID = 0x06U, /*!< UART Abort Transmit Complete Callback ID */
HAL_UART_ABORT_RECEIVE_COMPLETE_CB_ID = 0x07U, /*!< UART Abort Receive Complete Callback ID */
HAL_UART_WAKEUP_CB_ID = 0x08U, /*!< UART Wakeup Callback ID */
HAL_UART_RX_FIFO_FULL_CB_ID = 0x09U, /*!< UART Rx Fifo Full Callback ID */
HAL_UART_TX_FIFO_EMPTY_CB_ID = 0x0AU, /*!< UART Tx Fifo Empty Callback ID */
HAL_UART_MSPINIT_CB_ID = 0x0BU, /*!< UART MspInit callback ID */
HAL_UART_MSPDEINIT_CB_ID = 0x0CU /*!< UART MspDeInit callback ID */
} HAL_UART_CallbackIDTypeDef;
/**
* @brief HAL UART Callback pointer definition
*/
typedef void (*pUART_CallbackTypeDef)(UART_HandleTypeDef *huart); /*!< pointer to an UART callback function */
typedef void (*pUART_RxEventCallbackTypeDef)
(struct __UART_HandleTypeDef *huart, uint16_t Pos); /*!< pointer to a UART Rx Event specific callback function */
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup UART_Exported_Constants UART Exported Constants
* @{
*/
/** @defgroup UART_State_Definition UART State Code Definition
* @{
*/
#define HAL_UART_STATE_RESET 0x00000000U /*!< Peripheral is not initialized
Value is allowed for gState and RxState */
#define HAL_UART_STATE_READY 0x00000020U /*!< Peripheral Initialized and ready for use
Value is allowed for gState and RxState */
#define HAL_UART_STATE_BUSY 0x00000024U /*!< an internal process is ongoing
Value is allowed for gState only */
#define HAL_UART_STATE_BUSY_TX 0x00000021U /*!< Data Transmission process is ongoing
Value is allowed for gState only */
#define HAL_UART_STATE_BUSY_RX 0x00000022U /*!< Data Reception process is ongoing
Value is allowed for RxState only */
#define HAL_UART_STATE_BUSY_TX_RX 0x00000023U /*!< Data Transmission and Reception process is ongoing
Not to be used for neither gState nor RxState.Value is result
of combination (Or) between gState and RxState values */
#define HAL_UART_STATE_TIMEOUT 0x000000A0U /*!< Timeout state
Value is allowed for gState only */
#define HAL_UART_STATE_ERROR 0x000000E0U /*!< Error
Value is allowed for gState only */
/**
* @}
*/
/** @defgroup UART_Error_Definition UART Error Definition
* @{
*/
#define HAL_UART_ERROR_NONE (0x00000000U) /*!< No error */
#define HAL_UART_ERROR_PE (0x00000001U) /*!< Parity error */
#define HAL_UART_ERROR_NE (0x00000002U) /*!< Noise error */
#define HAL_UART_ERROR_FE (0x00000004U) /*!< Frame error */
#define HAL_UART_ERROR_ORE (0x00000008U) /*!< Overrun error */
#define HAL_UART_ERROR_DMA (0x00000010U) /*!< DMA transfer error */
#define HAL_UART_ERROR_RTO (0x00000020U) /*!< Receiver Timeout error */
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
#define HAL_UART_ERROR_INVALID_CALLBACK (0x00000040U) /*!< Invalid Callback error */
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
/**
* @}
*/
/** @defgroup UART_Stop_Bits UART Number of Stop Bits
* @{
*/
#define UART_STOPBITS_0_5 USART_CR2_STOP_0 /*!< UART frame with 0.5 stop bit */
#define UART_STOPBITS_1 0x00000000U /*!< UART frame with 1 stop bit */
#define UART_STOPBITS_1_5 (USART_CR2_STOP_0 | USART_CR2_STOP_1) /*!< UART frame with 1.5 stop bits */
#define UART_STOPBITS_2 USART_CR2_STOP_1 /*!< UART frame with 2 stop bits */
/**
* @}
*/
/** @defgroup UART_Parity UART Parity
* @{
*/
#define UART_PARITY_NONE 0x00000000U /*!< No parity */
#define UART_PARITY_EVEN USART_CR1_PCE /*!< Even parity */
#define UART_PARITY_ODD (USART_CR1_PCE | USART_CR1_PS) /*!< Odd parity */
/**
* @}
*/
/** @defgroup UART_Hardware_Flow_Control UART Hardware Flow Control
* @{
*/
#define UART_HWCONTROL_NONE 0x00000000U /*!< No hardware control */
#define UART_HWCONTROL_RTS USART_CR3_RTSE /*!< Request To Send */
#define UART_HWCONTROL_CTS USART_CR3_CTSE /*!< Clear To Send */
#define UART_HWCONTROL_RTS_CTS (USART_CR3_RTSE | USART_CR3_CTSE) /*!< Request and Clear To Send */
/**
* @}
*/
/** @defgroup UART_Mode UART Transfer Mode
* @{
*/
#define UART_MODE_RX USART_CR1_RE /*!< RX mode */
#define UART_MODE_TX USART_CR1_TE /*!< TX mode */
#define UART_MODE_TX_RX (USART_CR1_TE |USART_CR1_RE) /*!< RX and TX mode */
/**
* @}
*/
/** @defgroup UART_State UART State
* @{
*/
#define UART_STATE_DISABLE 0x00000000U /*!< UART disabled */
#define UART_STATE_ENABLE USART_CR1_UE /*!< UART enabled */
/**
* @}
*/
/** @defgroup UART_Over_Sampling UART Over Sampling
* @{
*/
#define UART_OVERSAMPLING_16 0x00000000U /*!< Oversampling by 16 */
#define UART_OVERSAMPLING_8 USART_CR1_OVER8 /*!< Oversampling by 8 */
/**
* @}
*/
/** @defgroup UART_OneBit_Sampling UART One Bit Sampling Method
* @{
*/
#define UART_ONE_BIT_SAMPLE_DISABLE 0x00000000U /*!< One-bit sampling disable */
#define UART_ONE_BIT_SAMPLE_ENABLE USART_CR3_ONEBIT /*!< One-bit sampling enable */
/**
* @}
*/
/** @defgroup UART_ClockPrescaler UART Clock Prescaler
* @{
*/
#define UART_PRESCALER_DIV1 0x00000000U /*!< fclk_pres = fclk */
#define UART_PRESCALER_DIV2 0x00000001U /*!< fclk_pres = fclk/2 */
#define UART_PRESCALER_DIV4 0x00000002U /*!< fclk_pres = fclk/4 */
#define UART_PRESCALER_DIV6 0x00000003U /*!< fclk_pres = fclk/6 */
#define UART_PRESCALER_DIV8 0x00000004U /*!< fclk_pres = fclk/8 */
#define UART_PRESCALER_DIV10 0x00000005U /*!< fclk_pres = fclk/10 */
#define UART_PRESCALER_DIV12 0x00000006U /*!< fclk_pres = fclk/12 */
#define UART_PRESCALER_DIV16 0x00000007U /*!< fclk_pres = fclk/16 */
#define UART_PRESCALER_DIV32 0x00000008U /*!< fclk_pres = fclk/32 */
#define UART_PRESCALER_DIV64 0x00000009U /*!< fclk_pres = fclk/64 */
#define UART_PRESCALER_DIV128 0x0000000AU /*!< fclk_pres = fclk/128 */
#define UART_PRESCALER_DIV256 0x0000000BU /*!< fclk_pres = fclk/256 */
/**
* @}
*/
/** @defgroup UART_AutoBaud_Rate_Mode UART Advanced Feature AutoBaud Rate Mode
* @{
*/
#define UART_ADVFEATURE_AUTOBAUDRATE_ONSTARTBIT 0x00000000U /*!< Auto Baud rate detection
on start bit */
#define UART_ADVFEATURE_AUTOBAUDRATE_ONFALLINGEDGE USART_CR2_ABRMODE_0 /*!< Auto Baud rate detection
on falling edge */
#define UART_ADVFEATURE_AUTOBAUDRATE_ON0X7FFRAME USART_CR2_ABRMODE_1 /*!< Auto Baud rate detection
on 0x7F frame detection */
#define UART_ADVFEATURE_AUTOBAUDRATE_ON0X55FRAME USART_CR2_ABRMODE /*!< Auto Baud rate detection
on 0x55 frame detection */
/**
* @}
*/
/** @defgroup UART_Receiver_Timeout UART Receiver Timeout
* @{
*/
#define UART_RECEIVER_TIMEOUT_DISABLE 0x00000000U /*!< UART Receiver Timeout disable */
#define UART_RECEIVER_TIMEOUT_ENABLE USART_CR2_RTOEN /*!< UART Receiver Timeout enable */
/**
* @}
*/
/** @defgroup UART_LIN UART Local Interconnection Network mode
* @{
*/
#define UART_LIN_DISABLE 0x00000000U /*!< Local Interconnect Network disable */
#define UART_LIN_ENABLE USART_CR2_LINEN /*!< Local Interconnect Network enable */
/**
* @}
*/
/** @defgroup UART_LIN_Break_Detection UART LIN Break Detection
* @{
*/
#define UART_LINBREAKDETECTLENGTH_10B 0x00000000U /*!< LIN 10-bit break detection length */
#define UART_LINBREAKDETECTLENGTH_11B USART_CR2_LBDL /*!< LIN 11-bit break detection length */
/**
* @}
*/
/** @defgroup UART_DMA_Tx UART DMA Tx
* @{
*/
#define UART_DMA_TX_DISABLE 0x00000000U /*!< UART DMA TX disabled */
#define UART_DMA_TX_ENABLE USART_CR3_DMAT /*!< UART DMA TX enabled */
/**
* @}
*/
/** @defgroup UART_DMA_Rx UART DMA Rx
* @{
*/
#define UART_DMA_RX_DISABLE 0x00000000U /*!< UART DMA RX disabled */
#define UART_DMA_RX_ENABLE USART_CR3_DMAR /*!< UART DMA RX enabled */
/**
* @}
*/
/** @defgroup UART_Half_Duplex_Selection UART Half Duplex Selection
* @{
*/
#define UART_HALF_DUPLEX_DISABLE 0x00000000U /*!< UART half-duplex disabled */
#define UART_HALF_DUPLEX_ENABLE USART_CR3_HDSEL /*!< UART half-duplex enabled */
/**
* @}
*/
/** @defgroup UART_WakeUp_Methods UART WakeUp Methods
* @{
*/
#define UART_WAKEUPMETHOD_IDLELINE 0x00000000U /*!< UART wake-up on idle line */
#define UART_WAKEUPMETHOD_ADDRESSMARK USART_CR1_WAKE /*!< UART wake-up on address mark */
/**
* @}
*/
/** @defgroup UART_Request_Parameters UART Request Parameters
* @{
*/
#define UART_AUTOBAUD_REQUEST USART_RQR_ABRRQ /*!< Auto-Baud Rate Request */
#define UART_SENDBREAK_REQUEST USART_RQR_SBKRQ /*!< Send Break Request */
#define UART_MUTE_MODE_REQUEST USART_RQR_MMRQ /*!< Mute Mode Request */
#define UART_RXDATA_FLUSH_REQUEST USART_RQR_RXFRQ /*!< Receive Data flush Request */
#define UART_TXDATA_FLUSH_REQUEST USART_RQR_TXFRQ /*!< Transmit data flush Request */
/**
* @}
*/
/** @defgroup UART_Advanced_Features_Initialization_Type UART Advanced Feature Initialization Type
* @{
*/
#define UART_ADVFEATURE_NO_INIT 0x00000000U /*!< No advanced feature initialization */
#define UART_ADVFEATURE_TXINVERT_INIT 0x00000001U /*!< TX pin active level inversion */
#define UART_ADVFEATURE_RXINVERT_INIT 0x00000002U /*!< RX pin active level inversion */
#define UART_ADVFEATURE_DATAINVERT_INIT 0x00000004U /*!< Binary data inversion */
#define UART_ADVFEATURE_SWAP_INIT 0x00000008U /*!< TX/RX pins swap */
#define UART_ADVFEATURE_RXOVERRUNDISABLE_INIT 0x00000010U /*!< RX overrun disable */
#define UART_ADVFEATURE_DMADISABLEONERROR_INIT 0x00000020U /*!< DMA disable on Reception Error */
#define UART_ADVFEATURE_AUTOBAUDRATE_INIT 0x00000040U /*!< Auto Baud rate detection initialization */
#define UART_ADVFEATURE_MSBFIRST_INIT 0x00000080U /*!< Most significant bit sent/received first */
/**
* @}
*/
/** @defgroup UART_Tx_Inv UART Advanced Feature TX Pin Active Level Inversion
* @{
*/
#define UART_ADVFEATURE_TXINV_DISABLE 0x00000000U /*!< TX pin active level inversion disable */
#define UART_ADVFEATURE_TXINV_ENABLE USART_CR2_TXINV /*!< TX pin active level inversion enable */
/**
* @}
*/
/** @defgroup UART_Rx_Inv UART Advanced Feature RX Pin Active Level Inversion
* @{
*/
#define UART_ADVFEATURE_RXINV_DISABLE 0x00000000U /*!< RX pin active level inversion disable */
#define UART_ADVFEATURE_RXINV_ENABLE USART_CR2_RXINV /*!< RX pin active level inversion enable */
/**
* @}
*/
/** @defgroup UART_Data_Inv UART Advanced Feature Binary Data Inversion
* @{
*/
#define UART_ADVFEATURE_DATAINV_DISABLE 0x00000000U /*!< Binary data inversion disable */
#define UART_ADVFEATURE_DATAINV_ENABLE USART_CR2_DATAINV /*!< Binary data inversion enable */
/**
* @}
*/
/** @defgroup UART_Rx_Tx_Swap UART Advanced Feature RX TX Pins Swap
* @{
*/
#define UART_ADVFEATURE_SWAP_DISABLE 0x00000000U /*!< TX/RX pins swap disable */
#define UART_ADVFEATURE_SWAP_ENABLE USART_CR2_SWAP /*!< TX/RX pins swap enable */
/**
* @}
*/
/** @defgroup UART_Overrun_Disable UART Advanced Feature Overrun Disable
* @{
*/
#define UART_ADVFEATURE_OVERRUN_ENABLE 0x00000000U /*!< RX overrun enable */
#define UART_ADVFEATURE_OVERRUN_DISABLE USART_CR3_OVRDIS /*!< RX overrun disable */
/**
* @}
*/
/** @defgroup UART_AutoBaudRate_Enable UART Advanced Feature Auto BaudRate Enable
* @{
*/
#define UART_ADVFEATURE_AUTOBAUDRATE_DISABLE 0x00000000U /*!< RX Auto Baud rate detection enable */
#define UART_ADVFEATURE_AUTOBAUDRATE_ENABLE USART_CR2_ABREN /*!< RX Auto Baud rate detection disable */
/**
* @}
*/
/** @defgroup UART_DMA_Disable_on_Rx_Error UART Advanced Feature DMA Disable On Rx Error
* @{
*/
#define UART_ADVFEATURE_DMA_ENABLEONRXERROR 0x00000000U /*!< DMA enable on Reception Error */
#define UART_ADVFEATURE_DMA_DISABLEONRXERROR USART_CR3_DDRE /*!< DMA disable on Reception Error */
/**
* @}
*/
/** @defgroup UART_MSB_First UART Advanced Feature MSB First
* @{
*/
#define UART_ADVFEATURE_MSBFIRST_DISABLE 0x00000000U /*!< Most significant bit sent/received
first disable */
#define UART_ADVFEATURE_MSBFIRST_ENABLE USART_CR2_MSBFIRST /*!< Most significant bit sent/received
first enable */
/**
* @}
*/
/** @defgroup UART_Stop_Mode_Enable UART Advanced Feature Stop Mode Enable
* @{
*/
#define UART_ADVFEATURE_STOPMODE_DISABLE 0x00000000U /*!< UART stop mode disable */
#define UART_ADVFEATURE_STOPMODE_ENABLE USART_CR1_UESM /*!< UART stop mode enable */
/**
* @}
*/
/** @defgroup UART_Mute_Mode UART Advanced Feature Mute Mode Enable
* @{
*/
#define UART_ADVFEATURE_MUTEMODE_DISABLE 0x00000000U /*!< UART mute mode disable */
#define UART_ADVFEATURE_MUTEMODE_ENABLE USART_CR1_MME /*!< UART mute mode enable */
/**
* @}
*/
/** @defgroup UART_CR2_ADDRESS_LSB_POS UART Address-matching LSB Position In CR2 Register
* @{
*/
#define UART_CR2_ADDRESS_LSB_POS 24U /*!< UART address-matching LSB position in CR2 register */
/**
* @}
*/
/** @defgroup UART_WakeUp_from_Stop_Selection UART WakeUp From Stop Selection
* @{
*/
#define UART_WAKEUP_ON_ADDRESS 0x00000000U /*!< UART wake-up on address */
#define UART_WAKEUP_ON_STARTBIT USART_CR3_WUS_1 /*!< UART wake-up on start bit */
#define UART_WAKEUP_ON_READDATA_NONEMPTY USART_CR3_WUS /*!< UART wake-up on receive data register
not empty or RXFIFO is not empty */
/**
* @}
*/
/** @defgroup UART_DriverEnable_Polarity UART DriverEnable Polarity
* @{
*/
#define UART_DE_POLARITY_HIGH 0x00000000U /*!< Driver enable signal is active high */
#define UART_DE_POLARITY_LOW USART_CR3_DEP /*!< Driver enable signal is active low */
/**
* @}
*/
/** @defgroup UART_CR1_DEAT_ADDRESS_LSB_POS UART Driver Enable Assertion Time LSB Position In CR1 Register
* @{
*/
#define UART_CR1_DEAT_ADDRESS_LSB_POS 21U /*!< UART Driver Enable assertion time LSB
position in CR1 register */
/**
* @}
*/
/** @defgroup UART_CR1_DEDT_ADDRESS_LSB_POS UART Driver Enable DeAssertion Time LSB Position In CR1 Register
* @{
*/
#define UART_CR1_DEDT_ADDRESS_LSB_POS 16U /*!< UART Driver Enable de-assertion time LSB
position in CR1 register */
/**
* @}
*/
/** @defgroup UART_Interruption_Mask UART Interruptions Flag Mask
* @{
*/
#define UART_IT_MASK 0x001FU /*!< UART interruptions flags mask */
/**
* @}
*/
/** @defgroup UART_TimeOut_Value UART polling-based communications time-out value
* @{
*/
#define HAL_UART_TIMEOUT_VALUE 0x1FFFFFFU /*!< UART polling-based communications time-out value */
/**
* @}
*/
/** @defgroup UART_Flags UART Status Flags
* Elements values convention: 0xXXXX
* - 0xXXXX : Flag mask in the ISR register
* @{
*/
#define UART_FLAG_TXFT USART_ISR_TXFT /*!< UART TXFIFO threshold flag */
#define UART_FLAG_RXFT USART_ISR_RXFT /*!< UART RXFIFO threshold flag */
#define UART_FLAG_RXFF USART_ISR_RXFF /*!< UART RXFIFO Full flag */
#define UART_FLAG_TXFE USART_ISR_TXFE /*!< UART TXFIFO Empty flag */
#define UART_FLAG_REACK USART_ISR_REACK /*!< UART receive enable acknowledge flag */
#define UART_FLAG_TEACK USART_ISR_TEACK /*!< UART transmit enable acknowledge flag */
#define UART_FLAG_WUF USART_ISR_WUF /*!< UART wake-up from stop mode flag */
#define UART_FLAG_RWU USART_ISR_RWU /*!< UART receiver wake-up from mute mode flag */
#define UART_FLAG_SBKF USART_ISR_SBKF /*!< UART send break flag */
#define UART_FLAG_CMF USART_ISR_CMF /*!< UART character match flag */
#define UART_FLAG_BUSY USART_ISR_BUSY /*!< UART busy flag */
#define UART_FLAG_ABRF USART_ISR_ABRF /*!< UART auto Baud rate flag */
#define UART_FLAG_ABRE USART_ISR_ABRE /*!< UART auto Baud rate error */
#define UART_FLAG_RTOF USART_ISR_RTOF /*!< UART receiver timeout flag */
#define UART_FLAG_CTS USART_ISR_CTS /*!< UART clear to send flag */
#define UART_FLAG_CTSIF USART_ISR_CTSIF /*!< UART clear to send interrupt flag */
#define UART_FLAG_LBDF USART_ISR_LBDF /*!< UART LIN break detection flag */
#define UART_FLAG_TXE USART_ISR_TXE_TXFNF /*!< UART transmit data register empty */
#define UART_FLAG_TXFNF USART_ISR_TXE_TXFNF /*!< UART TXFIFO not full */
#define UART_FLAG_TC USART_ISR_TC /*!< UART transmission complete */
#define UART_FLAG_RXNE USART_ISR_RXNE_RXFNE /*!< UART read data register not empty */
#define UART_FLAG_RXFNE USART_ISR_RXNE_RXFNE /*!< UART RXFIFO not empty */
#define UART_FLAG_IDLE USART_ISR_IDLE /*!< UART idle flag */
#define UART_FLAG_ORE USART_ISR_ORE /*!< UART overrun error */
#define UART_FLAG_NE USART_ISR_NE /*!< UART noise error */
#define UART_FLAG_FE USART_ISR_FE /*!< UART frame error */
#define UART_FLAG_PE USART_ISR_PE /*!< UART parity error */
/**
* @}
*/
/** @defgroup UART_Interrupt_definition UART Interrupts Definition
* Elements values convention: 000ZZZZZ0XXYYYYYb
* - YYYYY : Interrupt source position in the XX register (5bits)
* - XX : Interrupt source register (2bits)
* - 01: CR1 register
* - 10: CR2 register
* - 11: CR3 register
* - ZZZZZ : Flag position in the ISR register(5bits)
* Elements values convention: 000000000XXYYYYYb
* - YYYYY : Interrupt source position in the XX register (5bits)
* - XX : Interrupt source register (2bits)
* - 01: CR1 register
* - 10: CR2 register
* - 11: CR3 register
* Elements values convention: 0000ZZZZ00000000b
* - ZZZZ : Flag position in the ISR register(4bits)
* @{
*/
#define UART_IT_PE 0x0028U /*!< UART parity error interruption */
#define UART_IT_TXE 0x0727U /*!< UART transmit data register empty interruption */
#define UART_IT_TXFNF 0x0727U /*!< UART TX FIFO not full interruption */
#define UART_IT_TC 0x0626U /*!< UART transmission complete interruption */
#define UART_IT_RXNE 0x0525U /*!< UART read data register not empty interruption */
#define UART_IT_RXFNE 0x0525U /*!< UART RXFIFO not empty interruption */
#define UART_IT_IDLE 0x0424U /*!< UART idle interruption */
#define UART_IT_LBD 0x0846U /*!< UART LIN break detection interruption */
#define UART_IT_CTS 0x096AU /*!< UART CTS interruption */
#define UART_IT_CM 0x112EU /*!< UART character match interruption */
#define UART_IT_WUF 0x1476U /*!< UART wake-up from stop mode interruption */
#define UART_IT_RXFF 0x183FU /*!< UART RXFIFO full interruption */
#define UART_IT_TXFE 0x173EU /*!< UART TXFIFO empty interruption */
#define UART_IT_RXFT 0x1A7CU /*!< UART RXFIFO threshold reached interruption */
#define UART_IT_TXFT 0x1B77U /*!< UART TXFIFO threshold reached interruption */
#define UART_IT_RTO 0x0B3AU /*!< UART receiver timeout interruption */
#define UART_IT_ERR 0x0060U /*!< UART error interruption */
#define UART_IT_ORE 0x0300U /*!< UART overrun error interruption */
#define UART_IT_NE 0x0200U /*!< UART noise error interruption */
#define UART_IT_FE 0x0100U /*!< UART frame error interruption */
/**
* @}
*/
/** @defgroup UART_IT_CLEAR_Flags UART Interruption Clear Flags
* @{
*/
#define UART_CLEAR_PEF USART_ICR_PECF /*!< Parity Error Clear Flag */
#define UART_CLEAR_FEF USART_ICR_FECF /*!< Framing Error Clear Flag */
#define UART_CLEAR_NEF USART_ICR_NECF /*!< Noise Error detected Clear Flag */
#define UART_CLEAR_OREF USART_ICR_ORECF /*!< Overrun Error Clear Flag */
#define UART_CLEAR_IDLEF USART_ICR_IDLECF /*!< IDLE line detected Clear Flag */
#define UART_CLEAR_TXFECF USART_ICR_TXFECF /*!< TXFIFO empty clear flag */
#define UART_CLEAR_TCF USART_ICR_TCCF /*!< Transmission Complete Clear Flag */
#define UART_CLEAR_LBDF USART_ICR_LBDCF /*!< LIN Break Detection Clear Flag */
#define UART_CLEAR_CTSF USART_ICR_CTSCF /*!< CTS Interrupt Clear Flag */
#define UART_CLEAR_CMF USART_ICR_CMCF /*!< Character Match Clear Flag */
#define UART_CLEAR_WUF USART_ICR_WUCF /*!< Wake Up from stop mode Clear Flag */
#define UART_CLEAR_RTOF USART_ICR_RTOCF /*!< UART receiver timeout clear flag */
/**
* @}
*/
/** @defgroup UART_Reception_Type_Values UART Reception type values
* @{
*/
#define HAL_UART_RECEPTION_STANDARD (0x00000000U) /*!< Standard reception */
#define HAL_UART_RECEPTION_TOIDLE (0x00000001U) /*!< Reception till completion or IDLE event */
#define HAL_UART_RECEPTION_TORTO (0x00000002U) /*!< Reception till completion or RTO event */
#define HAL_UART_RECEPTION_TOCHARMATCH (0x00000003U) /*!< Reception till completion or CM event */
/**
* @}
*/
/** @defgroup UART_RxEvent_Type_Values UART RxEvent type values
* @{
*/
#define HAL_UART_RXEVENT_TC (0x00000000U) /*!< RxEvent linked to Transfer Complete event */
#define HAL_UART_RXEVENT_HT (0x00000001U) /*!< RxEvent linked to Half Transfer event */
#define HAL_UART_RXEVENT_IDLE (0x00000002U) /*!< RxEvent linked to IDLE event */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup UART_Exported_Macros UART Exported Macros
* @{
*/
/** @brief Reset UART handle states.
* @param __HANDLE__ UART handle.
* @retval None
*/
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
#define __HAL_UART_RESET_HANDLE_STATE(__HANDLE__) do{ \
(__HANDLE__)->gState = HAL_UART_STATE_RESET; \
(__HANDLE__)->RxState = HAL_UART_STATE_RESET; \
(__HANDLE__)->MspInitCallback = NULL; \
(__HANDLE__)->MspDeInitCallback = NULL; \
} while(0U)
#else
#define __HAL_UART_RESET_HANDLE_STATE(__HANDLE__) do{ \
(__HANDLE__)->gState = HAL_UART_STATE_RESET; \
(__HANDLE__)->RxState = HAL_UART_STATE_RESET; \
} while(0U)
#endif /*USE_HAL_UART_REGISTER_CALLBACKS */
/** @brief Flush the UART Data registers.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_FLUSH_DRREGISTER(__HANDLE__) \
do{ \
SET_BIT((__HANDLE__)->Instance->RQR, UART_RXDATA_FLUSH_REQUEST); \
SET_BIT((__HANDLE__)->Instance->RQR, UART_TXDATA_FLUSH_REQUEST); \
} while(0U)
/** @brief Clear the specified UART pending flag.
* @param __HANDLE__ specifies the UART Handle.
* @param __FLAG__ specifies the flag to check.
* This parameter can be any combination of the following values:
* @arg @ref UART_CLEAR_PEF Parity Error Clear Flag
* @arg @ref UART_CLEAR_FEF Framing Error Clear Flag
* @arg @ref UART_CLEAR_NEF Noise detected Clear Flag
* @arg @ref UART_CLEAR_OREF Overrun Error Clear Flag
* @arg @ref UART_CLEAR_IDLEF IDLE line detected Clear Flag
* @arg @ref UART_CLEAR_TXFECF TXFIFO empty clear Flag
* @arg @ref UART_CLEAR_TCF Transmission Complete Clear Flag
* @arg @ref UART_CLEAR_RTOF Receiver Timeout clear flag
* @arg @ref UART_CLEAR_LBDF LIN Break Detection Clear Flag
* @arg @ref UART_CLEAR_CTSF CTS Interrupt Clear Flag
* @arg @ref UART_CLEAR_CMF Character Match Clear Flag
* @arg @ref UART_CLEAR_WUF Wake Up from stop mode Clear Flag
* @retval None
*/
#define __HAL_UART_CLEAR_FLAG(__HANDLE__, __FLAG__) ((__HANDLE__)->Instance->ICR = (__FLAG__))
/** @brief Clear the UART PE pending flag.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_CLEAR_PEFLAG(__HANDLE__) __HAL_UART_CLEAR_FLAG((__HANDLE__), UART_CLEAR_PEF)
/** @brief Clear the UART FE pending flag.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_CLEAR_FEFLAG(__HANDLE__) __HAL_UART_CLEAR_FLAG((__HANDLE__), UART_CLEAR_FEF)
/** @brief Clear the UART NE pending flag.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_CLEAR_NEFLAG(__HANDLE__) __HAL_UART_CLEAR_FLAG((__HANDLE__), UART_CLEAR_NEF)
/** @brief Clear the UART ORE pending flag.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_CLEAR_OREFLAG(__HANDLE__) __HAL_UART_CLEAR_FLAG((__HANDLE__), UART_CLEAR_OREF)
/** @brief Clear the UART IDLE pending flag.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_CLEAR_IDLEFLAG(__HANDLE__) __HAL_UART_CLEAR_FLAG((__HANDLE__), UART_CLEAR_IDLEF)
/** @brief Clear the UART TX FIFO empty clear flag.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_CLEAR_TXFECF(__HANDLE__) __HAL_UART_CLEAR_FLAG((__HANDLE__), UART_CLEAR_TXFECF)
/** @brief Check whether the specified UART flag is set or not.
* @param __HANDLE__ specifies the UART Handle.
* @param __FLAG__ specifies the flag to check.
* This parameter can be one of the following values:
* @arg @ref UART_FLAG_TXFT TXFIFO threshold flag
* @arg @ref UART_FLAG_RXFT RXFIFO threshold flag
* @arg @ref UART_FLAG_RXFF RXFIFO Full flag
* @arg @ref UART_FLAG_TXFE TXFIFO Empty flag
* @arg @ref UART_FLAG_REACK Receive enable acknowledge flag
* @arg @ref UART_FLAG_TEACK Transmit enable acknowledge flag
* @arg @ref UART_FLAG_WUF Wake up from stop mode flag
* @arg @ref UART_FLAG_RWU Receiver wake up flag (if the UART in mute mode)
* @arg @ref UART_FLAG_SBKF Send Break flag
* @arg @ref UART_FLAG_CMF Character match flag
* @arg @ref UART_FLAG_BUSY Busy flag
* @arg @ref UART_FLAG_ABRF Auto Baud rate detection flag
* @arg @ref UART_FLAG_ABRE Auto Baud rate detection error flag
* @arg @ref UART_FLAG_CTS CTS Change flag
* @arg @ref UART_FLAG_LBDF LIN Break detection flag
* @arg @ref UART_FLAG_TXE Transmit data register empty flag
* @arg @ref UART_FLAG_TXFNF UART TXFIFO not full flag
* @arg @ref UART_FLAG_TC Transmission Complete flag
* @arg @ref UART_FLAG_RXNE Receive data register not empty flag
* @arg @ref UART_FLAG_RXFNE UART RXFIFO not empty flag
* @arg @ref UART_FLAG_RTOF Receiver Timeout flag
* @arg @ref UART_FLAG_IDLE Idle Line detection flag
* @arg @ref UART_FLAG_ORE Overrun Error flag
* @arg @ref UART_FLAG_NE Noise Error flag
* @arg @ref UART_FLAG_FE Framing Error flag
* @arg @ref UART_FLAG_PE Parity Error flag
* @retval The new state of __FLAG__ (TRUE or FALSE).
*/
#define __HAL_UART_GET_FLAG(__HANDLE__, __FLAG__) (((__HANDLE__)->Instance->ISR & (__FLAG__)) == (__FLAG__))
/** @brief Enable the specified UART interrupt.
* @param __HANDLE__ specifies the UART Handle.
* @param __INTERRUPT__ specifies the UART interrupt source to enable.
* This parameter can be one of the following values:
* @arg @ref UART_IT_RXFF RXFIFO Full interrupt
* @arg @ref UART_IT_TXFE TXFIFO Empty interrupt
* @arg @ref UART_IT_RXFT RXFIFO threshold interrupt
* @arg @ref UART_IT_TXFT TXFIFO threshold interrupt
* @arg @ref UART_IT_WUF Wakeup from stop mode interrupt
* @arg @ref UART_IT_CM Character match interrupt
* @arg @ref UART_IT_CTS CTS change interrupt
* @arg @ref UART_IT_LBD LIN Break detection interrupt
* @arg @ref UART_IT_TXE Transmit Data Register empty interrupt
* @arg @ref UART_IT_TXFNF TX FIFO not full interrupt
* @arg @ref UART_IT_TC Transmission complete interrupt
* @arg @ref UART_IT_RXNE Receive Data register not empty interrupt
* @arg @ref UART_IT_RXFNE RXFIFO not empty interrupt
* @arg @ref UART_IT_RTO Receive Timeout interrupt
* @arg @ref UART_IT_IDLE Idle line detection interrupt
* @arg @ref UART_IT_PE Parity Error interrupt
* @arg @ref UART_IT_ERR Error interrupt (frame error, noise error, overrun error)
* @retval None
*/
#define __HAL_UART_ENABLE_IT(__HANDLE__, __INTERRUPT__) (\
((((uint8_t)(__INTERRUPT__)) >> 5U) == 1U)?\
((__HANDLE__)->Instance->CR1 |= (1U <<\
((__INTERRUPT__) & UART_IT_MASK))): \
((((uint8_t)(__INTERRUPT__)) >> 5U) == 2U)?\
((__HANDLE__)->Instance->CR2 |= (1U <<\
((__INTERRUPT__) & UART_IT_MASK))): \
((__HANDLE__)->Instance->CR3 |= (1U <<\
((__INTERRUPT__) & UART_IT_MASK))))
/** @brief Disable the specified UART interrupt.
* @param __HANDLE__ specifies the UART Handle.
* @param __INTERRUPT__ specifies the UART interrupt source to disable.
* This parameter can be one of the following values:
* @arg @ref UART_IT_RXFF RXFIFO Full interrupt
* @arg @ref UART_IT_TXFE TXFIFO Empty interrupt
* @arg @ref UART_IT_RXFT RXFIFO threshold interrupt
* @arg @ref UART_IT_TXFT TXFIFO threshold interrupt
* @arg @ref UART_IT_WUF Wakeup from stop mode interrupt
* @arg @ref UART_IT_CM Character match interrupt
* @arg @ref UART_IT_CTS CTS change interrupt
* @arg @ref UART_IT_LBD LIN Break detection interrupt
* @arg @ref UART_IT_TXE Transmit Data Register empty interrupt
* @arg @ref UART_IT_TXFNF TX FIFO not full interrupt
* @arg @ref UART_IT_TC Transmission complete interrupt
* @arg @ref UART_IT_RXNE Receive Data register not empty interrupt
* @arg @ref UART_IT_RXFNE RXFIFO not empty interrupt
* @arg @ref UART_IT_RTO Receive Timeout interrupt
* @arg @ref UART_IT_IDLE Idle line detection interrupt
* @arg @ref UART_IT_PE Parity Error interrupt
* @arg @ref UART_IT_ERR Error interrupt (Frame error, noise error, overrun error)
* @retval None
*/
#define __HAL_UART_DISABLE_IT(__HANDLE__, __INTERRUPT__) (\
((((uint8_t)(__INTERRUPT__)) >> 5U) == 1U)?\
((__HANDLE__)->Instance->CR1 &= ~ (1U <<\
((__INTERRUPT__) & UART_IT_MASK))): \
((((uint8_t)(__INTERRUPT__)) >> 5U) == 2U)?\
((__HANDLE__)->Instance->CR2 &= ~ (1U <<\
((__INTERRUPT__) & UART_IT_MASK))): \
((__HANDLE__)->Instance->CR3 &= ~ (1U <<\
((__INTERRUPT__) & UART_IT_MASK))))
/** @brief Check whether the specified UART interrupt has occurred or not.
* @param __HANDLE__ specifies the UART Handle.
* @param __INTERRUPT__ specifies the UART interrupt to check.
* This parameter can be one of the following values:
* @arg @ref UART_IT_RXFF RXFIFO Full interrupt
* @arg @ref UART_IT_TXFE TXFIFO Empty interrupt
* @arg @ref UART_IT_RXFT RXFIFO threshold interrupt
* @arg @ref UART_IT_TXFT TXFIFO threshold interrupt
* @arg @ref UART_IT_WUF Wakeup from stop mode interrupt
* @arg @ref UART_IT_CM Character match interrupt
* @arg @ref UART_IT_CTS CTS change interrupt
* @arg @ref UART_IT_LBD LIN Break detection interrupt
* @arg @ref UART_IT_TXE Transmit Data Register empty interrupt
* @arg @ref UART_IT_TXFNF TX FIFO not full interrupt
* @arg @ref UART_IT_TC Transmission complete interrupt
* @arg @ref UART_IT_RXNE Receive Data register not empty interrupt
* @arg @ref UART_IT_RXFNE RXFIFO not empty interrupt
* @arg @ref UART_IT_RTO Receive Timeout interrupt
* @arg @ref UART_IT_IDLE Idle line detection interrupt
* @arg @ref UART_IT_PE Parity Error interrupt
* @arg @ref UART_IT_ERR Error interrupt (Frame error, noise error, overrun error)
* @retval The new state of __INTERRUPT__ (SET or RESET).
*/
#define __HAL_UART_GET_IT(__HANDLE__, __INTERRUPT__) ((((__HANDLE__)->Instance->ISR\
& (1U << ((__INTERRUPT__)>> 8U))) != RESET) ? SET : RESET)
/** @brief Check whether the specified UART interrupt source is enabled or not.
* @param __HANDLE__ specifies the UART Handle.
* @param __INTERRUPT__ specifies the UART interrupt source to check.
* This parameter can be one of the following values:
* @arg @ref UART_IT_RXFF RXFIFO Full interrupt
* @arg @ref UART_IT_TXFE TXFIFO Empty interrupt
* @arg @ref UART_IT_RXFT RXFIFO threshold interrupt
* @arg @ref UART_IT_TXFT TXFIFO threshold interrupt
* @arg @ref UART_IT_WUF Wakeup from stop mode interrupt
* @arg @ref UART_IT_CM Character match interrupt
* @arg @ref UART_IT_CTS CTS change interrupt
* @arg @ref UART_IT_LBD LIN Break detection interrupt
* @arg @ref UART_IT_TXE Transmit Data Register empty interrupt
* @arg @ref UART_IT_TXFNF TX FIFO not full interrupt
* @arg @ref UART_IT_TC Transmission complete interrupt
* @arg @ref UART_IT_RXNE Receive Data register not empty interrupt
* @arg @ref UART_IT_RXFNE RXFIFO not empty interrupt
* @arg @ref UART_IT_RTO Receive Timeout interrupt
* @arg @ref UART_IT_IDLE Idle line detection interrupt
* @arg @ref UART_IT_PE Parity Error interrupt
* @arg @ref UART_IT_ERR Error interrupt (Frame error, noise error, overrun error)
* @retval The new state of __INTERRUPT__ (SET or RESET).
*/
#define __HAL_UART_GET_IT_SOURCE(__HANDLE__, __INTERRUPT__) ((((((((uint8_t)(__INTERRUPT__)) >> 5U) == 1U) ?\
(__HANDLE__)->Instance->CR1 : \
(((((uint8_t)(__INTERRUPT__)) >> 5U) == 2U) ?\
(__HANDLE__)->Instance->CR2 : \
(__HANDLE__)->Instance->CR3)) & (1U <<\
(((uint16_t)(__INTERRUPT__)) &\
UART_IT_MASK))) != RESET) ? SET : RESET)
/** @brief Clear the specified UART ISR flag, in setting the proper ICR register flag.
* @param __HANDLE__ specifies the UART Handle.
* @param __IT_CLEAR__ specifies the interrupt clear register flag that needs to be set
* to clear the corresponding interrupt
* This parameter can be one of the following values:
* @arg @ref UART_CLEAR_PEF Parity Error Clear Flag
* @arg @ref UART_CLEAR_FEF Framing Error Clear Flag
* @arg @ref UART_CLEAR_NEF Noise detected Clear Flag
* @arg @ref UART_CLEAR_OREF Overrun Error Clear Flag
* @arg @ref UART_CLEAR_IDLEF IDLE line detected Clear Flag
* @arg @ref UART_CLEAR_RTOF Receiver timeout clear flag
* @arg @ref UART_CLEAR_TXFECF TXFIFO empty Clear Flag
* @arg @ref UART_CLEAR_TCF Transmission Complete Clear Flag
* @arg @ref UART_CLEAR_LBDF LIN Break Detection Clear Flag
* @arg @ref UART_CLEAR_CTSF CTS Interrupt Clear Flag
* @arg @ref UART_CLEAR_CMF Character Match Clear Flag
* @arg @ref UART_CLEAR_WUF Wake Up from stop mode Clear Flag
* @retval None
*/
#define __HAL_UART_CLEAR_IT(__HANDLE__, __IT_CLEAR__) ((__HANDLE__)->Instance->ICR = (uint32_t)(__IT_CLEAR__))
/** @brief Set a specific UART request flag.
* @param __HANDLE__ specifies the UART Handle.
* @param __REQ__ specifies the request flag to set
* This parameter can be one of the following values:
* @arg @ref UART_AUTOBAUD_REQUEST Auto-Baud Rate Request
* @arg @ref UART_SENDBREAK_REQUEST Send Break Request
* @arg @ref UART_MUTE_MODE_REQUEST Mute Mode Request
* @arg @ref UART_RXDATA_FLUSH_REQUEST Receive Data flush Request
* @arg @ref UART_TXDATA_FLUSH_REQUEST Transmit data flush Request
* @retval None
*/
#define __HAL_UART_SEND_REQ(__HANDLE__, __REQ__) ((__HANDLE__)->Instance->RQR |= (uint16_t)(__REQ__))
/** @brief Enable the UART one bit sample method.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_ONE_BIT_SAMPLE_ENABLE(__HANDLE__) ((__HANDLE__)->Instance->CR3|= USART_CR3_ONEBIT)
/** @brief Disable the UART one bit sample method.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_ONE_BIT_SAMPLE_DISABLE(__HANDLE__) ((__HANDLE__)->Instance->CR3 &= ~USART_CR3_ONEBIT)
/** @brief Enable UART.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_ENABLE(__HANDLE__) ((__HANDLE__)->Instance->CR1 |= USART_CR1_UE)
/** @brief Disable UART.
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_DISABLE(__HANDLE__) ((__HANDLE__)->Instance->CR1 &= ~USART_CR1_UE)
/** @brief Enable CTS flow control.
* @note This macro allows to enable CTS hardware flow control for a given UART instance,
* without need to call HAL_UART_Init() function.
* As involving direct access to UART registers, usage of this macro should be fully endorsed by user.
* @note As macro is expected to be used for modifying CTS Hw flow control feature activation, without need
* for USART instance Deinit/Init, following conditions for macro call should be fulfilled :
* - UART instance should have already been initialised (through call of HAL_UART_Init() )
* - macro could only be called when corresponding UART instance is disabled
* (i.e. __HAL_UART_DISABLE(__HANDLE__)) and should be followed by an Enable
* macro (i.e. __HAL_UART_ENABLE(__HANDLE__)).
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_HWCONTROL_CTS_ENABLE(__HANDLE__) \
do{ \
ATOMIC_SET_BIT((__HANDLE__)->Instance->CR3, USART_CR3_CTSE); \
(__HANDLE__)->Init.HwFlowCtl |= USART_CR3_CTSE; \
} while(0U)
/** @brief Disable CTS flow control.
* @note This macro allows to disable CTS hardware flow control for a given UART instance,
* without need to call HAL_UART_Init() function.
* As involving direct access to UART registers, usage of this macro should be fully endorsed by user.
* @note As macro is expected to be used for modifying CTS Hw flow control feature activation, without need
* for USART instance Deinit/Init, following conditions for macro call should be fulfilled :
* - UART instance should have already been initialised (through call of HAL_UART_Init() )
* - macro could only be called when corresponding UART instance is disabled
* (i.e. __HAL_UART_DISABLE(__HANDLE__)) and should be followed by an Enable
* macro (i.e. __HAL_UART_ENABLE(__HANDLE__)).
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_HWCONTROL_CTS_DISABLE(__HANDLE__) \
do{ \
ATOMIC_CLEAR_BIT((__HANDLE__)->Instance->CR3, USART_CR3_CTSE); \
(__HANDLE__)->Init.HwFlowCtl &= ~(USART_CR3_CTSE); \
} while(0U)
/** @brief Enable RTS flow control.
* @note This macro allows to enable RTS hardware flow control for a given UART instance,
* without need to call HAL_UART_Init() function.
* As involving direct access to UART registers, usage of this macro should be fully endorsed by user.
* @note As macro is expected to be used for modifying RTS Hw flow control feature activation, without need
* for USART instance Deinit/Init, following conditions for macro call should be fulfilled :
* - UART instance should have already been initialised (through call of HAL_UART_Init() )
* - macro could only be called when corresponding UART instance is disabled
* (i.e. __HAL_UART_DISABLE(__HANDLE__)) and should be followed by an Enable
* macro (i.e. __HAL_UART_ENABLE(__HANDLE__)).
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_HWCONTROL_RTS_ENABLE(__HANDLE__) \
do{ \
ATOMIC_SET_BIT((__HANDLE__)->Instance->CR3, USART_CR3_RTSE); \
(__HANDLE__)->Init.HwFlowCtl |= USART_CR3_RTSE; \
} while(0U)
/** @brief Disable RTS flow control.
* @note This macro allows to disable RTS hardware flow control for a given UART instance,
* without need to call HAL_UART_Init() function.
* As involving direct access to UART registers, usage of this macro should be fully endorsed by user.
* @note As macro is expected to be used for modifying RTS Hw flow control feature activation, without need
* for USART instance Deinit/Init, following conditions for macro call should be fulfilled :
* - UART instance should have already been initialised (through call of HAL_UART_Init() )
* - macro could only be called when corresponding UART instance is disabled
* (i.e. __HAL_UART_DISABLE(__HANDLE__)) and should be followed by an Enable
* macro (i.e. __HAL_UART_ENABLE(__HANDLE__)).
* @param __HANDLE__ specifies the UART Handle.
* @retval None
*/
#define __HAL_UART_HWCONTROL_RTS_DISABLE(__HANDLE__) \
do{ \
ATOMIC_CLEAR_BIT((__HANDLE__)->Instance->CR3, USART_CR3_RTSE);\
(__HANDLE__)->Init.HwFlowCtl &= ~(USART_CR3_RTSE); \
} while(0U)
/**
* @}
*/
/* Private macros --------------------------------------------------------*/
/** @defgroup UART_Private_Macros UART Private Macros
* @{
*/
/** @brief Get UART clok division factor from clock prescaler value.
* @param __CLOCKPRESCALER__ UART prescaler value.
* @retval UART clock division factor
*/
#define UART_GET_DIV_FACTOR(__CLOCKPRESCALER__) \
(((__CLOCKPRESCALER__) == UART_PRESCALER_DIV1) ? 1U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV2) ? 2U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV4) ? 4U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV6) ? 6U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV8) ? 8U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV10) ? 10U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV12) ? 12U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV16) ? 16U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV32) ? 32U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV64) ? 64U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV128) ? 128U : \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV256) ? 256U : 1U)
/** @brief BRR division operation to set BRR register with LPUART.
* @param __PCLK__ LPUART clock.
* @param __BAUD__ Baud rate set by the user.
* @param __CLOCKPRESCALER__ UART prescaler value.
* @retval Division result
*/
#define UART_DIV_LPUART(__PCLK__, __BAUD__, __CLOCKPRESCALER__) \
((uint32_t)((((((uint64_t)(__PCLK__))/(UARTPrescTable[(__CLOCKPRESCALER__)]))*256U)+ \
(uint32_t)((__BAUD__)/2U)) / (__BAUD__)) \
)
/** @brief BRR division operation to set BRR register in 8-bit oversampling mode.
* @param __PCLK__ UART clock.
* @param __BAUD__ Baud rate set by the user.
* @param __CLOCKPRESCALER__ UART prescaler value.
* @retval Division result
*/
#define UART_DIV_SAMPLING8(__PCLK__, __BAUD__, __CLOCKPRESCALER__) \
(((((__PCLK__)/UARTPrescTable[(__CLOCKPRESCALER__)])*2U) + ((__BAUD__)/2U)) / (__BAUD__))
/** @brief BRR division operation to set BRR register in 16-bit oversampling mode.
* @param __PCLK__ UART clock.
* @param __BAUD__ Baud rate set by the user.
* @param __CLOCKPRESCALER__ UART prescaler value.
* @retval Division result
*/
#define UART_DIV_SAMPLING16(__PCLK__, __BAUD__, __CLOCKPRESCALER__) \
((((__PCLK__)/UARTPrescTable[(__CLOCKPRESCALER__)]) + ((__BAUD__)/2U)) / (__BAUD__))
/** @brief Check whether or not UART instance is Low Power UART.
* @param __HANDLE__ specifies the UART Handle.
* @retval SET (instance is LPUART) or RESET (instance isn't LPUART)
*/
#define UART_INSTANCE_LOWPOWER(__HANDLE__) (IS_LPUART_INSTANCE((__HANDLE__)->Instance))
/** @brief Check UART Baud rate.
* @param __BAUDRATE__ Baudrate specified by the user.
* The maximum Baud Rate is derived from the maximum clock on G4 (i.e. 150 MHz)
* divided by the smallest oversampling used on the USART (i.e. 8)
* @retval SET (__BAUDRATE__ is valid) or RESET (__BAUDRATE__ is invalid)
*/
#define IS_UART_BAUDRATE(__BAUDRATE__) ((__BAUDRATE__) < 18750001U)
/** @brief Check UART assertion time.
* @param __TIME__ 5-bit value assertion time.
* @retval Test result (TRUE or FALSE).
*/
#define IS_UART_ASSERTIONTIME(__TIME__) ((__TIME__) <= 0x1FU)
/** @brief Check UART deassertion time.
* @param __TIME__ 5-bit value deassertion time.
* @retval Test result (TRUE or FALSE).
*/
#define IS_UART_DEASSERTIONTIME(__TIME__) ((__TIME__) <= 0x1FU)
/**
* @brief Ensure that UART frame number of stop bits is valid.
* @param __STOPBITS__ UART frame number of stop bits.
* @retval SET (__STOPBITS__ is valid) or RESET (__STOPBITS__ is invalid)
*/
#define IS_UART_STOPBITS(__STOPBITS__) (((__STOPBITS__) == UART_STOPBITS_0_5) || \
((__STOPBITS__) == UART_STOPBITS_1) || \
((__STOPBITS__) == UART_STOPBITS_1_5) || \
((__STOPBITS__) == UART_STOPBITS_2))
/**
* @brief Ensure that LPUART frame number of stop bits is valid.
* @param __STOPBITS__ LPUART frame number of stop bits.
* @retval SET (__STOPBITS__ is valid) or RESET (__STOPBITS__ is invalid)
*/
#define IS_LPUART_STOPBITS(__STOPBITS__) (((__STOPBITS__) == UART_STOPBITS_1) || \
((__STOPBITS__) == UART_STOPBITS_2))
/**
* @brief Ensure that UART frame parity is valid.
* @param __PARITY__ UART frame parity.
* @retval SET (__PARITY__ is valid) or RESET (__PARITY__ is invalid)
*/
#define IS_UART_PARITY(__PARITY__) (((__PARITY__) == UART_PARITY_NONE) || \
((__PARITY__) == UART_PARITY_EVEN) || \
((__PARITY__) == UART_PARITY_ODD))
/**
* @brief Ensure that UART hardware flow control is valid.
* @param __CONTROL__ UART hardware flow control.
* @retval SET (__CONTROL__ is valid) or RESET (__CONTROL__ is invalid)
*/
#define IS_UART_HARDWARE_FLOW_CONTROL(__CONTROL__)\
(((__CONTROL__) == UART_HWCONTROL_NONE) || \
((__CONTROL__) == UART_HWCONTROL_RTS) || \
((__CONTROL__) == UART_HWCONTROL_CTS) || \
((__CONTROL__) == UART_HWCONTROL_RTS_CTS))
/**
* @brief Ensure that UART communication mode is valid.
* @param __MODE__ UART communication mode.
* @retval SET (__MODE__ is valid) or RESET (__MODE__ is invalid)
*/
#define IS_UART_MODE(__MODE__) ((((__MODE__) & (~((uint32_t)(UART_MODE_TX_RX)))) == 0x00U) && ((__MODE__) != 0x00U))
/**
* @brief Ensure that UART state is valid.
* @param __STATE__ UART state.
* @retval SET (__STATE__ is valid) or RESET (__STATE__ is invalid)
*/
#define IS_UART_STATE(__STATE__) (((__STATE__) == UART_STATE_DISABLE) || \
((__STATE__) == UART_STATE_ENABLE))
/**
* @brief Ensure that UART oversampling is valid.
* @param __SAMPLING__ UART oversampling.
* @retval SET (__SAMPLING__ is valid) or RESET (__SAMPLING__ is invalid)
*/
#define IS_UART_OVERSAMPLING(__SAMPLING__) (((__SAMPLING__) == UART_OVERSAMPLING_16) || \
((__SAMPLING__) == UART_OVERSAMPLING_8))
/**
* @brief Ensure that UART frame sampling is valid.
* @param __ONEBIT__ UART frame sampling.
* @retval SET (__ONEBIT__ is valid) or RESET (__ONEBIT__ is invalid)
*/
#define IS_UART_ONE_BIT_SAMPLE(__ONEBIT__) (((__ONEBIT__) == UART_ONE_BIT_SAMPLE_DISABLE) || \
((__ONEBIT__) == UART_ONE_BIT_SAMPLE_ENABLE))
/**
* @brief Ensure that UART auto Baud rate detection mode is valid.
* @param __MODE__ UART auto Baud rate detection mode.
* @retval SET (__MODE__ is valid) or RESET (__MODE__ is invalid)
*/
#define IS_UART_ADVFEATURE_AUTOBAUDRATEMODE(__MODE__) (((__MODE__) == UART_ADVFEATURE_AUTOBAUDRATE_ONSTARTBIT) || \
((__MODE__) == UART_ADVFEATURE_AUTOBAUDRATE_ONFALLINGEDGE) || \
((__MODE__) == UART_ADVFEATURE_AUTOBAUDRATE_ON0X7FFRAME) || \
((__MODE__) == UART_ADVFEATURE_AUTOBAUDRATE_ON0X55FRAME))
/**
* @brief Ensure that UART receiver timeout setting is valid.
* @param __TIMEOUT__ UART receiver timeout setting.
* @retval SET (__TIMEOUT__ is valid) or RESET (__TIMEOUT__ is invalid)
*/
#define IS_UART_RECEIVER_TIMEOUT(__TIMEOUT__) (((__TIMEOUT__) == UART_RECEIVER_TIMEOUT_DISABLE) || \
((__TIMEOUT__) == UART_RECEIVER_TIMEOUT_ENABLE))
/** @brief Check the receiver timeout value.
* @note The maximum UART receiver timeout value is 0xFFFFFF.
* @param __TIMEOUTVALUE__ receiver timeout value.
* @retval Test result (TRUE or FALSE)
*/
#define IS_UART_RECEIVER_TIMEOUT_VALUE(__TIMEOUTVALUE__) ((__TIMEOUTVALUE__) <= 0xFFFFFFU)
/**
* @brief Ensure that UART LIN state is valid.
* @param __LIN__ UART LIN state.
* @retval SET (__LIN__ is valid) or RESET (__LIN__ is invalid)
*/
#define IS_UART_LIN(__LIN__) (((__LIN__) == UART_LIN_DISABLE) || \
((__LIN__) == UART_LIN_ENABLE))
/**
* @brief Ensure that UART LIN break detection length is valid.
* @param __LENGTH__ UART LIN break detection length.
* @retval SET (__LENGTH__ is valid) or RESET (__LENGTH__ is invalid)
*/
#define IS_UART_LIN_BREAK_DETECT_LENGTH(__LENGTH__) (((__LENGTH__) == UART_LINBREAKDETECTLENGTH_10B) || \
((__LENGTH__) == UART_LINBREAKDETECTLENGTH_11B))
/**
* @brief Ensure that UART DMA TX state is valid.
* @param __DMATX__ UART DMA TX state.
* @retval SET (__DMATX__ is valid) or RESET (__DMATX__ is invalid)
*/
#define IS_UART_DMA_TX(__DMATX__) (((__DMATX__) == UART_DMA_TX_DISABLE) || \
((__DMATX__) == UART_DMA_TX_ENABLE))
/**
* @brief Ensure that UART DMA RX state is valid.
* @param __DMARX__ UART DMA RX state.
* @retval SET (__DMARX__ is valid) or RESET (__DMARX__ is invalid)
*/
#define IS_UART_DMA_RX(__DMARX__) (((__DMARX__) == UART_DMA_RX_DISABLE) || \
((__DMARX__) == UART_DMA_RX_ENABLE))
/**
* @brief Ensure that UART half-duplex state is valid.
* @param __HDSEL__ UART half-duplex state.
* @retval SET (__HDSEL__ is valid) or RESET (__HDSEL__ is invalid)
*/
#define IS_UART_HALF_DUPLEX(__HDSEL__) (((__HDSEL__) == UART_HALF_DUPLEX_DISABLE) || \
((__HDSEL__) == UART_HALF_DUPLEX_ENABLE))
/**
* @brief Ensure that UART wake-up method is valid.
* @param __WAKEUP__ UART wake-up method .
* @retval SET (__WAKEUP__ is valid) or RESET (__WAKEUP__ is invalid)
*/
#define IS_UART_WAKEUPMETHOD(__WAKEUP__) (((__WAKEUP__) == UART_WAKEUPMETHOD_IDLELINE) || \
((__WAKEUP__) == UART_WAKEUPMETHOD_ADDRESSMARK))
/**
* @brief Ensure that UART request parameter is valid.
* @param __PARAM__ UART request parameter.
* @retval SET (__PARAM__ is valid) or RESET (__PARAM__ is invalid)
*/
#define IS_UART_REQUEST_PARAMETER(__PARAM__) (((__PARAM__) == UART_AUTOBAUD_REQUEST) || \
((__PARAM__) == UART_SENDBREAK_REQUEST) || \
((__PARAM__) == UART_MUTE_MODE_REQUEST) || \
((__PARAM__) == UART_RXDATA_FLUSH_REQUEST) || \
((__PARAM__) == UART_TXDATA_FLUSH_REQUEST))
/**
* @brief Ensure that UART advanced features initialization is valid.
* @param __INIT__ UART advanced features initialization.
* @retval SET (__INIT__ is valid) or RESET (__INIT__ is invalid)
*/
#define IS_UART_ADVFEATURE_INIT(__INIT__) ((__INIT__) <= (UART_ADVFEATURE_NO_INIT | \
UART_ADVFEATURE_TXINVERT_INIT | \
UART_ADVFEATURE_RXINVERT_INIT | \
UART_ADVFEATURE_DATAINVERT_INIT | \
UART_ADVFEATURE_SWAP_INIT | \
UART_ADVFEATURE_RXOVERRUNDISABLE_INIT | \
UART_ADVFEATURE_DMADISABLEONERROR_INIT | \
UART_ADVFEATURE_AUTOBAUDRATE_INIT | \
UART_ADVFEATURE_MSBFIRST_INIT))
/**
* @brief Ensure that UART frame TX inversion setting is valid.
* @param __TXINV__ UART frame TX inversion setting.
* @retval SET (__TXINV__ is valid) or RESET (__TXINV__ is invalid)
*/
#define IS_UART_ADVFEATURE_TXINV(__TXINV__) (((__TXINV__) == UART_ADVFEATURE_TXINV_DISABLE) || \
((__TXINV__) == UART_ADVFEATURE_TXINV_ENABLE))
/**
* @brief Ensure that UART frame RX inversion setting is valid.
* @param __RXINV__ UART frame RX inversion setting.
* @retval SET (__RXINV__ is valid) or RESET (__RXINV__ is invalid)
*/
#define IS_UART_ADVFEATURE_RXINV(__RXINV__) (((__RXINV__) == UART_ADVFEATURE_RXINV_DISABLE) || \
((__RXINV__) == UART_ADVFEATURE_RXINV_ENABLE))
/**
* @brief Ensure that UART frame data inversion setting is valid.
* @param __DATAINV__ UART frame data inversion setting.
* @retval SET (__DATAINV__ is valid) or RESET (__DATAINV__ is invalid)
*/
#define IS_UART_ADVFEATURE_DATAINV(__DATAINV__) (((__DATAINV__) == UART_ADVFEATURE_DATAINV_DISABLE) || \
((__DATAINV__) == UART_ADVFEATURE_DATAINV_ENABLE))
/**
* @brief Ensure that UART frame RX/TX pins swap setting is valid.
* @param __SWAP__ UART frame RX/TX pins swap setting.
* @retval SET (__SWAP__ is valid) or RESET (__SWAP__ is invalid)
*/
#define IS_UART_ADVFEATURE_SWAP(__SWAP__) (((__SWAP__) == UART_ADVFEATURE_SWAP_DISABLE) || \
((__SWAP__) == UART_ADVFEATURE_SWAP_ENABLE))
/**
* @brief Ensure that UART frame overrun setting is valid.
* @param __OVERRUN__ UART frame overrun setting.
* @retval SET (__OVERRUN__ is valid) or RESET (__OVERRUN__ is invalid)
*/
#define IS_UART_OVERRUN(__OVERRUN__) (((__OVERRUN__) == UART_ADVFEATURE_OVERRUN_ENABLE) || \
((__OVERRUN__) == UART_ADVFEATURE_OVERRUN_DISABLE))
/**
* @brief Ensure that UART auto Baud rate state is valid.
* @param __AUTOBAUDRATE__ UART auto Baud rate state.
* @retval SET (__AUTOBAUDRATE__ is valid) or RESET (__AUTOBAUDRATE__ is invalid)
*/
#define IS_UART_ADVFEATURE_AUTOBAUDRATE(__AUTOBAUDRATE__) (((__AUTOBAUDRATE__) == \
UART_ADVFEATURE_AUTOBAUDRATE_DISABLE) || \
((__AUTOBAUDRATE__) == UART_ADVFEATURE_AUTOBAUDRATE_ENABLE))
/**
* @brief Ensure that UART DMA enabling or disabling on error setting is valid.
* @param __DMA__ UART DMA enabling or disabling on error setting.
* @retval SET (__DMA__ is valid) or RESET (__DMA__ is invalid)
*/
#define IS_UART_ADVFEATURE_DMAONRXERROR(__DMA__) (((__DMA__) == UART_ADVFEATURE_DMA_ENABLEONRXERROR) || \
((__DMA__) == UART_ADVFEATURE_DMA_DISABLEONRXERROR))
/**
* @brief Ensure that UART frame MSB first setting is valid.
* @param __MSBFIRST__ UART frame MSB first setting.
* @retval SET (__MSBFIRST__ is valid) or RESET (__MSBFIRST__ is invalid)
*/
#define IS_UART_ADVFEATURE_MSBFIRST(__MSBFIRST__) (((__MSBFIRST__) == UART_ADVFEATURE_MSBFIRST_DISABLE) || \
((__MSBFIRST__) == UART_ADVFEATURE_MSBFIRST_ENABLE))
/**
* @brief Ensure that UART stop mode state is valid.
* @param __STOPMODE__ UART stop mode state.
* @retval SET (__STOPMODE__ is valid) or RESET (__STOPMODE__ is invalid)
*/
#define IS_UART_ADVFEATURE_STOPMODE(__STOPMODE__) (((__STOPMODE__) == UART_ADVFEATURE_STOPMODE_DISABLE) || \
((__STOPMODE__) == UART_ADVFEATURE_STOPMODE_ENABLE))
/**
* @brief Ensure that UART mute mode state is valid.
* @param __MUTE__ UART mute mode state.
* @retval SET (__MUTE__ is valid) or RESET (__MUTE__ is invalid)
*/
#define IS_UART_MUTE_MODE(__MUTE__) (((__MUTE__) == UART_ADVFEATURE_MUTEMODE_DISABLE) || \
((__MUTE__) == UART_ADVFEATURE_MUTEMODE_ENABLE))
/**
* @brief Ensure that UART wake-up selection is valid.
* @param __WAKE__ UART wake-up selection.
* @retval SET (__WAKE__ is valid) or RESET (__WAKE__ is invalid)
*/
#define IS_UART_WAKEUP_SELECTION(__WAKE__) (((__WAKE__) == UART_WAKEUP_ON_ADDRESS) || \
((__WAKE__) == UART_WAKEUP_ON_STARTBIT) || \
((__WAKE__) == UART_WAKEUP_ON_READDATA_NONEMPTY))
/**
* @brief Ensure that UART driver enable polarity is valid.
* @param __POLARITY__ UART driver enable polarity.
* @retval SET (__POLARITY__ is valid) or RESET (__POLARITY__ is invalid)
*/
#define IS_UART_DE_POLARITY(__POLARITY__) (((__POLARITY__) == UART_DE_POLARITY_HIGH) || \
((__POLARITY__) == UART_DE_POLARITY_LOW))
/**
* @brief Ensure that UART Prescaler is valid.
* @param __CLOCKPRESCALER__ UART Prescaler value.
* @retval SET (__CLOCKPRESCALER__ is valid) or RESET (__CLOCKPRESCALER__ is invalid)
*/
#define IS_UART_PRESCALER(__CLOCKPRESCALER__) (((__CLOCKPRESCALER__) == UART_PRESCALER_DIV1) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV2) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV4) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV6) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV8) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV10) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV12) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV16) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV32) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV64) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV128) || \
((__CLOCKPRESCALER__) == UART_PRESCALER_DIV256))
/**
* @}
*/
/* Include UART HAL Extended module */
#include "stm32g4xx_hal_uart_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup UART_Exported_Functions UART Exported Functions
* @{
*/
/** @addtogroup UART_Exported_Functions_Group1 Initialization and de-initialization functions
* @{
*/
/* Initialization and de-initialization functions ****************************/
HAL_StatusTypeDef HAL_UART_Init(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_HalfDuplex_Init(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_LIN_Init(UART_HandleTypeDef *huart, uint32_t BreakDetectLength);
HAL_StatusTypeDef HAL_MultiProcessor_Init(UART_HandleTypeDef *huart, uint8_t Address, uint32_t WakeUpMethod);
HAL_StatusTypeDef HAL_UART_DeInit(UART_HandleTypeDef *huart);
void HAL_UART_MspInit(UART_HandleTypeDef *huart);
void HAL_UART_MspDeInit(UART_HandleTypeDef *huart);
/* Callbacks Register/UnRegister functions ***********************************/
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
HAL_StatusTypeDef HAL_UART_RegisterCallback(UART_HandleTypeDef *huart, HAL_UART_CallbackIDTypeDef CallbackID,
pUART_CallbackTypeDef pCallback);
HAL_StatusTypeDef HAL_UART_UnRegisterCallback(UART_HandleTypeDef *huart, HAL_UART_CallbackIDTypeDef CallbackID);
HAL_StatusTypeDef HAL_UART_RegisterRxEventCallback(UART_HandleTypeDef *huart, pUART_RxEventCallbackTypeDef pCallback);
HAL_StatusTypeDef HAL_UART_UnRegisterRxEventCallback(UART_HandleTypeDef *huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
/**
* @}
*/
/** @addtogroup UART_Exported_Functions_Group2 IO operation functions
* @{
*/
/* IO operation functions *****************************************************/
HAL_StatusTypeDef HAL_UART_Transmit(UART_HandleTypeDef *huart, const uint8_t *pData, uint16_t Size, uint32_t Timeout);
HAL_StatusTypeDef HAL_UART_Receive(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size, uint32_t Timeout);
HAL_StatusTypeDef HAL_UART_Transmit_IT(UART_HandleTypeDef *huart, const uint8_t *pData, uint16_t Size);
HAL_StatusTypeDef HAL_UART_Receive_IT(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size);
HAL_StatusTypeDef HAL_UART_Transmit_DMA(UART_HandleTypeDef *huart, const uint8_t *pData, uint16_t Size);
HAL_StatusTypeDef HAL_UART_Receive_DMA(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size);
HAL_StatusTypeDef HAL_UART_DMAPause(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_DMAResume(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_DMAStop(UART_HandleTypeDef *huart);
/* Transfer Abort functions */
HAL_StatusTypeDef HAL_UART_Abort(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_AbortTransmit(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_AbortReceive(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_Abort_IT(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_AbortTransmit_IT(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_AbortReceive_IT(UART_HandleTypeDef *huart);
void HAL_UART_IRQHandler(UART_HandleTypeDef *huart);
void HAL_UART_TxHalfCpltCallback(UART_HandleTypeDef *huart);
void HAL_UART_TxCpltCallback(UART_HandleTypeDef *huart);
void HAL_UART_RxHalfCpltCallback(UART_HandleTypeDef *huart);
void HAL_UART_RxCpltCallback(UART_HandleTypeDef *huart);
void HAL_UART_ErrorCallback(UART_HandleTypeDef *huart);
void HAL_UART_AbortCpltCallback(UART_HandleTypeDef *huart);
void HAL_UART_AbortTransmitCpltCallback(UART_HandleTypeDef *huart);
void HAL_UART_AbortReceiveCpltCallback(UART_HandleTypeDef *huart);
void HAL_UARTEx_RxEventCallback(UART_HandleTypeDef *huart, uint16_t Size);
/**
* @}
*/
/** @addtogroup UART_Exported_Functions_Group3 Peripheral Control functions
* @{
*/
/* Peripheral Control functions ************************************************/
void HAL_UART_ReceiverTimeout_Config(UART_HandleTypeDef *huart, uint32_t TimeoutValue);
HAL_StatusTypeDef HAL_UART_EnableReceiverTimeout(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UART_DisableReceiverTimeout(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_LIN_SendBreak(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_MultiProcessor_EnableMuteMode(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_MultiProcessor_DisableMuteMode(UART_HandleTypeDef *huart);
void HAL_MultiProcessor_EnterMuteMode(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_HalfDuplex_EnableTransmitter(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_HalfDuplex_EnableReceiver(UART_HandleTypeDef *huart);
/**
* @}
*/
/** @addtogroup UART_Exported_Functions_Group4 Peripheral State and Error functions
* @{
*/
/* Peripheral State and Errors functions **************************************************/
HAL_UART_StateTypeDef HAL_UART_GetState(const UART_HandleTypeDef *huart);
uint32_t HAL_UART_GetError(const UART_HandleTypeDef *huart);
/**
* @}
*/
/**
* @}
*/
/* Private functions -----------------------------------------------------------*/
/** @addtogroup UART_Private_Functions UART Private Functions
* @{
*/
#if (USE_HAL_UART_REGISTER_CALLBACKS == 1)
void UART_InitCallbacksToDefault(UART_HandleTypeDef *huart);
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
HAL_StatusTypeDef UART_SetConfig(UART_HandleTypeDef *huart);
HAL_StatusTypeDef UART_CheckIdleState(UART_HandleTypeDef *huart);
HAL_StatusTypeDef UART_WaitOnFlagUntilTimeout(UART_HandleTypeDef *huart, uint32_t Flag, FlagStatus Status,
uint32_t Tickstart, uint32_t Timeout);
void UART_AdvFeatureConfig(UART_HandleTypeDef *huart);
HAL_StatusTypeDef UART_Start_Receive_IT(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size);
HAL_StatusTypeDef UART_Start_Receive_DMA(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size);
/**
* @}
*/
/* Private variables -----------------------------------------------------------*/
/** @defgroup UART_Private_variables UART Private variables
* @{
*/
/* Prescaler Table used in BRR computation macros.
Declared as extern here to allow use of private UART macros, outside of HAL UART functions */
extern const uint16_t UARTPrescTable[12];
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_UART_H */
| 90,424 | C | 50.76016 | 120 | 0.541847 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_uart_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_uart_ex.h
* @author MCD Application Team
* @brief Header file of UART HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_UART_EX_H
#define STM32G4xx_HAL_UART_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup UARTEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup UARTEx_Exported_Types UARTEx Exported Types
* @{
*/
/**
* @brief UART wake up from stop mode parameters
*/
typedef struct
{
uint32_t WakeUpEvent; /*!< Specifies which event will activate the Wakeup from Stop mode flag (WUF).
This parameter can be a value of @ref UART_WakeUp_from_Stop_Selection.
If set to UART_WAKEUP_ON_ADDRESS, the two other fields below must
be filled up. */
uint16_t AddressLength; /*!< Specifies whether the address is 4 or 7-bit long.
This parameter can be a value of @ref UARTEx_WakeUp_Address_Length. */
uint8_t Address; /*!< UART/USART node address (7-bit long max). */
} UART_WakeUpTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup UARTEx_Exported_Constants UARTEx Exported Constants
* @{
*/
/** @defgroup UARTEx_Word_Length UARTEx Word Length
* @{
*/
#define UART_WORDLENGTH_7B USART_CR1_M1 /*!< 7-bit long UART frame */
#define UART_WORDLENGTH_8B 0x00000000U /*!< 8-bit long UART frame */
#define UART_WORDLENGTH_9B USART_CR1_M0 /*!< 9-bit long UART frame */
/**
* @}
*/
/** @defgroup UARTEx_WakeUp_Address_Length UARTEx WakeUp Address Length
* @{
*/
#define UART_ADDRESS_DETECT_4B 0x00000000U /*!< 4-bit long wake-up address */
#define UART_ADDRESS_DETECT_7B USART_CR2_ADDM7 /*!< 7-bit long wake-up address */
/**
* @}
*/
/** @defgroup UARTEx_FIFO_mode UARTEx FIFO mode
* @brief UART FIFO mode
* @{
*/
#define UART_FIFOMODE_DISABLE 0x00000000U /*!< FIFO mode disable */
#define UART_FIFOMODE_ENABLE USART_CR1_FIFOEN /*!< FIFO mode enable */
/**
* @}
*/
/** @defgroup UARTEx_TXFIFO_threshold_level UARTEx TXFIFO threshold level
* @brief UART TXFIFO threshold level
* @{
*/
#define UART_TXFIFO_THRESHOLD_1_8 0x00000000U /*!< TX FIFO reaches 1/8 of its depth */
#define UART_TXFIFO_THRESHOLD_1_4 USART_CR3_TXFTCFG_0 /*!< TX FIFO reaches 1/4 of its depth */
#define UART_TXFIFO_THRESHOLD_1_2 USART_CR3_TXFTCFG_1 /*!< TX FIFO reaches 1/2 of its depth */
#define UART_TXFIFO_THRESHOLD_3_4 (USART_CR3_TXFTCFG_0|USART_CR3_TXFTCFG_1) /*!< TX FIFO reaches 3/4 of its depth */
#define UART_TXFIFO_THRESHOLD_7_8 USART_CR3_TXFTCFG_2 /*!< TX FIFO reaches 7/8 of its depth */
#define UART_TXFIFO_THRESHOLD_8_8 (USART_CR3_TXFTCFG_2|USART_CR3_TXFTCFG_0) /*!< TX FIFO becomes empty */
/**
* @}
*/
/** @defgroup UARTEx_RXFIFO_threshold_level UARTEx RXFIFO threshold level
* @brief UART RXFIFO threshold level
* @{
*/
#define UART_RXFIFO_THRESHOLD_1_8 0x00000000U /*!< RX FIFO reaches 1/8 of its depth */
#define UART_RXFIFO_THRESHOLD_1_4 USART_CR3_RXFTCFG_0 /*!< RX FIFO reaches 1/4 of its depth */
#define UART_RXFIFO_THRESHOLD_1_2 USART_CR3_RXFTCFG_1 /*!< RX FIFO reaches 1/2 of its depth */
#define UART_RXFIFO_THRESHOLD_3_4 (USART_CR3_RXFTCFG_0|USART_CR3_RXFTCFG_1) /*!< RX FIFO reaches 3/4 of its depth */
#define UART_RXFIFO_THRESHOLD_7_8 USART_CR3_RXFTCFG_2 /*!< RX FIFO reaches 7/8 of its depth */
#define UART_RXFIFO_THRESHOLD_8_8 (USART_CR3_RXFTCFG_2|USART_CR3_RXFTCFG_0) /*!< RX FIFO becomes full */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup UARTEx_Exported_Functions
* @{
*/
/** @addtogroup UARTEx_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions ****************************/
HAL_StatusTypeDef HAL_RS485Ex_Init(UART_HandleTypeDef *huart, uint32_t Polarity, uint32_t AssertionTime,
uint32_t DeassertionTime);
/**
* @}
*/
/** @addtogroup UARTEx_Exported_Functions_Group2
* @{
*/
void HAL_UARTEx_WakeupCallback(UART_HandleTypeDef *huart);
void HAL_UARTEx_RxFifoFullCallback(UART_HandleTypeDef *huart);
void HAL_UARTEx_TxFifoEmptyCallback(UART_HandleTypeDef *huart);
/**
* @}
*/
/** @addtogroup UARTEx_Exported_Functions_Group3
* @{
*/
/* Peripheral Control functions **********************************************/
HAL_StatusTypeDef HAL_UARTEx_StopModeWakeUpSourceConfig(UART_HandleTypeDef *huart, UART_WakeUpTypeDef WakeUpSelection);
HAL_StatusTypeDef HAL_UARTEx_EnableStopMode(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UARTEx_DisableStopMode(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_MultiProcessorEx_AddressLength_Set(UART_HandleTypeDef *huart, uint32_t AddressLength);
HAL_StatusTypeDef HAL_UARTEx_EnableFifoMode(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UARTEx_DisableFifoMode(UART_HandleTypeDef *huart);
HAL_StatusTypeDef HAL_UARTEx_SetTxFifoThreshold(UART_HandleTypeDef *huart, uint32_t Threshold);
HAL_StatusTypeDef HAL_UARTEx_SetRxFifoThreshold(UART_HandleTypeDef *huart, uint32_t Threshold);
HAL_StatusTypeDef HAL_UARTEx_ReceiveToIdle(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size, uint16_t *RxLen,
uint32_t Timeout);
HAL_StatusTypeDef HAL_UARTEx_ReceiveToIdle_IT(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size);
HAL_StatusTypeDef HAL_UARTEx_ReceiveToIdle_DMA(UART_HandleTypeDef *huart, uint8_t *pData, uint16_t Size);
HAL_UART_RxEventTypeTypeDef HAL_UARTEx_GetRxEventType(const UART_HandleTypeDef *huart);
/**
* @}
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup UARTEx_Private_Macros UARTEx Private Macros
* @{
*/
/** @brief Report the UART clock source.
* @param __HANDLE__ specifies the UART Handle.
* @param __CLOCKSOURCE__ output variable.
* @retval UART clocking source, written in __CLOCKSOURCE__.
*/
#if defined(UART5)
#define UART_GETCLOCKSOURCE(__HANDLE__,__CLOCKSOURCE__) \
do { \
if((__HANDLE__)->Instance == USART1) \
{ \
switch(__HAL_RCC_GET_USART1_SOURCE()) \
{ \
case RCC_USART1CLKSOURCE_PCLK2: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK2; \
break; \
case RCC_USART1CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART1CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART1CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == USART2) \
{ \
switch(__HAL_RCC_GET_USART2_SOURCE()) \
{ \
case RCC_USART2CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_USART2CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART2CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART2CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == USART3) \
{ \
switch(__HAL_RCC_GET_USART3_SOURCE()) \
{ \
case RCC_USART3CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_USART3CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART3CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART3CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == UART4) \
{ \
switch(__HAL_RCC_GET_UART4_SOURCE()) \
{ \
case RCC_UART4CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_UART4CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_UART4CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_UART4CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == UART5) \
{ \
switch(__HAL_RCC_GET_UART5_SOURCE()) \
{ \
case RCC_UART5CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_UART5CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_UART5CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_UART5CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == LPUART1) \
{ \
switch(__HAL_RCC_GET_LPUART1_SOURCE()) \
{ \
case RCC_LPUART1CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_LPUART1CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_LPUART1CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_LPUART1CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else \
{ \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
} \
} while(0U)
#elif defined(UART4)
#define UART_GETCLOCKSOURCE(__HANDLE__,__CLOCKSOURCE__) \
do { \
if((__HANDLE__)->Instance == USART1) \
{ \
switch(__HAL_RCC_GET_USART1_SOURCE()) \
{ \
case RCC_USART1CLKSOURCE_PCLK2: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK2; \
break; \
case RCC_USART1CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART1CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART1CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == USART2) \
{ \
switch(__HAL_RCC_GET_USART2_SOURCE()) \
{ \
case RCC_USART2CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_USART2CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART2CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART2CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == USART3) \
{ \
switch(__HAL_RCC_GET_USART3_SOURCE()) \
{ \
case RCC_USART3CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_USART3CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART3CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART3CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == UART4) \
{ \
switch(__HAL_RCC_GET_UART4_SOURCE()) \
{ \
case RCC_UART4CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_UART4CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_UART4CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_UART4CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == LPUART1) \
{ \
switch(__HAL_RCC_GET_LPUART1_SOURCE()) \
{ \
case RCC_LPUART1CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_LPUART1CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_LPUART1CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_LPUART1CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else \
{ \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
} \
} while(0U)
#else
#define UART_GETCLOCKSOURCE(__HANDLE__,__CLOCKSOURCE__) \
do { \
if((__HANDLE__)->Instance == USART1) \
{ \
switch(__HAL_RCC_GET_USART1_SOURCE()) \
{ \
case RCC_USART1CLKSOURCE_PCLK2: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK2; \
break; \
case RCC_USART1CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART1CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART1CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == USART2) \
{ \
switch(__HAL_RCC_GET_USART2_SOURCE()) \
{ \
case RCC_USART2CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_USART2CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART2CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART2CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == USART3) \
{ \
switch(__HAL_RCC_GET_USART3_SOURCE()) \
{ \
case RCC_USART3CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_USART3CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_USART3CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_USART3CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else if((__HANDLE__)->Instance == LPUART1) \
{ \
switch(__HAL_RCC_GET_LPUART1_SOURCE()) \
{ \
case RCC_LPUART1CLKSOURCE_PCLK1: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_PCLK1; \
break; \
case RCC_LPUART1CLKSOURCE_HSI: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_HSI; \
break; \
case RCC_LPUART1CLKSOURCE_SYSCLK: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_SYSCLK; \
break; \
case RCC_LPUART1CLKSOURCE_LSE: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_LSE; \
break; \
default: \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
break; \
} \
} \
else \
{ \
(__CLOCKSOURCE__) = UART_CLOCKSOURCE_UNDEFINED; \
} \
} while(0U)
#endif /* UART5 */
/** @brief Report the UART mask to apply to retrieve the received data
* according to the word length and to the parity bits activation.
* @note If PCE = 1, the parity bit is not included in the data extracted
* by the reception API().
* This masking operation is not carried out in the case of
* DMA transfers.
* @param __HANDLE__ specifies the UART Handle.
* @retval None, the mask to apply to UART RDR register is stored in (__HANDLE__)->Mask field.
*/
#define UART_MASK_COMPUTATION(__HANDLE__) \
do { \
if ((__HANDLE__)->Init.WordLength == UART_WORDLENGTH_9B) \
{ \
if ((__HANDLE__)->Init.Parity == UART_PARITY_NONE) \
{ \
(__HANDLE__)->Mask = 0x01FFU ; \
} \
else \
{ \
(__HANDLE__)->Mask = 0x00FFU ; \
} \
} \
else if ((__HANDLE__)->Init.WordLength == UART_WORDLENGTH_8B) \
{ \
if ((__HANDLE__)->Init.Parity == UART_PARITY_NONE) \
{ \
(__HANDLE__)->Mask = 0x00FFU ; \
} \
else \
{ \
(__HANDLE__)->Mask = 0x007FU ; \
} \
} \
else if ((__HANDLE__)->Init.WordLength == UART_WORDLENGTH_7B) \
{ \
if ((__HANDLE__)->Init.Parity == UART_PARITY_NONE) \
{ \
(__HANDLE__)->Mask = 0x007FU ; \
} \
else \
{ \
(__HANDLE__)->Mask = 0x003FU ; \
} \
} \
else \
{ \
(__HANDLE__)->Mask = 0x0000U; \
} \
} while(0U)
/**
* @brief Ensure that UART frame length is valid.
* @param __LENGTH__ UART frame length.
* @retval SET (__LENGTH__ is valid) or RESET (__LENGTH__ is invalid)
*/
#define IS_UART_WORD_LENGTH(__LENGTH__) (((__LENGTH__) == UART_WORDLENGTH_7B) || \
((__LENGTH__) == UART_WORDLENGTH_8B) || \
((__LENGTH__) == UART_WORDLENGTH_9B))
/**
* @brief Ensure that UART wake-up address length is valid.
* @param __ADDRESS__ UART wake-up address length.
* @retval SET (__ADDRESS__ is valid) or RESET (__ADDRESS__ is invalid)
*/
#define IS_UART_ADDRESSLENGTH_DETECT(__ADDRESS__) (((__ADDRESS__) == UART_ADDRESS_DETECT_4B) || \
((__ADDRESS__) == UART_ADDRESS_DETECT_7B))
/**
* @brief Ensure that UART TXFIFO threshold level is valid.
* @param __THRESHOLD__ UART TXFIFO threshold level.
* @retval SET (__THRESHOLD__ is valid) or RESET (__THRESHOLD__ is invalid)
*/
#define IS_UART_TXFIFO_THRESHOLD(__THRESHOLD__) (((__THRESHOLD__) == UART_TXFIFO_THRESHOLD_1_8) || \
((__THRESHOLD__) == UART_TXFIFO_THRESHOLD_1_4) || \
((__THRESHOLD__) == UART_TXFIFO_THRESHOLD_1_2) || \
((__THRESHOLD__) == UART_TXFIFO_THRESHOLD_3_4) || \
((__THRESHOLD__) == UART_TXFIFO_THRESHOLD_7_8) || \
((__THRESHOLD__) == UART_TXFIFO_THRESHOLD_8_8))
/**
* @brief Ensure that UART RXFIFO threshold level is valid.
* @param __THRESHOLD__ UART RXFIFO threshold level.
* @retval SET (__THRESHOLD__ is valid) or RESET (__THRESHOLD__ is invalid)
*/
#define IS_UART_RXFIFO_THRESHOLD(__THRESHOLD__) (((__THRESHOLD__) == UART_RXFIFO_THRESHOLD_1_8) || \
((__THRESHOLD__) == UART_RXFIFO_THRESHOLD_1_4) || \
((__THRESHOLD__) == UART_RXFIFO_THRESHOLD_1_2) || \
((__THRESHOLD__) == UART_RXFIFO_THRESHOLD_3_4) || \
((__THRESHOLD__) == UART_RXFIFO_THRESHOLD_7_8) || \
((__THRESHOLD__) == UART_RXFIFO_THRESHOLD_8_8))
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_UART_EX_H */
| 34,649 | C | 51.981651 | 119 | 0.33594 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_dma.h | /**
******************************************************************************
* @file stm32g4xx_hal_dma.h
* @author MCD Application Team
* @brief Header file of DMA HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_HAL_DMA_H
#define __STM32G4xx_HAL_DMA_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup DMA
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup DMA_Exported_Types DMA Exported Types
* @{
*/
/**
* @brief DMA Configuration Structure definition
*/
typedef struct
{
uint32_t Request; /*!< Specifies the request selected for the specified channel.
This parameter can be a value of @ref DMA_request */
uint32_t Direction; /*!< Specifies if the data will be transferred from memory to peripheral,
from memory to memory or from peripheral to memory.
This parameter can be a value of @ref DMA_Data_transfer_direction */
uint32_t PeriphInc; /*!< Specifies whether the Peripheral address register should be incremented or not.
This parameter can be a value of @ref DMA_Peripheral_incremented_mode */
uint32_t MemInc; /*!< Specifies whether the memory address register should be incremented or not.
This parameter can be a value of @ref DMA_Memory_incremented_mode */
uint32_t PeriphDataAlignment; /*!< Specifies the Peripheral data width.
This parameter can be a value of @ref DMA_Peripheral_data_size */
uint32_t MemDataAlignment; /*!< Specifies the Memory data width.
This parameter can be a value of @ref DMA_Memory_data_size */
uint32_t Mode; /*!< Specifies the operation mode of the DMAy Channelx.
This parameter can be a value of @ref DMA_mode
@note The circular buffer mode cannot be used if the memory-to-memory
data transfer is configured on the selected Channel */
uint32_t Priority; /*!< Specifies the software priority for the DMAy Channelx.
This parameter can be a value of @ref DMA_Priority_level */
} DMA_InitTypeDef;
/**
* @brief HAL DMA State structures definition
*/
typedef enum
{
HAL_DMA_STATE_RESET = 0x00U, /*!< DMA not yet initialized or disabled */
HAL_DMA_STATE_READY = 0x01U, /*!< DMA initialized and ready for use */
HAL_DMA_STATE_BUSY = 0x02U, /*!< DMA process is ongoing */
HAL_DMA_STATE_TIMEOUT = 0x03U, /*!< DMA timeout state */
} HAL_DMA_StateTypeDef;
/**
* @brief HAL DMA Error Code structure definition
*/
typedef enum
{
HAL_DMA_FULL_TRANSFER = 0x00U, /*!< Full transfer */
HAL_DMA_HALF_TRANSFER = 0x01U /*!< Half Transfer */
} HAL_DMA_LevelCompleteTypeDef;
/**
* @brief HAL DMA Callback ID structure definition
*/
typedef enum
{
HAL_DMA_XFER_CPLT_CB_ID = 0x00U, /*!< Full transfer */
HAL_DMA_XFER_HALFCPLT_CB_ID = 0x01U, /*!< Half transfer */
HAL_DMA_XFER_ERROR_CB_ID = 0x02U, /*!< Error */
HAL_DMA_XFER_ABORT_CB_ID = 0x03U, /*!< Abort */
HAL_DMA_XFER_ALL_CB_ID = 0x04U /*!< All */
} HAL_DMA_CallbackIDTypeDef;
/**
* @brief DMA handle Structure definition
*/
typedef struct __DMA_HandleTypeDef
{
DMA_Channel_TypeDef *Instance; /*!< Register base address */
DMA_InitTypeDef Init; /*!< DMA communication parameters */
HAL_LockTypeDef Lock; /*!< DMA locking object */
__IO HAL_DMA_StateTypeDef State; /*!< DMA transfer state */
void *Parent; /*!< Parent object state */
void (* XferCpltCallback)(struct __DMA_HandleTypeDef *hdma); /*!< DMA transfer complete callback */
void (* XferHalfCpltCallback)(struct __DMA_HandleTypeDef *hdma); /*!< DMA Half transfer complete callback */
void (* XferErrorCallback)(struct __DMA_HandleTypeDef *hdma); /*!< DMA transfer error callback */
void (* XferAbortCallback)(struct __DMA_HandleTypeDef *hdma); /*!< DMA transfer abort callback */
__IO uint32_t ErrorCode; /*!< DMA Error code */
DMA_TypeDef *DmaBaseAddress; /*!< DMA Channel Base Address */
uint32_t ChannelIndex; /*!< DMA Channel Index */
DMAMUX_Channel_TypeDef *DMAmuxChannel; /*!< Register base address */
DMAMUX_ChannelStatus_TypeDef *DMAmuxChannelStatus; /*!< DMAMUX Channels Status Base Address */
uint32_t DMAmuxChannelStatusMask; /*!< DMAMUX Channel Status Mask */
DMAMUX_RequestGen_TypeDef *DMAmuxRequestGen; /*!< DMAMUX request generator Base Address */
DMAMUX_RequestGenStatus_TypeDef *DMAmuxRequestGenStatus; /*!< DMAMUX request generator Address */
uint32_t DMAmuxRequestGenStatusMask; /*!< DMAMUX request generator Status mask */
} DMA_HandleTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup DMA_Exported_Constants DMA Exported Constants
* @{
*/
/** @defgroup DMA_Error_Code DMA Error Code
* @{
*/
#define HAL_DMA_ERROR_NONE 0x00000000U /*!< No error */
#define HAL_DMA_ERROR_TE 0x00000001U /*!< Transfer error */
#define HAL_DMA_ERROR_NO_XFER 0x00000004U /*!< Abort requested with no Xfer ongoing */
#define HAL_DMA_ERROR_TIMEOUT 0x00000020U /*!< Timeout error */
#define HAL_DMA_ERROR_NOT_SUPPORTED 0x00000100U /*!< Not supported mode */
#define HAL_DMA_ERROR_SYNC 0x00000200U /*!< DMAMUX sync overrun error */
#define HAL_DMA_ERROR_REQGEN 0x00000400U /*!< DMAMUX request generator overrun error */
/**
* @}
*/
/** @defgroup DMA_request DMA request
* @{
*/
#define DMA_REQUEST_MEM2MEM 0U /*!< memory to memory transfer */
#define DMA_REQUEST_GENERATOR0 1U
#define DMA_REQUEST_GENERATOR1 2U
#define DMA_REQUEST_GENERATOR2 3U
#define DMA_REQUEST_GENERATOR3 4U
#define DMA_REQUEST_ADC1 5U
#define DMA_REQUEST_DAC1_CHANNEL1 6U
#define DMA_REQUEST_DAC1_CHANNEL2 7U
#define DMA_REQUEST_TIM6_UP 8U
#define DMA_REQUEST_TIM7_UP 9U
#define DMA_REQUEST_SPI1_RX 10U
#define DMA_REQUEST_SPI1_TX 11U
#define DMA_REQUEST_SPI2_RX 12U
#define DMA_REQUEST_SPI2_TX 13U
#define DMA_REQUEST_SPI3_RX 14U
#define DMA_REQUEST_SPI3_TX 15U
#define DMA_REQUEST_I2C1_RX 16U
#define DMA_REQUEST_I2C1_TX 17U
#define DMA_REQUEST_I2C2_RX 18U
#define DMA_REQUEST_I2C2_TX 19U
#define DMA_REQUEST_I2C3_RX 20U
#define DMA_REQUEST_I2C3_TX 21U
#if defined (I2C4)
#define DMA_REQUEST_I2C4_RX 22U
#define DMA_REQUEST_I2C4_TX 23U
#endif /* I2C4 */
#define DMA_REQUEST_USART1_RX 24U
#define DMA_REQUEST_USART1_TX 25U
#define DMA_REQUEST_USART2_RX 26U
#define DMA_REQUEST_USART2_TX 27U
#define DMA_REQUEST_USART3_RX 28U
#define DMA_REQUEST_USART3_TX 29U
#define DMA_REQUEST_UART4_RX 30U
#define DMA_REQUEST_UART4_TX 31U
#if defined (UART5)
#define DMA_REQUEST_UART5_RX 32U
#define DMA_REQUEST_UART5_TX 33U
#endif /* UART5 */
#define DMA_REQUEST_LPUART1_RX 34U
#define DMA_REQUEST_LPUART1_TX 35U
#define DMA_REQUEST_ADC2 36U
#if defined (ADC3)
#define DMA_REQUEST_ADC3 37U
#endif /* ADC3 */
#if defined (ADC4)
#define DMA_REQUEST_ADC4 38U
#endif /* ADC4 */
#if defined (ADC5)
#define DMA_REQUEST_ADC5 39U
#endif /* ADC5 */
#if defined (QUADSPI)
#define DMA_REQUEST_QUADSPI 40U
#endif /* QUADSPI */
#if defined (DAC2)
#define DMA_REQUEST_DAC2_CHANNEL1 41U
#endif /* DAC2 */
#define DMA_REQUEST_TIM1_CH1 42U
#define DMA_REQUEST_TIM1_CH2 43U
#define DMA_REQUEST_TIM1_CH3 44U
#define DMA_REQUEST_TIM1_CH4 45U
#define DMA_REQUEST_TIM1_UP 46U
#define DMA_REQUEST_TIM1_TRIG 47U
#define DMA_REQUEST_TIM1_COM 48U
#define DMA_REQUEST_TIM8_CH1 49U
#define DMA_REQUEST_TIM8_CH2 50U
#define DMA_REQUEST_TIM8_CH3 51U
#define DMA_REQUEST_TIM8_CH4 52U
#define DMA_REQUEST_TIM8_UP 53U
#define DMA_REQUEST_TIM8_TRIG 54U
#define DMA_REQUEST_TIM8_COM 55U
#define DMA_REQUEST_TIM2_CH1 56U
#define DMA_REQUEST_TIM2_CH2 57U
#define DMA_REQUEST_TIM2_CH3 58U
#define DMA_REQUEST_TIM2_CH4 59U
#define DMA_REQUEST_TIM2_UP 60U
#define DMA_REQUEST_TIM3_CH1 61U
#define DMA_REQUEST_TIM3_CH2 62U
#define DMA_REQUEST_TIM3_CH3 63U
#define DMA_REQUEST_TIM3_CH4 64U
#define DMA_REQUEST_TIM3_UP 65U
#define DMA_REQUEST_TIM3_TRIG 66U
#define DMA_REQUEST_TIM4_CH1 67U
#define DMA_REQUEST_TIM4_CH2 68U
#define DMA_REQUEST_TIM4_CH3 69U
#define DMA_REQUEST_TIM4_CH4 70U
#define DMA_REQUEST_TIM4_UP 71U
#if defined (TIM5)
#define DMA_REQUEST_TIM5_CH1 72U
#define DMA_REQUEST_TIM5_CH2 73U
#define DMA_REQUEST_TIM5_CH3 74U
#define DMA_REQUEST_TIM5_CH4 75U
#define DMA_REQUEST_TIM5_UP 76U
#define DMA_REQUEST_TIM5_TRIG 77U
#endif /* TIM5 */
#define DMA_REQUEST_TIM15_CH1 78U
#define DMA_REQUEST_TIM15_UP 79U
#define DMA_REQUEST_TIM15_TRIG 80U
#define DMA_REQUEST_TIM15_COM 81U
#define DMA_REQUEST_TIM16_CH1 82U
#define DMA_REQUEST_TIM16_UP 83U
#define DMA_REQUEST_TIM17_CH1 84U
#define DMA_REQUEST_TIM17_UP 85U
#if defined (TIM20)
#define DMA_REQUEST_TIM20_CH1 86U
#define DMA_REQUEST_TIM20_CH2 87U
#define DMA_REQUEST_TIM20_CH3 88U
#define DMA_REQUEST_TIM20_CH4 89U
#define DMA_REQUEST_TIM20_UP 90U
#endif /* TIM20 */
#define DMA_REQUEST_AES_IN 91U
#define DMA_REQUEST_AES_OUT 92U
#if defined (TIM20)
#define DMA_REQUEST_TIM20_TRIG 93U
#define DMA_REQUEST_TIM20_COM 94U
#endif /* TIM20 */
#if defined (HRTIM1)
#define DMA_REQUEST_HRTIM1_M 95U
#define DMA_REQUEST_HRTIM1_A 96U
#define DMA_REQUEST_HRTIM1_B 97U
#define DMA_REQUEST_HRTIM1_C 98U
#define DMA_REQUEST_HRTIM1_D 99U
#define DMA_REQUEST_HRTIM1_E 100U
#define DMA_REQUEST_HRTIM1_F 101U
#endif /* HRTIM1 */
#define DMA_REQUEST_DAC3_CHANNEL1 102U
#define DMA_REQUEST_DAC3_CHANNEL2 103U
#if defined (DAC4)
#define DMA_REQUEST_DAC4_CHANNEL1 104U
#define DMA_REQUEST_DAC4_CHANNEL2 105U
#endif /* DAC4 */
#if defined (SPI4)
#define DMA_REQUEST_SPI4_RX 106U
#define DMA_REQUEST_SPI4_TX 107U
#endif /* SPI4 */
#define DMA_REQUEST_SAI1_A 108U
#define DMA_REQUEST_SAI1_B 109U
#define DMA_REQUEST_FMAC_READ 110U
#define DMA_REQUEST_FMAC_WRITE 111U
#define DMA_REQUEST_CORDIC_READ 112U
#define DMA_REQUEST_CORDIC_WRITE 113U
#define DMA_REQUEST_UCPD1_RX 114U
#define DMA_REQUEST_UCPD1_TX 115U
/**
* @}
*/
/** @defgroup DMA_Data_transfer_direction DMA Data transfer direction
* @{
*/
#define DMA_PERIPH_TO_MEMORY 0x00000000U /*!< Peripheral to memory direction */
#define DMA_MEMORY_TO_PERIPH DMA_CCR_DIR /*!< Memory to peripheral direction */
#define DMA_MEMORY_TO_MEMORY DMA_CCR_MEM2MEM /*!< Memory to memory direction */
/**
* @}
*/
/** @defgroup DMA_Peripheral_incremented_mode DMA Peripheral incremented mode
* @{
*/
#define DMA_PINC_ENABLE DMA_CCR_PINC /*!< Peripheral increment mode Enable */
#define DMA_PINC_DISABLE 0x00000000U /*!< Peripheral increment mode Disable */
/**
* @}
*/
/** @defgroup DMA_Memory_incremented_mode DMA Memory incremented mode
* @{
*/
#define DMA_MINC_ENABLE DMA_CCR_MINC /*!< Memory increment mode Enable */
#define DMA_MINC_DISABLE 0x00000000U /*!< Memory increment mode Disable */
/**
* @}
*/
/** @defgroup DMA_Peripheral_data_size DMA Peripheral data size
* @{
*/
#define DMA_PDATAALIGN_BYTE 0x00000000U /*!< Peripheral data alignment : Byte */
#define DMA_PDATAALIGN_HALFWORD DMA_CCR_PSIZE_0 /*!< Peripheral data alignment : HalfWord */
#define DMA_PDATAALIGN_WORD DMA_CCR_PSIZE_1 /*!< Peripheral data alignment : Word */
/**
* @}
*/
/** @defgroup DMA_Memory_data_size DMA Memory data size
* @{
*/
#define DMA_MDATAALIGN_BYTE 0x00000000U /*!< Memory data alignment : Byte */
#define DMA_MDATAALIGN_HALFWORD DMA_CCR_MSIZE_0 /*!< Memory data alignment : HalfWord */
#define DMA_MDATAALIGN_WORD DMA_CCR_MSIZE_1 /*!< Memory data alignment : Word */
/**
* @}
*/
/** @defgroup DMA_mode DMA mode
* @{
*/
#define DMA_NORMAL 0x00000000U /*!< Normal mode */
#define DMA_CIRCULAR DMA_CCR_CIRC /*!< Circular mode */
/**
* @}
*/
/** @defgroup DMA_Priority_level DMA Priority level
* @{
*/
#define DMA_PRIORITY_LOW 0x00000000U /*!< Priority level : Low */
#define DMA_PRIORITY_MEDIUM DMA_CCR_PL_0 /*!< Priority level : Medium */
#define DMA_PRIORITY_HIGH DMA_CCR_PL_1 /*!< Priority level : High */
#define DMA_PRIORITY_VERY_HIGH DMA_CCR_PL /*!< Priority level : Very_High */
/**
* @}
*/
/** @defgroup DMA_interrupt_enable_definitions DMA interrupt enable definitions
* @{
*/
#define DMA_IT_TC DMA_CCR_TCIE
#define DMA_IT_HT DMA_CCR_HTIE
#define DMA_IT_TE DMA_CCR_TEIE
/**
* @}
*/
/** @defgroup DMA_flag_definitions DMA flag definitions
* @{
*/
#define DMA_FLAG_GL1 0x00000001U
#define DMA_FLAG_TC1 0x00000002U
#define DMA_FLAG_HT1 0x00000004U
#define DMA_FLAG_TE1 0x00000008U
#define DMA_FLAG_GL2 0x00000010U
#define DMA_FLAG_TC2 0x00000020U
#define DMA_FLAG_HT2 0x00000040U
#define DMA_FLAG_TE2 0x00000080U
#define DMA_FLAG_GL3 0x00000100U
#define DMA_FLAG_TC3 0x00000200U
#define DMA_FLAG_HT3 0x00000400U
#define DMA_FLAG_TE3 0x00000800U
#define DMA_FLAG_GL4 0x00001000U
#define DMA_FLAG_TC4 0x00002000U
#define DMA_FLAG_HT4 0x00004000U
#define DMA_FLAG_TE4 0x00008000U
#define DMA_FLAG_GL5 0x00010000U
#define DMA_FLAG_TC5 0x00020000U
#define DMA_FLAG_HT5 0x00040000U
#define DMA_FLAG_TE5 0x00080000U
#define DMA_FLAG_GL6 0x00100000U
#define DMA_FLAG_TC6 0x00200000U
#define DMA_FLAG_HT6 0x00400000U
#define DMA_FLAG_TE6 0x00800000U
#if defined (DMA1_Channel7)
#define DMA_FLAG_GL7 0x01000000U
#define DMA_FLAG_TC7 0x02000000U
#define DMA_FLAG_HT7 0x04000000U
#define DMA_FLAG_TE7 0x08000000U
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
#define DMA_FLAG_GL8 0x10000000U
#define DMA_FLAG_TC8 0x20000000U
#define DMA_FLAG_HT8 0x40000000U
#define DMA_FLAG_TE8 0x80000000U
#endif /* DMA1_Channel8 */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup DMA_Exported_Macros DMA Exported Macros
* @{
*/
/** @brief Reset DMA handle state.
* @param __HANDLE__ DMA handle
* @retval None
*/
#define __HAL_DMA_RESET_HANDLE_STATE(__HANDLE__) ((__HANDLE__)->State = HAL_DMA_STATE_RESET)
/**
* @brief Enable the specified DMA Channel.
* @param __HANDLE__ DMA handle
* @retval None
*/
#define __HAL_DMA_ENABLE(__HANDLE__) ((__HANDLE__)->Instance->CCR |= DMA_CCR_EN)
/**
* @brief Disable the specified DMA Channel.
* @param __HANDLE__ DMA handle
* @retval None
*/
#define __HAL_DMA_DISABLE(__HANDLE__) ((__HANDLE__)->Instance->CCR &= ~DMA_CCR_EN)
/* Interrupt & Flag management */
/**
* @brief Return the current DMA Channel transfer complete flag.
* @param __HANDLE__ DMA handle
* @retval The specified transfer complete flag index.
*/
#if defined (DMA1_Channel8)
#define __HAL_DMA_GET_TC_FLAG_INDEX(__HANDLE__) \
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TC1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_TC1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TC2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_TC2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TC3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_TC3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TC4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_TC4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TC5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_FLAG_TC5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_TC6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel6))? DMA_FLAG_TC6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_FLAG_TC7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel7))? DMA_FLAG_TC7 :\
DMA_FLAG_TC8)
#elif defined (DMA1_Channel6)
#define __HAL_DMA_GET_TC_FLAG_INDEX(__HANDLE__) \
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TC1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_TC1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TC2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_TC2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TC3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_TC3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TC4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_TC4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TC5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_FLAG_TC5 :\
DMA_FLAG_TC6)
#endif /* DMA1_Channel8 */
/**
* @brief Return the current DMA Channel half transfer complete flag.
* @param __HANDLE__ DMA handle
* @retval The specified half transfer complete flag index.
*/
#if defined (DMA1_Channel8)
#define __HAL_DMA_GET_HT_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_HT1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_HT1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_HT2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_HT2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_HT3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_HT3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_HT4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_HT4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_HT5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_FLAG_HT5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_HT6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel6))? DMA_FLAG_HT6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_FLAG_HT7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel7))? DMA_FLAG_HT7 :\
DMA_FLAG_HT8)
#elif defined (DMA1_Channel6)
#define __HAL_DMA_GET_HT_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_HT1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_HT1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_HT2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_HT2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_HT3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_HT3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_HT4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_HT4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_HT5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_FLAG_HT5 :\
DMA_FLAG_HT6)
#endif /* DMA1_Channel8 */
/**
* @brief Return the current DMA Channel transfer error flag.
* @param __HANDLE__ DMA handle
* @retval The specified transfer error flag index.
*/
#if defined (DMA1_Channel8)
#define __HAL_DMA_GET_TE_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TE1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_TE1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TE2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_TE2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TE3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_TE3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TE4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_TE4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TE5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_FLAG_TE5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_FLAG_TE6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel6))? DMA_FLAG_TE6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_FLAG_TE7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel7))? DMA_FLAG_TE7 :\
DMA_FLAG_TE8)
#elif defined (DMA1_Channel6)
#define __HAL_DMA_GET_TE_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_FLAG_TE1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_FLAG_TE1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_FLAG_TE2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_FLAG_TE2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_FLAG_TE3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_FLAG_TE3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_FLAG_TE4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_FLAG_TE4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_FLAG_TE5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_FLAG_TE5 :\
DMA_FLAG_TE6)
#endif /* DMA1_Channel8 */
/**
* @brief Return the current DMA Channel Global interrupt flag.
* @param __HANDLE__ DMA handle
* @retval The specified transfer error flag index.
*/
#if defined (DMA1_Channel8)
#define __HAL_DMA_GET_GI_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_ISR_GIF1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_ISR_GIF1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_ISR_GIF2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_ISR_GIF2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_ISR_GIF3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_ISR_GIF3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_ISR_GIF4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_ISR_GIF4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_ISR_GIF5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_ISR_GIF5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel6))? DMA_ISR_GIF6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel6))? DMA_ISR_GIF6 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel7))? DMA_ISR_GIF7 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel7))? DMA_ISR_GIF7 :\
DMA_ISR_GIF8)
#elif defined (DMA1_Channel6)
#define __HAL_DMA_GET_GI_FLAG_INDEX(__HANDLE__)\
(((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel1))? DMA_ISR_GIF1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel1))? DMA_ISR_GIF1 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel2))? DMA_ISR_GIF2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel2))? DMA_ISR_GIF2 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel3))? DMA_ISR_GIF3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel3))? DMA_ISR_GIF3 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel4))? DMA_ISR_GIF4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel4))? DMA_ISR_GIF4 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA1_Channel5))? DMA_ISR_GIF5 :\
((uint32_t)((__HANDLE__)->Instance) == ((uint32_t)DMA2_Channel5))? DMA_ISR_GIF5 :\
DMA_ISR_GIF6)
#endif /* DMA1_Channel8 */
/**
* @brief Get the DMA Channel pending flags.
* @param __HANDLE__ DMA handle
* @param __FLAG__ Get the specified flag.
* This parameter can be any combination of the following values:
* @arg DMA_FLAG_TCx Transfer complete flag
* @arg DMA_FLAG_HTx Half transfer complete flag
* @arg DMA_FLAG_TEx Transfer error flag
* @arg DMA_FLAG_GLx Global interrupt flag
* Where x can be from 1 to 8 to select the DMA Channel x flag.
* @retval The state of FLAG (SET or RESET).
*/
#if defined (DMA1_Channel8)
#define __HAL_DMA_GET_FLAG(__HANDLE__, __FLAG__) (((uint32_t)((__HANDLE__)->Instance) > ((uint32_t)DMA1_Channel8))? \
(DMA2->ISR & (__FLAG__)) : (DMA1->ISR & (__FLAG__)))
#elif defined (DMA1_Channel6)
#define __HAL_DMA_GET_FLAG(__HANDLE__, __FLAG__) (((uint32_t)((__HANDLE__)->Instance) > ((uint32_t)DMA1_Channel6))? \
(DMA2->ISR & (__FLAG__)) : (DMA1->ISR & (__FLAG__)))
#endif /* DMA1_Channel8 */
/**
* @brief Clear the DMA Channel pending flags.
* @param __HANDLE__ DMA handle
* @param __FLAG__ specifies the flag to clear.
* This parameter can be any combination of the following values:
* @arg DMA_FLAG_TCx Transfer complete flag
* @arg DMA_FLAG_HTx Half transfer complete flag
* @arg DMA_FLAG_TEx Transfer error flag
* @arg DMA_FLAG_GLx Global interrupt flag
* Where x can be from 1 to 8 to select the DMA Channel x flag.
* @retval None
*/
#if defined (DMA1_Channel8)
#define __HAL_DMA_CLEAR_FLAG(__HANDLE__, __FLAG__) (((uint32_t)((__HANDLE__)->Instance) > ((uint32_t)DMA1_Channel8))? \
(DMA2->IFCR = (__FLAG__)) : (DMA1->IFCR = (__FLAG__)))
#else
#define __HAL_DMA_CLEAR_FLAG(__HANDLE__, __FLAG__) (((uint32_t)((__HANDLE__)->Instance) > ((uint32_t)DMA1_Channel6))? \
(DMA2->IFCR = (__FLAG__)) : (DMA1->IFCR = (__FLAG__)))
#endif /* DMA1_Channel8 */
/**
* @brief Enable the specified DMA Channel interrupts.
* @param __HANDLE__ DMA handle
* @param __INTERRUPT__ specifies the DMA interrupt sources to be enabled or disabled.
* This parameter can be any combination of the following values:
* @arg DMA_IT_TC Transfer complete interrupt mask
* @arg DMA_IT_HT Half transfer complete interrupt mask
* @arg DMA_IT_TE Transfer error interrupt mask
* @retval None
*/
#define __HAL_DMA_ENABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->CCR |= (__INTERRUPT__))
/**
* @brief Disable the specified DMA Channel interrupts.
* @param __HANDLE__ DMA handle
* @param __INTERRUPT__ specifies the DMA interrupt sources to be enabled or disabled.
* This parameter can be any combination of the following values:
* @arg DMA_IT_TC Transfer complete interrupt mask
* @arg DMA_IT_HT Half transfer complete interrupt mask
* @arg DMA_IT_TE Transfer error interrupt mask
* @retval None
*/
#define __HAL_DMA_DISABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->CCR &= ~(__INTERRUPT__))
/**
* @brief Check whether the specified DMA Channel interrupt is enabled or not.
* @param __HANDLE__ DMA handle
* @param __INTERRUPT__ specifies the DMA interrupt source to check.
* This parameter can be one of the following values:
* @arg DMA_IT_TC Transfer complete interrupt mask
* @arg DMA_IT_HT Half transfer complete interrupt mask
* @arg DMA_IT_TE Transfer error interrupt mask
* @retval The state of DMA_IT (SET or RESET).
*/
#define __HAL_DMA_GET_IT_SOURCE(__HANDLE__, __INTERRUPT__) (((__HANDLE__)->Instance->CCR & (__INTERRUPT__)))
/**
* @brief Return the number of remaining data units in the current DMA Channel transfer.
* @param __HANDLE__ DMA handle
* @retval The number of remaining data units in the current DMA Channel transfer.
*/
#define __HAL_DMA_GET_COUNTER(__HANDLE__) ((__HANDLE__)->Instance->CNDTR)
/**
* @}
*/
/* Include DMA HAL Extension module */
#include "stm32g4xx_hal_dma_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup DMA_Exported_Functions
* @{
*/
/** @addtogroup DMA_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions *****************************/
HAL_StatusTypeDef HAL_DMA_Init(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_DeInit(DMA_HandleTypeDef *hdma);
/**
* @}
*/
/** @addtogroup DMA_Exported_Functions_Group2
* @{
*/
/* IO operation functions *****************************************************/
HAL_StatusTypeDef HAL_DMA_Start(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress, uint32_t DataLength);
HAL_StatusTypeDef HAL_DMA_Start_IT(DMA_HandleTypeDef *hdma, uint32_t SrcAddress, uint32_t DstAddress,
uint32_t DataLength);
HAL_StatusTypeDef HAL_DMA_Abort(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_Abort_IT(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_PollForTransfer(DMA_HandleTypeDef *hdma, HAL_DMA_LevelCompleteTypeDef CompleteLevel,
uint32_t Timeout);
void HAL_DMA_IRQHandler(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMA_RegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID, void (* pCallback)(DMA_HandleTypeDef *_hdma));
HAL_StatusTypeDef HAL_DMA_UnRegisterCallback(DMA_HandleTypeDef *hdma, HAL_DMA_CallbackIDTypeDef CallbackID);
/**
* @}
*/
/** @addtogroup DMA_Exported_Functions_Group3
* @{
*/
/* Peripheral State and Error functions ***************************************/
HAL_DMA_StateTypeDef HAL_DMA_GetState(DMA_HandleTypeDef *hdma);
uint32_t HAL_DMA_GetError(DMA_HandleTypeDef *hdma);
/**
* @}
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup DMA_Private_Macros DMA Private Macros
* @{
*/
#define IS_DMA_DIRECTION(DIRECTION) (((DIRECTION) == DMA_PERIPH_TO_MEMORY ) || \
((DIRECTION) == DMA_MEMORY_TO_PERIPH) || \
((DIRECTION) == DMA_MEMORY_TO_MEMORY))
#define IS_DMA_BUFFER_SIZE(SIZE) (((SIZE) >= 0x1U) && ((SIZE) < 0x40000U))
#define IS_DMA_PERIPHERAL_INC_STATE(STATE) (((STATE) == DMA_PINC_ENABLE) || \
((STATE) == DMA_PINC_DISABLE))
#define IS_DMA_MEMORY_INC_STATE(STATE) (((STATE) == DMA_MINC_ENABLE) || \
((STATE) == DMA_MINC_DISABLE))
#define IS_DMA_ALL_REQUEST(REQUEST) ((REQUEST) <= DMA_REQUEST_UCPD1_TX)
#define IS_DMA_PERIPHERAL_DATA_SIZE(SIZE) (((SIZE) == DMA_PDATAALIGN_BYTE) || \
((SIZE) == DMA_PDATAALIGN_HALFWORD) || \
((SIZE) == DMA_PDATAALIGN_WORD))
#define IS_DMA_MEMORY_DATA_SIZE(SIZE) (((SIZE) == DMA_MDATAALIGN_BYTE) || \
((SIZE) == DMA_MDATAALIGN_HALFWORD) || \
((SIZE) == DMA_MDATAALIGN_WORD ))
#define IS_DMA_MODE(MODE) (((MODE) == DMA_NORMAL ) || \
((MODE) == DMA_CIRCULAR))
#define IS_DMA_PRIORITY(PRIORITY) (((PRIORITY) == DMA_PRIORITY_LOW ) || \
((PRIORITY) == DMA_PRIORITY_MEDIUM) || \
((PRIORITY) == DMA_PRIORITY_HIGH) || \
((PRIORITY) == DMA_PRIORITY_VERY_HIGH))
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_HAL_DMA_H */
| 36,647 | C | 41.963658 | 152 | 0.556417 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_cortex.h | /**
******************************************************************************
* @file stm32g4xx_hal_cortex.h
* @author MCD Application Team
* @brief Header file of CORTEX HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_HAL_CORTEX_H
#define __STM32G4xx_HAL_CORTEX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup CORTEX CORTEX
* @brief CORTEX HAL module driver
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup CORTEX_Exported_Types CORTEX Exported Types
* @{
*/
#if (__MPU_PRESENT == 1)
/** @defgroup CORTEX_MPU_Region_Initialization_Structure_definition MPU Region Initialization Structure Definition
* @brief MPU Region initialization structure
* @{
*/
typedef struct
{
uint8_t Enable; /*!< Specifies the status of the region.
This parameter can be a value of @ref CORTEX_MPU_Region_Enable */
uint8_t Number; /*!< Specifies the number of the region to protect.
This parameter can be a value of @ref CORTEX_MPU_Region_Number */
uint32_t BaseAddress; /*!< Specifies the base address of the region to protect. */
uint8_t Size; /*!< Specifies the size of the region to protect.
This parameter can be a value of @ref CORTEX_MPU_Region_Size */
uint8_t SubRegionDisable; /*!< Specifies the number of the subregion protection to disable.
This parameter must be a number between Min_Data = 0x00 and Max_Data = 0xFF */
uint8_t TypeExtField; /*!< Specifies the TEX field level.
This parameter can be a value of @ref CORTEX_MPU_TEX_Levels */
uint8_t AccessPermission; /*!< Specifies the region access permission type.
This parameter can be a value of @ref CORTEX_MPU_Region_Permission_Attributes */
uint8_t DisableExec; /*!< Specifies the instruction access status.
This parameter can be a value of @ref CORTEX_MPU_Instruction_Access */
uint8_t IsShareable; /*!< Specifies the shareability status of the protected region.
This parameter can be a value of @ref CORTEX_MPU_Access_Shareable */
uint8_t IsCacheable; /*!< Specifies the cacheable status of the region protected.
This parameter can be a value of @ref CORTEX_MPU_Access_Cacheable */
uint8_t IsBufferable; /*!< Specifies the bufferable status of the protected region.
This parameter can be a value of @ref CORTEX_MPU_Access_Bufferable */
}MPU_Region_InitTypeDef;
/**
* @}
*/
#endif /* __MPU_PRESENT */
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup CORTEX_Exported_Constants CORTEX Exported Constants
* @{
*/
/** @defgroup CORTEX_Preemption_Priority_Group CORTEX Preemption Priority Group
* @{
*/
#define NVIC_PRIORITYGROUP_0 0x00000007U /*!< 0 bit for pre-emption priority,
4 bits for subpriority */
#define NVIC_PRIORITYGROUP_1 0x00000006U /*!< 1 bit for pre-emption priority,
3 bits for subpriority */
#define NVIC_PRIORITYGROUP_2 0x00000005U /*!< 2 bits for pre-emption priority,
2 bits for subpriority */
#define NVIC_PRIORITYGROUP_3 0x00000004U /*!< 3 bits for pre-emption priority,
1 bit for subpriority */
#define NVIC_PRIORITYGROUP_4 0x00000003U /*!< 4 bits for pre-emption priority,
0 bit for subpriority */
/**
* @}
*/
/** @defgroup CORTEX_SysTick_clock_source CORTEX SysTick clock source
* @{
*/
#define SYSTICK_CLKSOURCE_HCLK_DIV8 0x00000000U
#define SYSTICK_CLKSOURCE_HCLK 0x00000004U
/**
* @}
*/
#if (__MPU_PRESENT == 1)
/** @defgroup CORTEX_MPU_HFNMI_PRIVDEF_Control CORTEX MPU HFNMI and PRIVILEGED Access control
* @{
*/
#define MPU_HFNMI_PRIVDEF_NONE 0x00000000U
#define MPU_HARDFAULT_NMI (MPU_CTRL_HFNMIENA_Msk)
#define MPU_PRIVILEGED_DEFAULT (MPU_CTRL_PRIVDEFENA_Msk)
#define MPU_HFNMI_PRIVDEF (MPU_CTRL_HFNMIENA_Msk | MPU_CTRL_PRIVDEFENA_Msk)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Enable CORTEX MPU Region Enable
* @{
*/
#define MPU_REGION_ENABLE ((uint8_t)0x01)
#define MPU_REGION_DISABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Instruction_Access CORTEX MPU Instruction Access
* @{
*/
#define MPU_INSTRUCTION_ACCESS_ENABLE ((uint8_t)0x00)
#define MPU_INSTRUCTION_ACCESS_DISABLE ((uint8_t)0x01)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Access_Shareable CORTEX MPU Instruction Access Shareable
* @{
*/
#define MPU_ACCESS_SHAREABLE ((uint8_t)0x01)
#define MPU_ACCESS_NOT_SHAREABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Access_Cacheable CORTEX MPU Instruction Access Cacheable
* @{
*/
#define MPU_ACCESS_CACHEABLE ((uint8_t)0x01)
#define MPU_ACCESS_NOT_CACHEABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Access_Bufferable CORTEX MPU Instruction Access Bufferable
* @{
*/
#define MPU_ACCESS_BUFFERABLE ((uint8_t)0x01)
#define MPU_ACCESS_NOT_BUFFERABLE ((uint8_t)0x00)
/**
* @}
*/
/** @defgroup CORTEX_MPU_TEX_Levels CORTEX MPU TEX Levels
* @{
*/
#define MPU_TEX_LEVEL0 ((uint8_t)0x00)
#define MPU_TEX_LEVEL1 ((uint8_t)0x01)
#define MPU_TEX_LEVEL2 ((uint8_t)0x02)
#define MPU_TEX_LEVEL4 ((uint8_t)0x04)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Size CORTEX MPU Region Size
* @{
*/
#define MPU_REGION_SIZE_32B ((uint8_t)0x04)
#define MPU_REGION_SIZE_64B ((uint8_t)0x05)
#define MPU_REGION_SIZE_128B ((uint8_t)0x06)
#define MPU_REGION_SIZE_256B ((uint8_t)0x07)
#define MPU_REGION_SIZE_512B ((uint8_t)0x08)
#define MPU_REGION_SIZE_1KB ((uint8_t)0x09)
#define MPU_REGION_SIZE_2KB ((uint8_t)0x0A)
#define MPU_REGION_SIZE_4KB ((uint8_t)0x0B)
#define MPU_REGION_SIZE_8KB ((uint8_t)0x0C)
#define MPU_REGION_SIZE_16KB ((uint8_t)0x0D)
#define MPU_REGION_SIZE_32KB ((uint8_t)0x0E)
#define MPU_REGION_SIZE_64KB ((uint8_t)0x0F)
#define MPU_REGION_SIZE_128KB ((uint8_t)0x10)
#define MPU_REGION_SIZE_256KB ((uint8_t)0x11)
#define MPU_REGION_SIZE_512KB ((uint8_t)0x12)
#define MPU_REGION_SIZE_1MB ((uint8_t)0x13)
#define MPU_REGION_SIZE_2MB ((uint8_t)0x14)
#define MPU_REGION_SIZE_4MB ((uint8_t)0x15)
#define MPU_REGION_SIZE_8MB ((uint8_t)0x16)
#define MPU_REGION_SIZE_16MB ((uint8_t)0x17)
#define MPU_REGION_SIZE_32MB ((uint8_t)0x18)
#define MPU_REGION_SIZE_64MB ((uint8_t)0x19)
#define MPU_REGION_SIZE_128MB ((uint8_t)0x1A)
#define MPU_REGION_SIZE_256MB ((uint8_t)0x1B)
#define MPU_REGION_SIZE_512MB ((uint8_t)0x1C)
#define MPU_REGION_SIZE_1GB ((uint8_t)0x1D)
#define MPU_REGION_SIZE_2GB ((uint8_t)0x1E)
#define MPU_REGION_SIZE_4GB ((uint8_t)0x1F)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Permission_Attributes CORTEX MPU Region Permission Attributes
* @{
*/
#define MPU_REGION_NO_ACCESS ((uint8_t)0x00)
#define MPU_REGION_PRIV_RW ((uint8_t)0x01)
#define MPU_REGION_PRIV_RW_URO ((uint8_t)0x02)
#define MPU_REGION_FULL_ACCESS ((uint8_t)0x03)
#define MPU_REGION_PRIV_RO ((uint8_t)0x05)
#define MPU_REGION_PRIV_RO_URO ((uint8_t)0x06)
/**
* @}
*/
/** @defgroup CORTEX_MPU_Region_Number CORTEX MPU Region Number
* @{
*/
#define MPU_REGION_NUMBER0 ((uint8_t)0x00)
#define MPU_REGION_NUMBER1 ((uint8_t)0x01)
#define MPU_REGION_NUMBER2 ((uint8_t)0x02)
#define MPU_REGION_NUMBER3 ((uint8_t)0x03)
#define MPU_REGION_NUMBER4 ((uint8_t)0x04)
#define MPU_REGION_NUMBER5 ((uint8_t)0x05)
#define MPU_REGION_NUMBER6 ((uint8_t)0x06)
#define MPU_REGION_NUMBER7 ((uint8_t)0x07)
/**
* @}
*/
#endif /* __MPU_PRESENT */
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup CORTEX_Exported_Macros CORTEX Exported Macros
* @{
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup CORTEX_Exported_Functions CORTEX Exported Functions
* @{
*/
/** @defgroup CORTEX_Exported_Functions_Group1 Initialization and Configuration functions
* @brief Initialization and Configuration functions
* @{
*/
/* Initialization and Configuration functions *****************************/
void HAL_NVIC_SetPriorityGrouping(uint32_t PriorityGroup);
void HAL_NVIC_SetPriority(IRQn_Type IRQn, uint32_t PreemptPriority, uint32_t SubPriority);
void HAL_NVIC_EnableIRQ(IRQn_Type IRQn);
void HAL_NVIC_DisableIRQ(IRQn_Type IRQn);
void HAL_NVIC_SystemReset(void);
uint32_t HAL_SYSTICK_Config(uint32_t TicksNumb);
/**
* @}
*/
/** @defgroup CORTEX_Exported_Functions_Group2 Peripheral Control functions
* @brief Cortex control functions
* @{
*/
/* Peripheral Control functions ***********************************************/
uint32_t HAL_NVIC_GetPriorityGrouping(void);
void HAL_NVIC_GetPriority(IRQn_Type IRQn, uint32_t PriorityGroup, uint32_t* pPreemptPriority, uint32_t* pSubPriority);
uint32_t HAL_NVIC_GetPendingIRQ(IRQn_Type IRQn);
void HAL_NVIC_SetPendingIRQ(IRQn_Type IRQn);
void HAL_NVIC_ClearPendingIRQ(IRQn_Type IRQn);
uint32_t HAL_NVIC_GetActive(IRQn_Type IRQn);
void HAL_SYSTICK_CLKSourceConfig(uint32_t CLKSource);
void HAL_SYSTICK_IRQHandler(void);
void HAL_SYSTICK_Callback(void);
#if (__MPU_PRESENT == 1)
void HAL_MPU_Enable(uint32_t MPU_Control);
void HAL_MPU_Disable(void);
void HAL_MPU_ConfigRegion(MPU_Region_InitTypeDef *MPU_Init);
#endif /* __MPU_PRESENT */
/**
* @}
*/
/**
* @}
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup CORTEX_Private_Macros CORTEX Private Macros
* @{
*/
#define IS_NVIC_PRIORITY_GROUP(GROUP) (((GROUP) == NVIC_PRIORITYGROUP_0) || \
((GROUP) == NVIC_PRIORITYGROUP_1) || \
((GROUP) == NVIC_PRIORITYGROUP_2) || \
((GROUP) == NVIC_PRIORITYGROUP_3) || \
((GROUP) == NVIC_PRIORITYGROUP_4))
#define IS_NVIC_PREEMPTION_PRIORITY(PRIORITY) ((PRIORITY) < 0x10U)
#define IS_NVIC_SUB_PRIORITY(PRIORITY) ((PRIORITY) < 0x10U)
#define IS_NVIC_DEVICE_IRQ(IRQ) ((IRQ) > SysTick_IRQn)
#define IS_SYSTICK_CLK_SOURCE(SOURCE) (((SOURCE) == SYSTICK_CLKSOURCE_HCLK) || \
((SOURCE) == SYSTICK_CLKSOURCE_HCLK_DIV8))
#if (__MPU_PRESENT == 1)
#define IS_MPU_REGION_ENABLE(STATE) (((STATE) == MPU_REGION_ENABLE) || \
((STATE) == MPU_REGION_DISABLE))
#define IS_MPU_INSTRUCTION_ACCESS(STATE) (((STATE) == MPU_INSTRUCTION_ACCESS_ENABLE) || \
((STATE) == MPU_INSTRUCTION_ACCESS_DISABLE))
#define IS_MPU_ACCESS_SHAREABLE(STATE) (((STATE) == MPU_ACCESS_SHAREABLE) || \
((STATE) == MPU_ACCESS_NOT_SHAREABLE))
#define IS_MPU_ACCESS_CACHEABLE(STATE) (((STATE) == MPU_ACCESS_CACHEABLE) || \
((STATE) == MPU_ACCESS_NOT_CACHEABLE))
#define IS_MPU_ACCESS_BUFFERABLE(STATE) (((STATE) == MPU_ACCESS_BUFFERABLE) || \
((STATE) == MPU_ACCESS_NOT_BUFFERABLE))
#define IS_MPU_TEX_LEVEL(TYPE) (((TYPE) == MPU_TEX_LEVEL0) || \
((TYPE) == MPU_TEX_LEVEL1) || \
((TYPE) == MPU_TEX_LEVEL2) || \
((TYPE) == MPU_TEX_LEVEL4))
#define IS_MPU_REGION_PERMISSION_ATTRIBUTE(TYPE) (((TYPE) == MPU_REGION_NO_ACCESS) || \
((TYPE) == MPU_REGION_PRIV_RW) || \
((TYPE) == MPU_REGION_PRIV_RW_URO) || \
((TYPE) == MPU_REGION_FULL_ACCESS) || \
((TYPE) == MPU_REGION_PRIV_RO) || \
((TYPE) == MPU_REGION_PRIV_RO_URO))
#define IS_MPU_REGION_NUMBER(NUMBER) (((NUMBER) == MPU_REGION_NUMBER0) || \
((NUMBER) == MPU_REGION_NUMBER1) || \
((NUMBER) == MPU_REGION_NUMBER2) || \
((NUMBER) == MPU_REGION_NUMBER3) || \
((NUMBER) == MPU_REGION_NUMBER4) || \
((NUMBER) == MPU_REGION_NUMBER5) || \
((NUMBER) == MPU_REGION_NUMBER6) || \
((NUMBER) == MPU_REGION_NUMBER7))
#define IS_MPU_REGION_SIZE(SIZE) (((SIZE) == MPU_REGION_SIZE_32B) || \
((SIZE) == MPU_REGION_SIZE_64B) || \
((SIZE) == MPU_REGION_SIZE_128B) || \
((SIZE) == MPU_REGION_SIZE_256B) || \
((SIZE) == MPU_REGION_SIZE_512B) || \
((SIZE) == MPU_REGION_SIZE_1KB) || \
((SIZE) == MPU_REGION_SIZE_2KB) || \
((SIZE) == MPU_REGION_SIZE_4KB) || \
((SIZE) == MPU_REGION_SIZE_8KB) || \
((SIZE) == MPU_REGION_SIZE_16KB) || \
((SIZE) == MPU_REGION_SIZE_32KB) || \
((SIZE) == MPU_REGION_SIZE_64KB) || \
((SIZE) == MPU_REGION_SIZE_128KB) || \
((SIZE) == MPU_REGION_SIZE_256KB) || \
((SIZE) == MPU_REGION_SIZE_512KB) || \
((SIZE) == MPU_REGION_SIZE_1MB) || \
((SIZE) == MPU_REGION_SIZE_2MB) || \
((SIZE) == MPU_REGION_SIZE_4MB) || \
((SIZE) == MPU_REGION_SIZE_8MB) || \
((SIZE) == MPU_REGION_SIZE_16MB) || \
((SIZE) == MPU_REGION_SIZE_32MB) || \
((SIZE) == MPU_REGION_SIZE_64MB) || \
((SIZE) == MPU_REGION_SIZE_128MB) || \
((SIZE) == MPU_REGION_SIZE_256MB) || \
((SIZE) == MPU_REGION_SIZE_512MB) || \
((SIZE) == MPU_REGION_SIZE_1GB) || \
((SIZE) == MPU_REGION_SIZE_2GB) || \
((SIZE) == MPU_REGION_SIZE_4GB))
#define IS_MPU_SUB_REGION_DISABLE(SUBREGION) ((SUBREGION) < (uint16_t)0x00FF)
#endif /* __MPU_PRESENT */
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_HAL_CORTEX_H */
| 17,395 | C | 40.419048 | 134 | 0.488704 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_pwr.h | /**
******************************************************************************
* @file stm32g4xx_hal_pwr.h
* @author MCD Application Team
* @brief Header file of PWR HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_PWR_H
#define STM32G4xx_HAL_PWR_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup PWR
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup PWR_Exported_Types PWR Exported Types
* @{
*/
/**
* @brief PWR PVD configuration structure definition
*/
typedef struct
{
uint32_t PVDLevel; /*!< PVDLevel: Specifies the PVD detection level.
This parameter can be a value of @ref PWR_PVD_detection_level. */
uint32_t Mode; /*!< Mode: Specifies the operating mode for the selected pins.
This parameter can be a value of @ref PWR_PVD_Mode. */
}PWR_PVDTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup PWR_Exported_Constants PWR Exported Constants
* @{
*/
/** @defgroup PWR_PVD_detection_level Programmable Voltage Detection levels
* @{
*/
#define PWR_PVDLEVEL_0 PWR_CR2_PLS_LEV0 /*!< PVD threshold around 2.0 V */
#define PWR_PVDLEVEL_1 PWR_CR2_PLS_LEV1 /*!< PVD threshold around 2.2 V */
#define PWR_PVDLEVEL_2 PWR_CR2_PLS_LEV2 /*!< PVD threshold around 2.4 V */
#define PWR_PVDLEVEL_3 PWR_CR2_PLS_LEV3 /*!< PVD threshold around 2.5 V */
#define PWR_PVDLEVEL_4 PWR_CR2_PLS_LEV4 /*!< PVD threshold around 2.6 V */
#define PWR_PVDLEVEL_5 PWR_CR2_PLS_LEV5 /*!< PVD threshold around 2.8 V */
#define PWR_PVDLEVEL_6 PWR_CR2_PLS_LEV6 /*!< PVD threshold around 2.9 V */
#define PWR_PVDLEVEL_7 PWR_CR2_PLS_LEV7 /*!< External input analog voltage (compared internally to VREFINT) */
/**
* @}
*/
/** @defgroup PWR_PVD_Mode PWR PVD interrupt and event mode
* @{
*/
#define PWR_PVD_MODE_NORMAL ((uint32_t)0x00000000) /*!< Basic mode is used */
#define PWR_PVD_MODE_IT_RISING ((uint32_t)0x00010001) /*!< External Interrupt Mode with Rising edge trigger detection */
#define PWR_PVD_MODE_IT_FALLING ((uint32_t)0x00010002) /*!< External Interrupt Mode with Falling edge trigger detection */
#define PWR_PVD_MODE_IT_RISING_FALLING ((uint32_t)0x00010003) /*!< External Interrupt Mode with Rising/Falling edge trigger detection */
#define PWR_PVD_MODE_EVENT_RISING ((uint32_t)0x00020001) /*!< Event Mode with Rising edge trigger detection */
#define PWR_PVD_MODE_EVENT_FALLING ((uint32_t)0x00020002) /*!< Event Mode with Falling edge trigger detection */
#define PWR_PVD_MODE_EVENT_RISING_FALLING ((uint32_t)0x00020003) /*!< Event Mode with Rising/Falling edge trigger detection */
/**
* @}
*/
/** @defgroup PWR_Regulator_state_in_SLEEP_STOP_mode PWR regulator mode
* @{
*/
#define PWR_MAINREGULATOR_ON ((uint32_t)0x00000000) /*!< Regulator in main mode */
#define PWR_LOWPOWERREGULATOR_ON PWR_CR1_LPR /*!< Regulator in low-power mode */
/**
* @}
*/
/** @defgroup PWR_SLEEP_mode_entry PWR SLEEP mode entry
* @{
*/
#define PWR_SLEEPENTRY_WFI ((uint8_t)0x01) /*!< Wait For Interruption instruction to enter Sleep mode */
#define PWR_SLEEPENTRY_WFE ((uint8_t)0x02) /*!< Wait For Event instruction to enter Sleep mode */
/**
* @}
*/
/** @defgroup PWR_STOP_mode_entry PWR STOP mode entry
* @{
*/
#define PWR_STOPENTRY_WFI ((uint8_t)0x01) /*!< Wait For Interruption instruction to enter Stop mode */
#define PWR_STOPENTRY_WFE ((uint8_t)0x02) /*!< Wait For Event instruction to enter Stop mode */
/**
* @}
*/
/** @defgroup PWR_PVD_EXTI_LINE PWR PVD external interrupt line
* @{
*/
#define PWR_EXTI_LINE_PVD ((uint32_t)0x00010000) /*!< External interrupt line 16 Connected to the PVD EXTI Line */
/**
* @}
*/
/** @defgroup PWR_PVD_EVENT_LINE PWR PVD event line
* @{
*/
#define PWR_EVENT_LINE_PVD ((uint32_t)0x00010000) /*!< Event line 16 Connected to the PVD Event Line */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup PWR_Exported_Macros PWR Exported Macros
* @{
*/
/** @brief Check whether or not a specific PWR flag is set.
* @param __FLAG__: specifies the flag to check.
* This parameter can be one of the following values:
* @arg @ref PWR_FLAG_WUF1 Wake Up Flag 1. Indicates that a wakeup event
* was received from the WKUP pin 1.
* @arg @ref PWR_FLAG_WUF2 Wake Up Flag 2. Indicates that a wakeup event
* was received from the WKUP pin 2.
* @arg @ref PWR_FLAG_WUF3 Wake Up Flag 3. Indicates that a wakeup event
* was received from the WKUP pin 3.
* @arg @ref PWR_FLAG_WUF4 Wake Up Flag 4. Indicates that a wakeup event
* was received from the WKUP pin 4.
* @arg @ref PWR_FLAG_WUF5 Wake Up Flag 5. Indicates that a wakeup event
* was received from the WKUP pin 5.
* @arg @ref PWR_FLAG_SB StandBy Flag. Indicates that the system
* entered StandBy mode.
* @arg @ref PWR_FLAG_WUFI Wake-Up Flag Internal. Set when a wakeup is detected on
* the internal wakeup line.
* @arg @ref PWR_FLAG_REGLPS Low Power Regulator Started. Indicates whether or not the
* low-power regulator is ready.
* @arg @ref PWR_FLAG_REGLPF Low Power Regulator Flag. Indicates whether the
* regulator is ready in main mode or is in low-power mode.
* @arg @ref PWR_FLAG_VOSF Voltage Scaling Flag. Indicates whether the regulator is ready
* in the selected voltage range or is still changing to the required voltage level.
* @arg @ref PWR_FLAG_PVDO Power Voltage Detector Output. Indicates whether VDD voltage is
* below or above the selected PVD threshold.
@if PWR_CR2_PVME1
* @arg @ref PWR_FLAG_PVMO1 Peripheral Voltage Monitoring Output 1. Indicates whether VDDUSB voltage is
* is below or above PVM1 threshold (applicable when USB feature is supported).
@endif
@if PWR_CR2_PVME2
* @arg @ref PWR_FLAG_PVMO2 Peripheral Voltage Monitoring Output 2. Indicates whether VDDIO2 voltage is
* is below or above PVM2 threshold (applicable when VDDIO2 is present on device).
@endif
* @arg @ref PWR_FLAG_PVMO3 Peripheral Voltage Monitoring Output 3. Indicates whether VDDA voltage is
* is below or above PVM3 threshold.
* @arg @ref PWR_FLAG_PVMO4 Peripheral Voltage Monitoring Output 4. Indicates whether VDDA voltage is
* is below or above PVM4 threshold.
*
* @retval The new state of __FLAG__ (TRUE or FALSE).
*/
#define __HAL_PWR_GET_FLAG(__FLAG__) ( ((((uint8_t)(__FLAG__)) >> 5U) == 1) ?\
(PWR->SR1 & (1U << ((__FLAG__) & 31U))) :\
(PWR->SR2 & (1U << ((__FLAG__) & 31U))) )
/** @brief Clear a specific PWR flag.
* @param __FLAG__: specifies the flag to clear.
* This parameter can be one of the following values:
* @arg @ref PWR_FLAG_WUF1 Wake Up Flag 1. Indicates that a wakeup event
* was received from the WKUP pin 1.
* @arg @ref PWR_FLAG_WUF2 Wake Up Flag 2. Indicates that a wakeup event
* was received from the WKUP pin 2.
* @arg @ref PWR_FLAG_WUF3 Wake Up Flag 3. Indicates that a wakeup event
* was received from the WKUP pin 3.
* @arg @ref PWR_FLAG_WUF4 Wake Up Flag 4. Indicates that a wakeup event
* was received from the WKUP pin 4.
* @arg @ref PWR_FLAG_WUF5 Wake Up Flag 5. Indicates that a wakeup event
* was received from the WKUP pin 5.
* @arg @ref PWR_FLAG_WU Encompasses all five Wake Up Flags.
* @arg @ref PWR_FLAG_SB Standby Flag. Indicates that the system
* entered Standby mode.
* @retval None
*/
#define __HAL_PWR_CLEAR_FLAG(__FLAG__) ( (((uint8_t)(__FLAG__)) == PWR_FLAG_WU) ?\
(PWR->SCR = (__FLAG__)) :\
(PWR->SCR = (1U << ((__FLAG__) & 31U))) )
/**
* @brief Enable the PVD Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_IT() SET_BIT(EXTI->IMR1, PWR_EXTI_LINE_PVD)
/**
* @brief Disable the PVD Extended Interrupt Line.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_IT() CLEAR_BIT(EXTI->IMR1, PWR_EXTI_LINE_PVD)
/**
* @brief Enable the PVD Event Line.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_EVENT() SET_BIT(EXTI->EMR1, PWR_EVENT_LINE_PVD)
/**
* @brief Disable the PVD Event Line.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_EVENT() CLEAR_BIT(EXTI->EMR1, PWR_EVENT_LINE_PVD)
/**
* @brief Enable the PVD Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE() SET_BIT(EXTI->RTSR1, PWR_EXTI_LINE_PVD)
/**
* @brief Disable the PVD Extended Interrupt Rising Trigger.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE() CLEAR_BIT(EXTI->RTSR1, PWR_EXTI_LINE_PVD)
/**
* @brief Enable the PVD Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE() SET_BIT(EXTI->FTSR1, PWR_EXTI_LINE_PVD)
/**
* @brief Disable the PVD Extended Interrupt Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE() CLEAR_BIT(EXTI->FTSR1, PWR_EXTI_LINE_PVD)
/**
* @brief Enable the PVD Extended Interrupt Rising & Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_ENABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE(); \
__HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Disable the PVD Extended Interrupt Rising & Falling Trigger.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_DISABLE_RISING_FALLING_EDGE() \
do { \
__HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE(); \
__HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Generate a Software interrupt on selected EXTI line.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_GENERATE_SWIT() SET_BIT(EXTI->SWIER1, PWR_EXTI_LINE_PVD)
/**
* @brief Check whether or not the PVD EXTI interrupt flag is set.
* @retval EXTI PVD Line Status.
*/
#define __HAL_PWR_PVD_EXTI_GET_FLAG() (EXTI->PR1 & PWR_EXTI_LINE_PVD)
/**
* @brief Clear the PVD EXTI interrupt flag.
* @retval None
*/
#define __HAL_PWR_PVD_EXTI_CLEAR_FLAG() WRITE_REG(EXTI->PR1, PWR_EXTI_LINE_PVD)
/**
* @}
*/
/* Private macros --------------------------------------------------------*/
/** @addtogroup PWR_Private_Macros PWR Private Macros
* @{
*/
#define IS_PWR_PVD_LEVEL(LEVEL) (((LEVEL) == PWR_PVDLEVEL_0) || ((LEVEL) == PWR_PVDLEVEL_1)|| \
((LEVEL) == PWR_PVDLEVEL_2) || ((LEVEL) == PWR_PVDLEVEL_3)|| \
((LEVEL) == PWR_PVDLEVEL_4) || ((LEVEL) == PWR_PVDLEVEL_5)|| \
((LEVEL) == PWR_PVDLEVEL_6) || ((LEVEL) == PWR_PVDLEVEL_7))
#define IS_PWR_PVD_MODE(MODE) (((MODE) == PWR_PVD_MODE_NORMAL) ||\
((MODE) == PWR_PVD_MODE_IT_RISING) ||\
((MODE) == PWR_PVD_MODE_IT_FALLING) ||\
((MODE) == PWR_PVD_MODE_IT_RISING_FALLING) ||\
((MODE) == PWR_PVD_MODE_EVENT_RISING) ||\
((MODE) == PWR_PVD_MODE_EVENT_FALLING) ||\
((MODE) == PWR_PVD_MODE_EVENT_RISING_FALLING))
#define IS_PWR_REGULATOR(REGULATOR) (((REGULATOR) == PWR_MAINREGULATOR_ON) || \
((REGULATOR) == PWR_LOWPOWERREGULATOR_ON))
#define IS_PWR_SLEEP_ENTRY(ENTRY) (((ENTRY) == PWR_SLEEPENTRY_WFI) || ((ENTRY) == PWR_SLEEPENTRY_WFE))
#define IS_PWR_STOP_ENTRY(ENTRY) (((ENTRY) == PWR_STOPENTRY_WFI) || ((ENTRY) == PWR_STOPENTRY_WFE) )
/**
* @}
*/
/* Include PWR HAL Extended module */
#include "stm32g4xx_hal_pwr_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup PWR_Exported_Functions PWR Exported Functions
* @{
*/
/** @addtogroup PWR_Exported_Functions_Group1 Initialization and de-initialization functions
* @{
*/
/* Initialization and de-initialization functions *******************************/
void HAL_PWR_DeInit(void);
void HAL_PWR_EnableBkUpAccess(void);
void HAL_PWR_DisableBkUpAccess(void);
/**
* @}
*/
/** @addtogroup PWR_Exported_Functions_Group2 Peripheral Control functions
* @{
*/
/* Peripheral Control functions ************************************************/
HAL_StatusTypeDef HAL_PWR_ConfigPVD(PWR_PVDTypeDef *sConfigPVD);
void HAL_PWR_EnablePVD(void);
void HAL_PWR_DisablePVD(void);
/* WakeUp pins configuration functions ****************************************/
void HAL_PWR_EnableWakeUpPin(uint32_t WakeUpPinPolarity);
void HAL_PWR_DisableWakeUpPin(uint32_t WakeUpPinx);
/* Low Power modes configuration functions ************************************/
void HAL_PWR_EnterSLEEPMode(uint32_t Regulator, uint8_t SLEEPEntry);
void HAL_PWR_EnterSTOPMode(uint32_t Regulator, uint8_t STOPEntry);
void HAL_PWR_EnterSTANDBYMode(void);
void HAL_PWR_EnableSleepOnExit(void);
void HAL_PWR_DisableSleepOnExit(void);
void HAL_PWR_EnableSEVOnPend(void);
void HAL_PWR_DisableSEVOnPend(void);
void HAL_PWR_PVDCallback(void);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_PWR_H */
| 15,118 | C | 35.696602 | 143 | 0.562839 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_tim.h | /**
******************************************************************************
* @file stm32g4xx_ll_tim.h
* @author MCD Application Team
* @brief Header file of TIM LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_LL_TIM_H
#define __STM32G4xx_LL_TIM_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined (TIM1) || defined (TIM2) || defined (TIM3) || defined (TIM4) || defined (TIM5) || defined (TIM6) || defined (TIM7) || defined (TIM8) || defined (TIM15) || defined (TIM16) || defined (TIM17) || defined (TIM20)
/** @defgroup TIM_LL TIM
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup TIM_LL_Private_Variables TIM Private Variables
* @{
*/
static const uint8_t OFFSET_TAB_CCMRx[] =
{
0x00U, /* 0: TIMx_CH1 */
0x00U, /* 1: TIMx_CH1N */
0x00U, /* 2: TIMx_CH2 */
0x00U, /* 3: TIMx_CH2N */
0x04U, /* 4: TIMx_CH3 */
0x04U, /* 5: TIMx_CH3N */
0x04U, /* 6: TIMx_CH4 */
0x04U, /* 7: TIMx_CH4N */
0x38U, /* 8: TIMx_CH5 */
0x38U /* 9: TIMx_CH6 */
};
static const uint8_t SHIFT_TAB_OCxx[] =
{
0U, /* 0: OC1M, OC1FE, OC1PE */
0U, /* 1: - NA */
8U, /* 2: OC2M, OC2FE, OC2PE */
0U, /* 3: - NA */
0U, /* 4: OC3M, OC3FE, OC3PE */
0U, /* 5: - NA */
8U, /* 6: OC4M, OC4FE, OC4PE */
0U, /* 7: - NA */
0U, /* 8: OC5M, OC5FE, OC5PE */
8U /* 9: OC6M, OC6FE, OC6PE */
};
static const uint8_t SHIFT_TAB_ICxx[] =
{
0U, /* 0: CC1S, IC1PSC, IC1F */
0U, /* 1: - NA */
8U, /* 2: CC2S, IC2PSC, IC2F */
0U, /* 3: - NA */
0U, /* 4: CC3S, IC3PSC, IC3F */
0U, /* 5: - NA */
8U, /* 6: CC4S, IC4PSC, IC4F */
0U, /* 7: - NA */
0U, /* 8: - NA */
0U /* 9: - NA */
};
static const uint8_t SHIFT_TAB_CCxP[] =
{
0U, /* 0: CC1P */
2U, /* 1: CC1NP */
4U, /* 2: CC2P */
6U, /* 3: CC2NP */
8U, /* 4: CC3P */
10U, /* 5: CC3NP */
12U, /* 6: CC4P */
14U, /* 7: CC4NP */
16U, /* 8: CC5P */
20U /* 9: CC6P */
};
static const uint8_t SHIFT_TAB_OISx[] =
{
0U, /* 0: OIS1 */
1U, /* 1: OIS1N */
2U, /* 2: OIS2 */
3U, /* 3: OIS2N */
4U, /* 4: OIS3 */
5U, /* 5: OIS3N */
6U, /* 6: OIS4 */
7U, /* 7: OIS4N */
8U, /* 8: OIS5 */
10U /* 9: OIS6 */
};
/**
* @}
*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup TIM_LL_Private_Constants TIM Private Constants
* @{
*/
/* Defines used for the bit position in the register and perform offsets */
#define TIM_POSITION_BRK_SOURCE (POSITION_VAL(Source) & 0x1FUL)
/* Generic bit definitions for TIMx_AF1 register */
#define TIMx_AF1_BKINP TIM1_AF1_BKINP /*!< BRK BKIN input polarity */
#define TIMx_AF1_ETRSEL TIM1_AF1_ETRSEL /*!< TIMx ETR source selection */
/* Mask used to set the TDG[x:0] of the DTG bits of the TIMx_BDTR register */
#define DT_DELAY_1 ((uint8_t)0x7F)
#define DT_DELAY_2 ((uint8_t)0x3F)
#define DT_DELAY_3 ((uint8_t)0x1F)
#define DT_DELAY_4 ((uint8_t)0x1F)
/* Mask used to set the DTG[7:5] bits of the DTG bits of the TIMx_BDTR register */
#define DT_RANGE_1 ((uint8_t)0x00)
#define DT_RANGE_2 ((uint8_t)0x80)
#define DT_RANGE_3 ((uint8_t)0xC0)
#define DT_RANGE_4 ((uint8_t)0xE0)
/** Legacy definitions for compatibility purpose
@cond 0
*/
/**
@endcond
*/
#define OCREF_CLEAR_SELECT_Pos (28U)
#define OCREF_CLEAR_SELECT_Msk (0x1U << OCREF_CLEAR_SELECT_Pos) /*!< 0x10000000 */
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup TIM_LL_Private_Macros TIM Private Macros
* @{
*/
/** @brief Convert channel id into channel index.
* @param __CHANNEL__ This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval none
*/
#define TIM_GET_CHANNEL_INDEX( __CHANNEL__) \
(((__CHANNEL__) == LL_TIM_CHANNEL_CH1) ? 0U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH1N) ? 1U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH2) ? 2U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH2N) ? 3U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH3) ? 4U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH3N) ? 5U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH4) ? 6U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH4N) ? 7U :\
((__CHANNEL__) == LL_TIM_CHANNEL_CH5) ? 8U : 9U)
/** @brief Calculate the deadtime sampling period(in ps).
* @param __TIMCLK__ timer input clock frequency (in Hz).
* @param __CKD__ This parameter can be one of the following values:
* @arg @ref LL_TIM_CLOCKDIVISION_DIV1
* @arg @ref LL_TIM_CLOCKDIVISION_DIV2
* @arg @ref LL_TIM_CLOCKDIVISION_DIV4
* @retval none
*/
#define TIM_CALC_DTS(__TIMCLK__, __CKD__) \
(((__CKD__) == LL_TIM_CLOCKDIVISION_DIV1) ? ((uint64_t)1000000000000U/(__TIMCLK__)) : \
((__CKD__) == LL_TIM_CLOCKDIVISION_DIV2) ? ((uint64_t)1000000000000U/((__TIMCLK__) >> 1U)) : \
((uint64_t)1000000000000U/((__TIMCLK__) >> 2U)))
/**
* @}
*/
/* Exported types ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup TIM_LL_ES_INIT TIM Exported Init structure
* @{
*/
/**
* @brief TIM Time Base configuration structure definition.
*/
typedef struct
{
uint16_t Prescaler; /*!< Specifies the prescaler value used to divide the TIM clock.
This parameter can be a number between Min_Data=0x0000 and Max_Data=0xFFFF.
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetPrescaler().*/
uint32_t CounterMode; /*!< Specifies the counter mode.
This parameter can be a value of @ref TIM_LL_EC_COUNTERMODE.
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetCounterMode().*/
uint32_t Autoreload; /*!< Specifies the auto reload value to be loaded into the active
Auto-Reload Register at the next update event.
This parameter must be a number between Min_Data=0x0000 and Max_Data=0xFFFF.
Some timer instances may support 32 bits counters. In that case this parameter must
be a number between 0x0000 and 0xFFFFFFFF.
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetAutoReload().*/
uint32_t ClockDivision; /*!< Specifies the clock division.
This parameter can be a value of @ref TIM_LL_EC_CLOCKDIVISION.
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetClockDivision().*/
uint32_t RepetitionCounter; /*!< Specifies the repetition counter value. Each time the RCR downcounter
reaches zero, an update event is generated and counting restarts
from the RCR value (N).
This means in PWM mode that (N+1) corresponds to:
- the number of PWM periods in edge-aligned mode
- the number of half PWM period in center-aligned mode
GP timers: this parameter must be a number between Min_Data = 0x00 and
Max_Data = 0xFF.
Advanced timers: this parameter must be a number between Min_Data = 0x0000 and
Max_Data = 0xFFFF.
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetRepetitionCounter().*/
} LL_TIM_InitTypeDef;
/**
* @brief TIM Output Compare configuration structure definition.
*/
typedef struct
{
uint32_t OCMode; /*!< Specifies the output mode.
This parameter can be a value of @ref TIM_LL_EC_OCMODE.
This feature can be modified afterwards using unitary function
@ref LL_TIM_OC_SetMode().*/
uint32_t OCState; /*!< Specifies the TIM Output Compare state.
This parameter can be a value of @ref TIM_LL_EC_OCSTATE.
This feature can be modified afterwards using unitary functions
@ref LL_TIM_CC_EnableChannel() or @ref LL_TIM_CC_DisableChannel().*/
uint32_t OCNState; /*!< Specifies the TIM complementary Output Compare state.
This parameter can be a value of @ref TIM_LL_EC_OCSTATE.
This feature can be modified afterwards using unitary functions
@ref LL_TIM_CC_EnableChannel() or @ref LL_TIM_CC_DisableChannel().*/
uint32_t CompareValue; /*!< Specifies the Compare value to be loaded into the Capture Compare Register.
This parameter can be a number between Min_Data=0x0000 and Max_Data=0xFFFF.
This feature can be modified afterwards using unitary function
LL_TIM_OC_SetCompareCHx (x=1..6).*/
uint32_t OCPolarity; /*!< Specifies the output polarity.
This parameter can be a value of @ref TIM_LL_EC_OCPOLARITY.
This feature can be modified afterwards using unitary function
@ref LL_TIM_OC_SetPolarity().*/
uint32_t OCNPolarity; /*!< Specifies the complementary output polarity.
This parameter can be a value of @ref TIM_LL_EC_OCPOLARITY.
This feature can be modified afterwards using unitary function
@ref LL_TIM_OC_SetPolarity().*/
uint32_t OCIdleState; /*!< Specifies the TIM Output Compare pin state during Idle state.
This parameter can be a value of @ref TIM_LL_EC_OCIDLESTATE.
This feature can be modified afterwards using unitary function
@ref LL_TIM_OC_SetIdleState().*/
uint32_t OCNIdleState; /*!< Specifies the TIM Output Compare pin state during Idle state.
This parameter can be a value of @ref TIM_LL_EC_OCIDLESTATE.
This feature can be modified afterwards using unitary function
@ref LL_TIM_OC_SetIdleState().*/
} LL_TIM_OC_InitTypeDef;
/**
* @brief TIM Input Capture configuration structure definition.
*/
typedef struct
{
uint32_t ICPolarity; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_LL_EC_IC_POLARITY.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPolarity().*/
uint32_t ICActiveInput; /*!< Specifies the input.
This parameter can be a value of @ref TIM_LL_EC_ACTIVEINPUT.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetActiveInput().*/
uint32_t ICPrescaler; /*!< Specifies the Input Capture Prescaler.
This parameter can be a value of @ref TIM_LL_EC_ICPSC.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPrescaler().*/
uint32_t ICFilter; /*!< Specifies the input capture filter.
This parameter can be a value of @ref TIM_LL_EC_IC_FILTER.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetFilter().*/
} LL_TIM_IC_InitTypeDef;
/**
* @brief TIM Encoder interface configuration structure definition.
*/
typedef struct
{
uint32_t EncoderMode; /*!< Specifies the encoder resolution (x2 or x4).
This parameter can be a value of @ref TIM_LL_EC_ENCODERMODE.
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetEncoderMode().*/
uint32_t IC1Polarity; /*!< Specifies the active edge of TI1 input.
This parameter can be a value of @ref TIM_LL_EC_IC_POLARITY.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPolarity().*/
uint32_t IC1ActiveInput; /*!< Specifies the TI1 input source
This parameter can be a value of @ref TIM_LL_EC_ACTIVEINPUT.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetActiveInput().*/
uint32_t IC1Prescaler; /*!< Specifies the TI1 input prescaler value.
This parameter can be a value of @ref TIM_LL_EC_ICPSC.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPrescaler().*/
uint32_t IC1Filter; /*!< Specifies the TI1 input filter.
This parameter can be a value of @ref TIM_LL_EC_IC_FILTER.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetFilter().*/
uint32_t IC2Polarity; /*!< Specifies the active edge of TI2 input.
This parameter can be a value of @ref TIM_LL_EC_IC_POLARITY.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPolarity().*/
uint32_t IC2ActiveInput; /*!< Specifies the TI2 input source
This parameter can be a value of @ref TIM_LL_EC_ACTIVEINPUT.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetActiveInput().*/
uint32_t IC2Prescaler; /*!< Specifies the TI2 input prescaler value.
This parameter can be a value of @ref TIM_LL_EC_ICPSC.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPrescaler().*/
uint32_t IC2Filter; /*!< Specifies the TI2 input filter.
This parameter can be a value of @ref TIM_LL_EC_IC_FILTER.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetFilter().*/
} LL_TIM_ENCODER_InitTypeDef;
/**
* @brief TIM Hall sensor interface configuration structure definition.
*/
typedef struct
{
uint32_t IC1Polarity; /*!< Specifies the active edge of TI1 input.
This parameter can be a value of @ref TIM_LL_EC_IC_POLARITY.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPolarity().*/
uint32_t IC1Prescaler; /*!< Specifies the TI1 input prescaler value.
Prescaler must be set to get a maximum counter period longer than the
time interval between 2 consecutive changes on the Hall inputs.
This parameter can be a value of @ref TIM_LL_EC_ICPSC.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetPrescaler().*/
uint32_t IC1Filter; /*!< Specifies the TI1 input filter.
This parameter can be a value of
@ref TIM_LL_EC_IC_FILTER.
This feature can be modified afterwards using unitary function
@ref LL_TIM_IC_SetFilter().*/
uint32_t CommutationDelay; /*!< Specifies the compare value to be loaded into the Capture Compare Register.
A positive pulse (TRGO event) is generated with a programmable delay every time
a change occurs on the Hall inputs.
This parameter can be a number between Min_Data = 0x0000 and Max_Data = 0xFFFF.
This feature can be modified afterwards using unitary function
@ref LL_TIM_OC_SetCompareCH2().*/
} LL_TIM_HALLSENSOR_InitTypeDef;
/**
* @brief BDTR (Break and Dead Time) structure definition
*/
typedef struct
{
uint32_t OSSRState; /*!< Specifies the Off-State selection used in Run mode.
This parameter can be a value of @ref TIM_LL_EC_OSSR
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetOffStates()
@note This bit-field cannot be modified as long as LOCK level 2 has been
programmed. */
uint32_t OSSIState; /*!< Specifies the Off-State used in Idle state.
This parameter can be a value of @ref TIM_LL_EC_OSSI
This feature can be modified afterwards using unitary function
@ref LL_TIM_SetOffStates()
@note This bit-field cannot be modified as long as LOCK level 2 has been
programmed. */
uint32_t LockLevel; /*!< Specifies the LOCK level parameters.
This parameter can be a value of @ref TIM_LL_EC_LOCKLEVEL
@note The LOCK bits can be written only once after the reset. Once the TIMx_BDTR
register has been written, their content is frozen until the next reset.*/
uint8_t DeadTime; /*!< Specifies the delay time between the switching-off and the
switching-on of the outputs.
This parameter can be a number between Min_Data = 0x00 and Max_Data = 0xFF.
This feature can be modified afterwards using unitary function
@ref LL_TIM_OC_SetDeadTime()
@note This bit-field can not be modified as long as LOCK level 1, 2 or 3 has been
programmed. */
uint16_t BreakState; /*!< Specifies whether the TIM Break input is enabled or not.
This parameter can be a value of @ref TIM_LL_EC_BREAK_ENABLE
This feature can be modified afterwards using unitary functions
@ref LL_TIM_EnableBRK() or @ref LL_TIM_DisableBRK()
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t BreakPolarity; /*!< Specifies the TIM Break Input pin polarity.
This parameter can be a value of @ref TIM_LL_EC_BREAK_POLARITY
This feature can be modified afterwards using unitary function
@ref LL_TIM_ConfigBRK()
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t BreakFilter; /*!< Specifies the TIM Break Filter.
This parameter can be a value of @ref TIM_LL_EC_BREAK_FILTER
This feature can be modified afterwards using unitary function
@ref LL_TIM_ConfigBRK()
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t BreakAFMode; /*!< Specifies the alternate function mode of the break input.
This parameter can be a value of @ref TIM_LL_EC_BREAK_AFMODE
This feature can be modified afterwards using unitary functions
@ref LL_TIM_ConfigBRK()
@note Bidirectional break input is only supported by advanced timers instances.
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t Break2State; /*!< Specifies whether the TIM Break2 input is enabled or not.
This parameter can be a value of @ref TIM_LL_EC_BREAK2_ENABLE
This feature can be modified afterwards using unitary functions
@ref LL_TIM_EnableBRK2() or @ref LL_TIM_DisableBRK2()
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t Break2Polarity; /*!< Specifies the TIM Break2 Input pin polarity.
This parameter can be a value of @ref TIM_LL_EC_BREAK2_POLARITY
This feature can be modified afterwards using unitary function
@ref LL_TIM_ConfigBRK2()
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t Break2Filter; /*!< Specifies the TIM Break2 Filter.
This parameter can be a value of @ref TIM_LL_EC_BREAK2_FILTER
This feature can be modified afterwards using unitary function
@ref LL_TIM_ConfigBRK2()
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t Break2AFMode; /*!< Specifies the alternate function mode of the break2 input.
This parameter can be a value of @ref TIM_LL_EC_BREAK2_AFMODE
This feature can be modified afterwards using unitary functions
@ref LL_TIM_ConfigBRK2()
@note Bidirectional break input is only supported by advanced timers instances.
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
uint32_t AutomaticOutput; /*!< Specifies whether the TIM Automatic Output feature is enabled or not.
This parameter can be a value of @ref TIM_LL_EC_AUTOMATICOUTPUT_ENABLE
This feature can be modified afterwards using unitary functions
@ref LL_TIM_EnableAutomaticOutput() or @ref LL_TIM_DisableAutomaticOutput()
@note This bit-field can not be modified as long as LOCK level 1 has been
programmed. */
} LL_TIM_BDTR_InitTypeDef;
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/* Exported constants --------------------------------------------------------*/
/** @defgroup TIM_LL_Exported_Constants TIM Exported Constants
* @{
*/
/** @defgroup TIM_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_TIM_ReadReg function.
* @{
*/
#define LL_TIM_SR_UIF TIM_SR_UIF /*!< Update interrupt flag */
#define LL_TIM_SR_CC1IF TIM_SR_CC1IF /*!< Capture/compare 1 interrupt flag */
#define LL_TIM_SR_CC2IF TIM_SR_CC2IF /*!< Capture/compare 2 interrupt flag */
#define LL_TIM_SR_CC3IF TIM_SR_CC3IF /*!< Capture/compare 3 interrupt flag */
#define LL_TIM_SR_CC4IF TIM_SR_CC4IF /*!< Capture/compare 4 interrupt flag */
#define LL_TIM_SR_CC5IF TIM_SR_CC5IF /*!< Capture/compare 5 interrupt flag */
#define LL_TIM_SR_CC6IF TIM_SR_CC6IF /*!< Capture/compare 6 interrupt flag */
#define LL_TIM_SR_COMIF TIM_SR_COMIF /*!< COM interrupt flag */
#define LL_TIM_SR_TIF TIM_SR_TIF /*!< Trigger interrupt flag */
#define LL_TIM_SR_BIF TIM_SR_BIF /*!< Break interrupt flag */
#define LL_TIM_SR_B2IF TIM_SR_B2IF /*!< Second break interrupt flag */
#define LL_TIM_SR_CC1OF TIM_SR_CC1OF /*!< Capture/Compare 1 overcapture flag */
#define LL_TIM_SR_CC2OF TIM_SR_CC2OF /*!< Capture/Compare 2 overcapture flag */
#define LL_TIM_SR_CC3OF TIM_SR_CC3OF /*!< Capture/Compare 3 overcapture flag */
#define LL_TIM_SR_CC4OF TIM_SR_CC4OF /*!< Capture/Compare 4 overcapture flag */
#define LL_TIM_SR_SBIF TIM_SR_SBIF /*!< System Break interrupt flag */
#define LL_TIM_SR_IDXF TIM_SR_IDXF /*!< Index interrupt flag */
#define LL_TIM_SR_DIRF TIM_SR_DIRF /*!< Direction Change interrupt flag */
#define LL_TIM_SR_IERRF TIM_SR_IERRF /*!< Index Error flag */
#define LL_TIM_SR_TERRF TIM_SR_TERRF /*!< Transition Error flag */
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup TIM_LL_EC_BREAK_ENABLE Break Enable
* @{
*/
#define LL_TIM_BREAK_DISABLE 0x00000000U /*!< Break function disabled */
#define LL_TIM_BREAK_ENABLE TIM_BDTR_BKE /*!< Break function enabled */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BREAK2_ENABLE Break2 Enable
* @{
*/
#define LL_TIM_BREAK2_DISABLE 0x00000000U /*!< Break2 function disabled */
#define LL_TIM_BREAK2_ENABLE TIM_BDTR_BK2E /*!< Break2 function enabled */
/**
* @}
*/
/** @defgroup TIM_LL_EC_AUTOMATICOUTPUT_ENABLE Automatic output enable
* @{
*/
#define LL_TIM_AUTOMATICOUTPUT_DISABLE 0x00000000U /*!< MOE can be set only by software */
#define LL_TIM_AUTOMATICOUTPUT_ENABLE TIM_BDTR_AOE /*!< MOE can be set by software or automatically at the next update event */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/** @defgroup TIM_LL_EC_IT IT Defines
* @brief IT defines which can be used with LL_TIM_ReadReg and LL_TIM_WriteReg functions.
* @{
*/
#define LL_TIM_DIER_UIE TIM_DIER_UIE /*!< Update interrupt enable */
#define LL_TIM_DIER_CC1IE TIM_DIER_CC1IE /*!< Capture/compare 1 interrupt enable */
#define LL_TIM_DIER_CC2IE TIM_DIER_CC2IE /*!< Capture/compare 2 interrupt enable */
#define LL_TIM_DIER_CC3IE TIM_DIER_CC3IE /*!< Capture/compare 3 interrupt enable */
#define LL_TIM_DIER_CC4IE TIM_DIER_CC4IE /*!< Capture/compare 4 interrupt enable */
#define LL_TIM_DIER_COMIE TIM_DIER_COMIE /*!< COM interrupt enable */
#define LL_TIM_DIER_TIE TIM_DIER_TIE /*!< Trigger interrupt enable */
#define LL_TIM_DIER_BIE TIM_DIER_BIE /*!< Break interrupt enable */
#define LL_TIM_DIER_IDXIE TIM_DIER_IDXIE /*!< Index interrupt enable */
#define LL_TIM_DIER_DIRIE TIM_DIER_DIRIE /*!< Direction Change interrupt enable */
#define LL_TIM_DIER_IERRIE TIM_DIER_IERRIE /*!< Index Error interrupt enable */
#define LL_TIM_DIER_TERRIE TIM_DIER_TERRIE /*!< Transition Error interrupt enable */
/**
* @}
*/
/** @defgroup TIM_LL_EC_UPDATESOURCE Update Source
* @{
*/
#define LL_TIM_UPDATESOURCE_REGULAR 0x00000000U /*!< Counter overflow/underflow, Setting the UG bit or Update generation through the slave mode controller generates an update request */
#define LL_TIM_UPDATESOURCE_COUNTER TIM_CR1_URS /*!< Only counter overflow/underflow generates an update request */
/**
* @}
*/
/** @defgroup TIM_LL_EC_ONEPULSEMODE One Pulse Mode
* @{
*/
#define LL_TIM_ONEPULSEMODE_SINGLE TIM_CR1_OPM /*!< Counter stops counting at the next update event */
#define LL_TIM_ONEPULSEMODE_REPETITIVE 0x00000000U /*!< Counter is not stopped at update event */
/**
* @}
*/
/** @defgroup TIM_LL_EC_COUNTERMODE Counter Mode
* @{
*/
#define LL_TIM_COUNTERMODE_UP 0x00000000U /*!< Counter used as upcounter */
#define LL_TIM_COUNTERMODE_DOWN TIM_CR1_DIR /*!< Counter used as downcounter */
#define LL_TIM_COUNTERMODE_CENTER_DOWN TIM_CR1_CMS_0 /*!< The counter counts up and down alternatively. Output compare interrupt flags of output channels are set only when the counter is counting down. */
#define LL_TIM_COUNTERMODE_CENTER_UP TIM_CR1_CMS_1 /*!< The counter counts up and down alternatively. Output compare interrupt flags of output channels are set only when the counter is counting up */
#define LL_TIM_COUNTERMODE_CENTER_UP_DOWN TIM_CR1_CMS /*!< The counter counts up and down alternatively. Output compare interrupt flags of output channels are set only when the counter is counting up or down. */
/**
* @}
*/
/** @defgroup TIM_LL_EC_CLOCKDIVISION Clock Division
* @{
*/
#define LL_TIM_CLOCKDIVISION_DIV1 0x00000000U /*!< tDTS=tCK_INT */
#define LL_TIM_CLOCKDIVISION_DIV2 TIM_CR1_CKD_0 /*!< tDTS=2*tCK_INT */
#define LL_TIM_CLOCKDIVISION_DIV4 TIM_CR1_CKD_1 /*!< tDTS=4*tCK_INT */
/**
* @}
*/
/** @defgroup TIM_LL_EC_COUNTERDIRECTION Counter Direction
* @{
*/
#define LL_TIM_COUNTERDIRECTION_UP 0x00000000U /*!< Timer counter counts up */
#define LL_TIM_COUNTERDIRECTION_DOWN TIM_CR1_DIR /*!< Timer counter counts down */
/**
* @}
*/
/** @defgroup TIM_LL_EC_CCUPDATESOURCE Capture Compare Update Source
* @{
*/
#define LL_TIM_CCUPDATESOURCE_COMG_ONLY 0x00000000U /*!< Capture/compare control bits are updated by setting the COMG bit only */
#define LL_TIM_CCUPDATESOURCE_COMG_AND_TRGI TIM_CR2_CCUS /*!< Capture/compare control bits are updated by setting the COMG bit or when a rising edge occurs on trigger input (TRGI) */
/**
* @}
*/
/** @defgroup TIM_LL_EC_CCDMAREQUEST Capture Compare DMA Request
* @{
*/
#define LL_TIM_CCDMAREQUEST_CC 0x00000000U /*!< CCx DMA request sent when CCx event occurs */
#define LL_TIM_CCDMAREQUEST_UPDATE TIM_CR2_CCDS /*!< CCx DMA requests sent when update event occurs */
/**
* @}
*/
/** @defgroup TIM_LL_EC_LOCKLEVEL Lock Level
* @{
*/
#define LL_TIM_LOCKLEVEL_OFF 0x00000000U /*!< LOCK OFF - No bit is write protected */
#define LL_TIM_LOCKLEVEL_1 TIM_BDTR_LOCK_0 /*!< LOCK Level 1 */
#define LL_TIM_LOCKLEVEL_2 TIM_BDTR_LOCK_1 /*!< LOCK Level 2 */
#define LL_TIM_LOCKLEVEL_3 TIM_BDTR_LOCK /*!< LOCK Level 3 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_CHANNEL Channel
* @{
*/
#define LL_TIM_CHANNEL_CH1 TIM_CCER_CC1E /*!< Timer input/output channel 1 */
#define LL_TIM_CHANNEL_CH1N TIM_CCER_CC1NE /*!< Timer complementary output channel 1 */
#define LL_TIM_CHANNEL_CH2 TIM_CCER_CC2E /*!< Timer input/output channel 2 */
#define LL_TIM_CHANNEL_CH2N TIM_CCER_CC2NE /*!< Timer complementary output channel 2 */
#define LL_TIM_CHANNEL_CH3 TIM_CCER_CC3E /*!< Timer input/output channel 3 */
#define LL_TIM_CHANNEL_CH3N TIM_CCER_CC3NE /*!< Timer complementary output channel 3 */
#define LL_TIM_CHANNEL_CH4 TIM_CCER_CC4E /*!< Timer input/output channel 4 */
#define LL_TIM_CHANNEL_CH4N TIM_CCER_CC4NE /*!< Timer complementary output channel 4 */
#define LL_TIM_CHANNEL_CH5 TIM_CCER_CC5E /*!< Timer output channel 5 */
#define LL_TIM_CHANNEL_CH6 TIM_CCER_CC6E /*!< Timer output channel 6 */
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup TIM_LL_EC_OCSTATE Output Configuration State
* @{
*/
#define LL_TIM_OCSTATE_DISABLE 0x00000000U /*!< OCx is not active */
#define LL_TIM_OCSTATE_ENABLE TIM_CCER_CC1E /*!< OCx signal is output on the corresponding output pin */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/** Legacy definitions for compatibility purpose
@cond 0
*/
#define LL_TIM_OCMODE_ASSYMETRIC_PWM1 LL_TIM_OCMODE_ASYMMETRIC_PWM1
#define LL_TIM_OCMODE_ASSYMETRIC_PWM2 LL_TIM_OCMODE_ASYMMETRIC_PWM2
/**
@endcond
*/
/** @defgroup TIM_LL_EC_OCMODE Output Configuration Mode
* @{
*/
#define LL_TIM_OCMODE_FROZEN 0x00000000U /*!<The comparison between the output compare register TIMx_CCRy and the counter TIMx_CNT has no effect on the output channel level */
#define LL_TIM_OCMODE_ACTIVE TIM_CCMR1_OC1M_0 /*!<OCyREF is forced high on compare match*/
#define LL_TIM_OCMODE_INACTIVE TIM_CCMR1_OC1M_1 /*!<OCyREF is forced low on compare match*/
#define LL_TIM_OCMODE_TOGGLE (TIM_CCMR1_OC1M_1 | TIM_CCMR1_OC1M_0) /*!<OCyREF toggles on compare match*/
#define LL_TIM_OCMODE_FORCED_INACTIVE TIM_CCMR1_OC1M_2 /*!<OCyREF is forced low*/
#define LL_TIM_OCMODE_FORCED_ACTIVE (TIM_CCMR1_OC1M_2 | TIM_CCMR1_OC1M_0) /*!<OCyREF is forced high*/
#define LL_TIM_OCMODE_PWM1 (TIM_CCMR1_OC1M_2 | TIM_CCMR1_OC1M_1) /*!<In upcounting, channel y is active as long as TIMx_CNT<TIMx_CCRy else inactive. In downcounting, channel y is inactive as long as TIMx_CNT>TIMx_CCRy else active.*/
#define LL_TIM_OCMODE_PWM2 (TIM_CCMR1_OC1M_2 | TIM_CCMR1_OC1M_1 | TIM_CCMR1_OC1M_0) /*!<In upcounting, channel y is inactive as long as TIMx_CNT<TIMx_CCRy else active. In downcounting, channel y is active as long as TIMx_CNT>TIMx_CCRy else inactive*/
#define LL_TIM_OCMODE_RETRIG_OPM1 TIM_CCMR1_OC1M_3 /*!<Retrigerrable OPM mode 1*/
#define LL_TIM_OCMODE_RETRIG_OPM2 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_0) /*!<Retrigerrable OPM mode 2*/
#define LL_TIM_OCMODE_COMBINED_PWM1 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_2) /*!<Combined PWM mode 1*/
#define LL_TIM_OCMODE_COMBINED_PWM2 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_0 | TIM_CCMR1_OC1M_2) /*!<Combined PWM mode 2*/
#define LL_TIM_OCMODE_ASYMMETRIC_PWM1 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_1 | TIM_CCMR1_OC1M_2) /*!<Asymmetric PWM mode 1*/
#define LL_TIM_OCMODE_ASYMMETRIC_PWM2 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M) /*!<Asymmetric PWM mode 2*/
#define LL_TIM_OCMODE_PULSE_ON_COMPARE (TIM_CCMR2_OC3M_3 | TIM_CCMR2_OC3M_1) /*!<Pulse on Compare mode */
#define LL_TIM_OCMODE_DIRECTION_OUTPUT (TIM_CCMR2_OC3M_3 | TIM_CCMR2_OC3M_1 | TIM_CCMR2_OC3M_0) /*!<Direction output mode */
/**
* @}
*/
/** @defgroup TIM_LL_EC_OCPOLARITY Output Configuration Polarity
* @{
*/
#define LL_TIM_OCPOLARITY_HIGH 0x00000000U /*!< OCxactive high*/
#define LL_TIM_OCPOLARITY_LOW TIM_CCER_CC1P /*!< OCxactive low*/
/**
* @}
*/
/** @defgroup TIM_LL_EC_OCIDLESTATE Output Configuration Idle State
* @{
*/
#define LL_TIM_OCIDLESTATE_LOW 0x00000000U /*!<OCx=0 (after a dead-time if OC is implemented) when MOE=0*/
#define LL_TIM_OCIDLESTATE_HIGH TIM_CR2_OIS1 /*!<OCx=1 (after a dead-time if OC is implemented) when MOE=0*/
/**
* @}
*/
/** @defgroup TIM_LL_EC_GROUPCH5 GROUPCH5
* @{
*/
#define LL_TIM_GROUPCH5_NONE 0x00000000U /*!< No effect of OC5REF on OC1REFC, OC2REFC and OC3REFC */
#define LL_TIM_GROUPCH5_OC1REFC TIM_CCR5_GC5C1 /*!< OC1REFC is the logical AND of OC1REFC and OC5REF */
#define LL_TIM_GROUPCH5_OC2REFC TIM_CCR5_GC5C2 /*!< OC2REFC is the logical AND of OC2REFC and OC5REF */
#define LL_TIM_GROUPCH5_OC3REFC TIM_CCR5_GC5C3 /*!< OC3REFC is the logical AND of OC3REFC and OC5REF */
/**
* @}
*/
/** @defgroup TIM_LL_EC_ACTIVEINPUT Active Input Selection
* @{
*/
#define LL_TIM_ACTIVEINPUT_DIRECTTI (TIM_CCMR1_CC1S_0 << 16U) /*!< ICx is mapped on TIx */
#define LL_TIM_ACTIVEINPUT_INDIRECTTI (TIM_CCMR1_CC1S_1 << 16U) /*!< ICx is mapped on TIy */
#define LL_TIM_ACTIVEINPUT_TRC (TIM_CCMR1_CC1S << 16U) /*!< ICx is mapped on TRC */
/**
* @}
*/
/** @defgroup TIM_LL_EC_ICPSC Input Configuration Prescaler
* @{
*/
#define LL_TIM_ICPSC_DIV1 0x00000000U /*!< No prescaler, capture is done each time an edge is detected on the capture input */
#define LL_TIM_ICPSC_DIV2 (TIM_CCMR1_IC1PSC_0 << 16U) /*!< Capture is done once every 2 events */
#define LL_TIM_ICPSC_DIV4 (TIM_CCMR1_IC1PSC_1 << 16U) /*!< Capture is done once every 4 events */
#define LL_TIM_ICPSC_DIV8 (TIM_CCMR1_IC1PSC << 16U) /*!< Capture is done once every 8 events */
/**
* @}
*/
/** @defgroup TIM_LL_EC_IC_FILTER Input Configuration Filter
* @{
*/
#define LL_TIM_IC_FILTER_FDIV1 0x00000000U /*!< No filter, sampling is done at fDTS */
#define LL_TIM_IC_FILTER_FDIV1_N2 (TIM_CCMR1_IC1F_0 << 16U) /*!< fSAMPLING=fCK_INT, N=2 */
#define LL_TIM_IC_FILTER_FDIV1_N4 (TIM_CCMR1_IC1F_1 << 16U) /*!< fSAMPLING=fCK_INT, N=4 */
#define LL_TIM_IC_FILTER_FDIV1_N8 ((TIM_CCMR1_IC1F_1 | TIM_CCMR1_IC1F_0) << 16U) /*!< fSAMPLING=fCK_INT, N=8 */
#define LL_TIM_IC_FILTER_FDIV2_N6 (TIM_CCMR1_IC1F_2 << 16U) /*!< fSAMPLING=fDTS/2, N=6 */
#define LL_TIM_IC_FILTER_FDIV2_N8 ((TIM_CCMR1_IC1F_2 | TIM_CCMR1_IC1F_0) << 16U) /*!< fSAMPLING=fDTS/2, N=8 */
#define LL_TIM_IC_FILTER_FDIV4_N6 ((TIM_CCMR1_IC1F_2 | TIM_CCMR1_IC1F_1) << 16U) /*!< fSAMPLING=fDTS/4, N=6 */
#define LL_TIM_IC_FILTER_FDIV4_N8 ((TIM_CCMR1_IC1F_2 | TIM_CCMR1_IC1F_1 | TIM_CCMR1_IC1F_0) << 16U) /*!< fSAMPLING=fDTS/4, N=8 */
#define LL_TIM_IC_FILTER_FDIV8_N6 (TIM_CCMR1_IC1F_3 << 16U) /*!< fSAMPLING=fDTS/8, N=6 */
#define LL_TIM_IC_FILTER_FDIV8_N8 ((TIM_CCMR1_IC1F_3 | TIM_CCMR1_IC1F_0) << 16U) /*!< fSAMPLING=fDTS/8, N=8 */
#define LL_TIM_IC_FILTER_FDIV16_N5 ((TIM_CCMR1_IC1F_3 | TIM_CCMR1_IC1F_1) << 16U) /*!< fSAMPLING=fDTS/16, N=5 */
#define LL_TIM_IC_FILTER_FDIV16_N6 ((TIM_CCMR1_IC1F_3 | TIM_CCMR1_IC1F_1 | TIM_CCMR1_IC1F_0) << 16U) /*!< fSAMPLING=fDTS/16, N=6 */
#define LL_TIM_IC_FILTER_FDIV16_N8 ((TIM_CCMR1_IC1F_3 | TIM_CCMR1_IC1F_2) << 16U) /*!< fSAMPLING=fDTS/16, N=8 */
#define LL_TIM_IC_FILTER_FDIV32_N5 ((TIM_CCMR1_IC1F_3 | TIM_CCMR1_IC1F_2 | TIM_CCMR1_IC1F_0) << 16U) /*!< fSAMPLING=fDTS/32, N=5 */
#define LL_TIM_IC_FILTER_FDIV32_N6 ((TIM_CCMR1_IC1F_3 | TIM_CCMR1_IC1F_2 | TIM_CCMR1_IC1F_1) << 16U) /*!< fSAMPLING=fDTS/32, N=6 */
#define LL_TIM_IC_FILTER_FDIV32_N8 (TIM_CCMR1_IC1F << 16U) /*!< fSAMPLING=fDTS/32, N=8 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_IC_POLARITY Input Configuration Polarity
* @{
*/
#define LL_TIM_IC_POLARITY_RISING 0x00000000U /*!< The circuit is sensitive to TIxFP1 rising edge, TIxFP1 is not inverted */
#define LL_TIM_IC_POLARITY_FALLING TIM_CCER_CC1P /*!< The circuit is sensitive to TIxFP1 falling edge, TIxFP1 is inverted */
#define LL_TIM_IC_POLARITY_BOTHEDGE (TIM_CCER_CC1P | TIM_CCER_CC1NP) /*!< The circuit is sensitive to both TIxFP1 rising and falling edges, TIxFP1 is not inverted */
/**
* @}
*/
/** @defgroup TIM_LL_EC_CLOCKSOURCE Clock Source
* @{
*/
#define LL_TIM_CLOCKSOURCE_INTERNAL 0x00000000U /*!< The timer is clocked by the internal clock provided from the RCC */
#define LL_TIM_CLOCKSOURCE_EXT_MODE1 (TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< Counter counts at each rising or falling edge on a selected input*/
#define LL_TIM_CLOCKSOURCE_EXT_MODE2 TIM_SMCR_ECE /*!< Counter counts at each rising or falling edge on the external trigger input ETR */
/**
* @}
*/
/** @defgroup TIM_LL_EC_ENCODERMODE Encoder Mode
* @{
*/
#define LL_TIM_ENCODERMODE_X2_TI1 TIM_SMCR_SMS_0 /*!< Quadrature encoder mode 1, x2 mode - Counter counts up/down on TI1FP1 edge depending on TI2FP2 level */
#define LL_TIM_ENCODERMODE_X2_TI2 TIM_SMCR_SMS_1 /*!< Quadrature encoder mode 2, x2 mode - Counter counts up/down on TI2FP2 edge depending on TI1FP1 level */
#define LL_TIM_ENCODERMODE_X4_TI12 (TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< Quadrature encoder mode 3, x4 mode - Counter counts up/down on both TI1FP1 and TI2FP2 edges depending on the level of the other input */
#define LL_TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X2 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_1) /*!< Encoder mode: Clock plus direction - x2 mode */
#define LL_TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X1 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< Encoder mode: Clock plus direction, x1 mode, TI2FP2 edge sensitivity is set by CC2P */
#define LL_TIM_ENCODERMODE_DIRECTIONALCLOCK_X2 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2) /*!< Encoder mode: Directional Clock, x2 mode */
#define LL_TIM_ENCODERMODE_DIRECTIONALCLOCK_X1_TI12 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2 | TIM_SMCR_SMS_0) /*!< Encoder mode: Directional Clock, x1 mode, TI1FP1 and TI2FP2 edge sensitivity is set by CC1P and CC2P */
#define LL_TIM_ENCODERMODE_X1_TI1 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1) /*!< Quadrature encoder mode: x1 mode, counting on TI1FP1 edges only, edge sensitivity is set by CC1P */
#define LL_TIM_ENCODERMODE_X1_TI2 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< Quadrature encoder mode: x1 mode, counting on TI2FP2 edges only, edge sensitivity is set by CC1P */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TRGO Trigger Output
* @{
*/
#define LL_TIM_TRGO_RESET 0x00000000U /*!< UG bit from the TIMx_EGR register is used as trigger output */
#define LL_TIM_TRGO_ENABLE TIM_CR2_MMS_0 /*!< Counter Enable signal (CNT_EN) is used as trigger output */
#define LL_TIM_TRGO_UPDATE TIM_CR2_MMS_1 /*!< Update event is used as trigger output */
#define LL_TIM_TRGO_CC1IF (TIM_CR2_MMS_1 | TIM_CR2_MMS_0) /*!< CC1 capture or a compare match is used as trigger output */
#define LL_TIM_TRGO_OC1REF TIM_CR2_MMS_2 /*!< OC1REF signal is used as trigger output */
#define LL_TIM_TRGO_OC2REF (TIM_CR2_MMS_2 | TIM_CR2_MMS_0) /*!< OC2REF signal is used as trigger output */
#define LL_TIM_TRGO_OC3REF (TIM_CR2_MMS_2 | TIM_CR2_MMS_1) /*!< OC3REF signal is used as trigger output */
#define LL_TIM_TRGO_OC4REF (TIM_CR2_MMS_2 | TIM_CR2_MMS_1 | TIM_CR2_MMS_0) /*!< OC4REF signal is used as trigger output */
#define LL_TIM_TRGO_ENCODERCLK TIM_CR2_MMS_3 /*!< Encoder clock signal is used as trigger output */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TRGO2 Trigger Output 2
* @{
*/
#define LL_TIM_TRGO2_RESET 0x00000000U /*!< UG bit from the TIMx_EGR register is used as trigger output 2 */
#define LL_TIM_TRGO2_ENABLE TIM_CR2_MMS2_0 /*!< Counter Enable signal (CNT_EN) is used as trigger output 2 */
#define LL_TIM_TRGO2_UPDATE TIM_CR2_MMS2_1 /*!< Update event is used as trigger output 2 */
#define LL_TIM_TRGO2_CC1F (TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< CC1 capture or a compare match is used as trigger output 2 */
#define LL_TIM_TRGO2_OC1 TIM_CR2_MMS2_2 /*!< OC1REF signal is used as trigger output 2 */
#define LL_TIM_TRGO2_OC2 (TIM_CR2_MMS2_2 | TIM_CR2_MMS2_0) /*!< OC2REF signal is used as trigger output 2 */
#define LL_TIM_TRGO2_OC3 (TIM_CR2_MMS2_2 | TIM_CR2_MMS2_1) /*!< OC3REF signal is used as trigger output 2 */
#define LL_TIM_TRGO2_OC4 (TIM_CR2_MMS2_2 | TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< OC4REF signal is used as trigger output 2 */
#define LL_TIM_TRGO2_OC5 TIM_CR2_MMS2_3 /*!< OC5REF signal is used as trigger output 2 */
#define LL_TIM_TRGO2_OC6 (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_0) /*!< OC6REF signal is used as trigger output 2 */
#define LL_TIM_TRGO2_OC4_RISINGFALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_1) /*!< OC4REF rising or falling edges are used as trigger output 2 */
#define LL_TIM_TRGO2_OC6_RISINGFALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< OC6REF rising or falling edges are used as trigger output 2 */
#define LL_TIM_TRGO2_OC4_RISING_OC6_RISING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2) /*!< OC4REF or OC6REF rising edges are used as trigger output 2 */
#define LL_TIM_TRGO2_OC4_RISING_OC6_FALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2 | TIM_CR2_MMS2_0) /*!< OC4REF rising or OC6REF falling edges are used as trigger output 2 */
#define LL_TIM_TRGO2_OC5_RISING_OC6_RISING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2 |TIM_CR2_MMS2_1) /*!< OC5REF or OC6REF rising edges are used as trigger output 2 */
#define LL_TIM_TRGO2_OC5_RISING_OC6_FALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2 | TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< OC5REF rising or OC6REF falling edges are used as trigger output 2 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_SLAVEMODE Slave Mode
* @{
*/
#define LL_TIM_SLAVEMODE_DISABLED 0x00000000U /*!< Slave mode disabled */
#define LL_TIM_SLAVEMODE_RESET TIM_SMCR_SMS_2 /*!< Reset Mode - Rising edge of the selected trigger input (TRGI) reinitializes the counter */
#define LL_TIM_SLAVEMODE_GATED (TIM_SMCR_SMS_2 | TIM_SMCR_SMS_0) /*!< Gated Mode - The counter clock is enabled when the trigger input (TRGI) is high */
#define LL_TIM_SLAVEMODE_TRIGGER (TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1) /*!< Trigger Mode - The counter starts at a rising edge of the trigger TRGI */
#define LL_TIM_SLAVEMODE_COMBINED_RESETTRIGGER TIM_SMCR_SMS_3 /*!< Combined reset + trigger mode - Rising edge of the selected trigger input (TRGI) reinitializes the counter, generates an update of the registers and starts the counter */
#define LL_TIM_SLAVEMODE_COMBINED_GATEDRESET (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_0) /*!< Combined gated + reset mode - The counter clock is enabled when the trigger input (TRGI) is high. The counter stops and is reset) as soon as the trigger becomes low.Both startand stop of
the counter are controlled. */
/**
* @}
*/
/** @defgroup TIM_LL_EC_SMS_PRELOAD_SOURCE SMS Preload Source
* @{
*/
#define LL_TIM_SMSPS_TIMUPDATE 0x00000000U /*!< The SMS preload transfer is triggered by the Timer's Update event */
#define LL_TIM_SMSPS_INDEX TIM_SMCR_SMSPS /*!< The SMS preload transfer is triggered by the Index event */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TS Trigger Selection
* @{
*/
#define LL_TIM_TS_ITR0 0x00000000U /*!< Internal Trigger 0 (ITR0) is used as trigger input */
#define LL_TIM_TS_ITR1 TIM_SMCR_TS_0 /*!< Internal Trigger 1 (ITR1) is used as trigger input */
#define LL_TIM_TS_ITR2 TIM_SMCR_TS_1 /*!< Internal Trigger 2 (ITR2) is used as trigger input */
#define LL_TIM_TS_ITR3 (TIM_SMCR_TS_0 | TIM_SMCR_TS_1) /*!< Internal Trigger 3 (ITR3) is used as trigger input */
#define LL_TIM_TS_ITR4 TIM_SMCR_TS_3 /*!< Internal Trigger 4 (ITR4) is used as trigger input */
#define LL_TIM_TS_ITR5 (TIM_SMCR_TS_3 | TIM_SMCR_TS_0) /*!< Internal Trigger 5 (ITR5) is used as trigger input */
#define LL_TIM_TS_ITR6 (TIM_SMCR_TS_3 | TIM_SMCR_TS_1) /*!< Internal Trigger 6 (ITR6) is used as trigger input */
#define LL_TIM_TS_ITR7 (TIM_SMCR_TS_3 | TIM_SMCR_TS_1 | TIM_SMCR_TS_0) /*!< Internal Trigger 7 (ITR7) is used as trigger input */
#define LL_TIM_TS_ITR8 (TIM_SMCR_TS_3 | TIM_SMCR_TS_2) /*!< Internal Trigger 8 (ITR8) is used as trigger input */
#define LL_TIM_TS_ITR9 (TIM_SMCR_TS_3 | TIM_SMCR_TS_2 | TIM_SMCR_TS_0) /*!< Internal Trigger 9 (ITR9) is used as trigger input */
#define LL_TIM_TS_ITR10 (TIM_SMCR_TS_3 | TIM_SMCR_TS_2 | TIM_SMCR_TS_1) /*!< Internal Trigger 10 (ITR10) is used as trigger input */
#define LL_TIM_TS_ITR11 (TIM_SMCR_TS_3 | TIM_SMCR_TS_2 | TIM_SMCR_TS_1 | TIM_SMCR_TS_0) /*!< Internal Trigger 11 (ITR11) is used as trigger input */
#define LL_TIM_TS_TI1F_ED TIM_SMCR_TS_2 /*!< TI1 Edge Detector (TI1F_ED) is used as trigger input */
#define LL_TIM_TS_TI1FP1 (TIM_SMCR_TS_2 | TIM_SMCR_TS_0) /*!< Filtered Timer Input 1 (TI1FP1) is used as trigger input */
#define LL_TIM_TS_TI2FP2 (TIM_SMCR_TS_2 | TIM_SMCR_TS_1) /*!< Filtered Timer Input 2 (TI12P2) is used as trigger input */
#define LL_TIM_TS_ETRF (TIM_SMCR_TS_2 | TIM_SMCR_TS_1 | TIM_SMCR_TS_0) /*!< Filtered external Trigger (ETRF) is used as trigger input */
/**
* @}
*/
/** @defgroup TIM_LL_EC_ETR_POLARITY External Trigger Polarity
* @{
*/
#define LL_TIM_ETR_POLARITY_NONINVERTED 0x00000000U /*!< ETR is non-inverted, active at high level or rising edge */
#define LL_TIM_ETR_POLARITY_INVERTED TIM_SMCR_ETP /*!< ETR is inverted, active at low level or falling edge */
/**
* @}
*/
/** @defgroup TIM_LL_EC_ETR_PRESCALER External Trigger Prescaler
* @{
*/
#define LL_TIM_ETR_PRESCALER_DIV1 0x00000000U /*!< ETR prescaler OFF */
#define LL_TIM_ETR_PRESCALER_DIV2 TIM_SMCR_ETPS_0 /*!< ETR frequency is divided by 2 */
#define LL_TIM_ETR_PRESCALER_DIV4 TIM_SMCR_ETPS_1 /*!< ETR frequency is divided by 4 */
#define LL_TIM_ETR_PRESCALER_DIV8 TIM_SMCR_ETPS /*!< ETR frequency is divided by 8 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_ETR_FILTER External Trigger Filter
* @{
*/
#define LL_TIM_ETR_FILTER_FDIV1 0x00000000U /*!< No filter, sampling is done at fDTS */
#define LL_TIM_ETR_FILTER_FDIV1_N2 TIM_SMCR_ETF_0 /*!< fSAMPLING=fCK_INT, N=2 */
#define LL_TIM_ETR_FILTER_FDIV1_N4 TIM_SMCR_ETF_1 /*!< fSAMPLING=fCK_INT, N=4 */
#define LL_TIM_ETR_FILTER_FDIV1_N8 (TIM_SMCR_ETF_1 | TIM_SMCR_ETF_0) /*!< fSAMPLING=fCK_INT, N=8 */
#define LL_TIM_ETR_FILTER_FDIV2_N6 TIM_SMCR_ETF_2 /*!< fSAMPLING=fDTS/2, N=6 */
#define LL_TIM_ETR_FILTER_FDIV2_N8 (TIM_SMCR_ETF_2 | TIM_SMCR_ETF_0) /*!< fSAMPLING=fDTS/2, N=8 */
#define LL_TIM_ETR_FILTER_FDIV4_N6 (TIM_SMCR_ETF_2 | TIM_SMCR_ETF_1) /*!< fSAMPLING=fDTS/4, N=6 */
#define LL_TIM_ETR_FILTER_FDIV4_N8 (TIM_SMCR_ETF_2 | TIM_SMCR_ETF_1 | TIM_SMCR_ETF_0) /*!< fSAMPLING=fDTS/4, N=8 */
#define LL_TIM_ETR_FILTER_FDIV8_N6 TIM_SMCR_ETF_3 /*!< fSAMPLING=fDTS/8, N=6 */
#define LL_TIM_ETR_FILTER_FDIV8_N8 (TIM_SMCR_ETF_3 | TIM_SMCR_ETF_0) /*!< fSAMPLING=fDTS/16, N=8 */
#define LL_TIM_ETR_FILTER_FDIV16_N5 (TIM_SMCR_ETF_3 | TIM_SMCR_ETF_1) /*!< fSAMPLING=fDTS/16, N=5 */
#define LL_TIM_ETR_FILTER_FDIV16_N6 (TIM_SMCR_ETF_3 | TIM_SMCR_ETF_1 | TIM_SMCR_ETF_0) /*!< fSAMPLING=fDTS/16, N=6 */
#define LL_TIM_ETR_FILTER_FDIV16_N8 (TIM_SMCR_ETF_3 | TIM_SMCR_ETF_2) /*!< fSAMPLING=fDTS/16, N=8 */
#define LL_TIM_ETR_FILTER_FDIV32_N5 (TIM_SMCR_ETF_3 | TIM_SMCR_ETF_2 | TIM_SMCR_ETF_0) /*!< fSAMPLING=fDTS/32, N=5 */
#define LL_TIM_ETR_FILTER_FDIV32_N6 (TIM_SMCR_ETF_3 | TIM_SMCR_ETF_2 | TIM_SMCR_ETF_1) /*!< fSAMPLING=fDTS/32, N=6 */
#define LL_TIM_ETR_FILTER_FDIV32_N8 TIM_SMCR_ETF /*!< fSAMPLING=fDTS/32, N=8 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM1_ETRSOURCE External Trigger Source TIM1
* @{
*/
#define LL_TIM_TIM1_ETRSOURCE_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define LL_TIM_TIM1_ETRSOURCE_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define LL_TIM_TIM1_ETRSOURCE_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define LL_TIM_TIM1_ETRSOURCE_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define LL_TIM_TIM1_ETRSOURCE_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM1_ETRSOURCE_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM1_ETRSOURCE_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM1_ETRSOURCE_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define LL_TIM_TIM1_ETRSOURCE_ADC1_AWD1 TIM1_AF1_ETRSEL_3 /*!< ADC1 analog watchdog 1 */
#define LL_TIM_TIM1_ETRSOURCE_ADC1_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ADC1 analog watchdog 2 */
#define LL_TIM_TIM1_ETRSOURCE_ADC1_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ADC1 analog watchdog 3 */
#if defined(ADC4)
#define LL_TIM_TIM1_ETRSOURCE_ADC4_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC4 analog watchdog 1 */
#define LL_TIM_TIM1_ETRSOURCE_ADC4_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC4 analog watchdog 2 */
#define LL_TIM_TIM1_ETRSOURCE_ADC4_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC4 analog watchdog 3 */
#endif /* ADC4 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM2_ETRSOURCE External Trigger Source TIM2
* @{
*/
#define LL_TIM_TIM2_ETRSOURCE_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define LL_TIM_TIM2_ETRSOURCE_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define LL_TIM_TIM2_ETRSOURCE_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define LL_TIM_TIM2_ETRSOURCE_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define LL_TIM_TIM2_ETRSOURCE_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM2_ETRSOURCE_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM2_ETRSOURCE_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM2_ETRSOURCE_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define LL_TIM_TIM2_ETRSOURCE_TIM3_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM3 ETR */
#define LL_TIM_TIM2_ETRSOURCE_TIM4_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM4 ETR */
#if defined(TIM5)
#define LL_TIM_TIM2_ETRSOURCE_TIM5_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to TIM5 ETR */
#endif /* TIM5 */
#define LL_TIM_TIM2_ETRSOURCE_LSE (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to LSE */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM3_ETRSOURCE External Trigger Source TIM3
* @{
*/
#define LL_TIM_TIM3_ETRSOURCE_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define LL_TIM_TIM3_ETRSOURCE_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define LL_TIM_TIM3_ETRSOURCE_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define LL_TIM_TIM3_ETRSOURCE_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define LL_TIM_TIM3_ETRSOURCE_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM3_ETRSOURCE_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM3_ETRSOURCE_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM3_ETRSOURCE_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define LL_TIM_TIM3_ETRSOURCE_TIM2_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM2 ETR */
#define LL_TIM_TIM3_ETRSOURCE_TIM4_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM4 ETR */
#define LL_TIM_TIM3_ETRSOURCE_ADC2_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC2 analog watchdog 1 */
#define LL_TIM_TIM3_ETRSOURCE_ADC2_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC2 analog watchdog 2 */
#define LL_TIM_TIM3_ETRSOURCE_ADC2_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC2 analog watchdog 3 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM4_ETRSOURCE External Trigger Source TIM4
* @{
*/
#define LL_TIM_TIM4_ETRSOURCE_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define LL_TIM_TIM4_ETRSOURCE_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define LL_TIM_TIM4_ETRSOURCE_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define LL_TIM_TIM4_ETRSOURCE_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define LL_TIM_TIM4_ETRSOURCE_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM4_ETRSOURCE_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM4_ETRSOURCE_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM4_ETRSOURCE_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define LL_TIM_TIM4_ETRSOURCE_TIM3_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM3 ETR */
#if defined(TIM5)
#define LL_TIM_TIM4_ETRSOURCE_TIM5_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM5 ETR */
#endif /* TIM5 */
/**
* @}
*/
#if defined(TIM5)
/** @defgroup TIM_LL_EC_TIM5_ETRSOURCE External Trigger Source TIM5
* @{
*/
#define LL_TIM_TIM5_ETRSOURCE_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define LL_TIM_TIM5_ETRSOURCE_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define LL_TIM_TIM5_ETRSOURCE_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define LL_TIM_TIM5_ETRSOURCE_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define LL_TIM_TIM5_ETRSOURCE_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM5_ETRSOURCE_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM5_ETRSOURCE_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM5_ETRSOURCE_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define LL_TIM_TIM5_ETRSOURCE_TIM2_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM2 ETR */
#define LL_TIM_TIM5_ETRSOURCE_TIM3_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM3 ETR */
/**
* @}
*/
#endif /* TIM5 */
/** @defgroup TIM_LL_EC_TIM8_ETRSOURCE External Trigger Source TIM8
* @{
*/
#define LL_TIM_TIM8_ETRSOURCE_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define LL_TIM_TIM8_ETRSOURCE_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define LL_TIM_TIM8_ETRSOURCE_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define LL_TIM_TIM8_ETRSOURCE_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define LL_TIM_TIM8_ETRSOURCE_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM8_ETRSOURCE_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM8_ETRSOURCE_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM8_ETRSOURCE_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define LL_TIM_TIM8_ETRSOURCE_ADC2_AWD1 TIM1_AF1_ETRSEL_3 /*!< ADC2 analog watchdog 1 */
#define LL_TIM_TIM8_ETRSOURCE_ADC2_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ADC2 analog watchdog 2 */
#define LL_TIM_TIM8_ETRSOURCE_ADC2_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ADC2 analog watchdog 3 */
#if defined(ADC3)
#define LL_TIM_TIM8_ETRSOURCE_ADC3_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC3 analog watchdog 1 */
#define LL_TIM_TIM8_ETRSOURCE_ADC3_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC3 analog watchdog 2 */
#define LL_TIM_TIM8_ETRSOURCE_ADC3_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC3 analog watchdog 3 */
#endif /* ADC3 */
/**
* @}
*/
#if defined(TIM20)
/** @defgroup TIM_LL_EC_TIM20_ETRSOURCE External Trigger Source TIM20
* @{
*/
#define LL_TIM_TIM20_ETRSOURCE_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define LL_TIM_TIM20_ETRSOURCE_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define LL_TIM_TIM20_ETRSOURCE_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define LL_TIM_TIM20_ETRSOURCE_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define LL_TIM_TIM20_ETRSOURCE_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM20_ETRSOURCE_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM20_ETRSOURCE_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM20_ETRSOURCE_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#if defined(ADC3)
#define LL_TIM_TIM20_ETRSOURCE_ADC3_AWD1 TIM1_AF1_ETRSEL_3 /*!< ADC3 analog watchdog 1 */
#define LL_TIM_TIM20_ETRSOURCE_ADC3_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ADC3 analog watchdog 2 */
#define LL_TIM_TIM20_ETRSOURCE_ADC3_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ADC3 analog watchdog 3 */
#endif /* ADC3 */
#if defined(ADC5)
#define LL_TIM_TIM20_ETRSOURCE_ADC5_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC5 analog watchdog 1 */
#define LL_TIM_TIM20_ETRSOURCE_ADC5_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC5 analog watchdog 2 */
#define LL_TIM_TIM20_ETRSOURCE_ADC5_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC5 analog watchdog 3 */
#endif /* ADC5 */
/**
* @}
*/
#endif /* TIM20 */
/** @defgroup TIM_LL_EC_BREAK_POLARITY break polarity
* @{
*/
#define LL_TIM_BREAK_POLARITY_LOW 0x00000000U /*!< Break input BRK is active low */
#define LL_TIM_BREAK_POLARITY_HIGH TIM_BDTR_BKP /*!< Break input BRK is active high */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BREAK_FILTER break filter
* @{
*/
#define LL_TIM_BREAK_FILTER_FDIV1 0x00000000U /*!< No filter, BRK acts asynchronously */
#define LL_TIM_BREAK_FILTER_FDIV1_N2 0x00010000U /*!< fSAMPLING=fCK_INT, N=2 */
#define LL_TIM_BREAK_FILTER_FDIV1_N4 0x00020000U /*!< fSAMPLING=fCK_INT, N=4 */
#define LL_TIM_BREAK_FILTER_FDIV1_N8 0x00030000U /*!< fSAMPLING=fCK_INT, N=8 */
#define LL_TIM_BREAK_FILTER_FDIV2_N6 0x00040000U /*!< fSAMPLING=fDTS/2, N=6 */
#define LL_TIM_BREAK_FILTER_FDIV2_N8 0x00050000U /*!< fSAMPLING=fDTS/2, N=8 */
#define LL_TIM_BREAK_FILTER_FDIV4_N6 0x00060000U /*!< fSAMPLING=fDTS/4, N=6 */
#define LL_TIM_BREAK_FILTER_FDIV4_N8 0x00070000U /*!< fSAMPLING=fDTS/4, N=8 */
#define LL_TIM_BREAK_FILTER_FDIV8_N6 0x00080000U /*!< fSAMPLING=fDTS/8, N=6 */
#define LL_TIM_BREAK_FILTER_FDIV8_N8 0x00090000U /*!< fSAMPLING=fDTS/8, N=8 */
#define LL_TIM_BREAK_FILTER_FDIV16_N5 0x000A0000U /*!< fSAMPLING=fDTS/16, N=5 */
#define LL_TIM_BREAK_FILTER_FDIV16_N6 0x000B0000U /*!< fSAMPLING=fDTS/16, N=6 */
#define LL_TIM_BREAK_FILTER_FDIV16_N8 0x000C0000U /*!< fSAMPLING=fDTS/16, N=8 */
#define LL_TIM_BREAK_FILTER_FDIV32_N5 0x000D0000U /*!< fSAMPLING=fDTS/32, N=5 */
#define LL_TIM_BREAK_FILTER_FDIV32_N6 0x000E0000U /*!< fSAMPLING=fDTS/32, N=6 */
#define LL_TIM_BREAK_FILTER_FDIV32_N8 0x000F0000U /*!< fSAMPLING=fDTS/32, N=8 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BREAK2_POLARITY BREAK2 POLARITY
* @{
*/
#define LL_TIM_BREAK2_POLARITY_LOW 0x00000000U /*!< Break input BRK2 is active low */
#define LL_TIM_BREAK2_POLARITY_HIGH TIM_BDTR_BK2P /*!< Break input BRK2 is active high */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BREAK2_FILTER BREAK2 FILTER
* @{
*/
#define LL_TIM_BREAK2_FILTER_FDIV1 0x00000000U /*!< No filter, BRK acts asynchronously */
#define LL_TIM_BREAK2_FILTER_FDIV1_N2 0x00100000U /*!< fSAMPLING=fCK_INT, N=2 */
#define LL_TIM_BREAK2_FILTER_FDIV1_N4 0x00200000U /*!< fSAMPLING=fCK_INT, N=4 */
#define LL_TIM_BREAK2_FILTER_FDIV1_N8 0x00300000U /*!< fSAMPLING=fCK_INT, N=8 */
#define LL_TIM_BREAK2_FILTER_FDIV2_N6 0x00400000U /*!< fSAMPLING=fDTS/2, N=6 */
#define LL_TIM_BREAK2_FILTER_FDIV2_N8 0x00500000U /*!< fSAMPLING=fDTS/2, N=8 */
#define LL_TIM_BREAK2_FILTER_FDIV4_N6 0x00600000U /*!< fSAMPLING=fDTS/4, N=6 */
#define LL_TIM_BREAK2_FILTER_FDIV4_N8 0x00700000U /*!< fSAMPLING=fDTS/4, N=8 */
#define LL_TIM_BREAK2_FILTER_FDIV8_N6 0x00800000U /*!< fSAMPLING=fDTS/8, N=6 */
#define LL_TIM_BREAK2_FILTER_FDIV8_N8 0x00900000U /*!< fSAMPLING=fDTS/8, N=8 */
#define LL_TIM_BREAK2_FILTER_FDIV16_N5 0x00A00000U /*!< fSAMPLING=fDTS/16, N=5 */
#define LL_TIM_BREAK2_FILTER_FDIV16_N6 0x00B00000U /*!< fSAMPLING=fDTS/16, N=6 */
#define LL_TIM_BREAK2_FILTER_FDIV16_N8 0x00C00000U /*!< fSAMPLING=fDTS/16, N=8 */
#define LL_TIM_BREAK2_FILTER_FDIV32_N5 0x00D00000U /*!< fSAMPLING=fDTS/32, N=5 */
#define LL_TIM_BREAK2_FILTER_FDIV32_N6 0x00E00000U /*!< fSAMPLING=fDTS/32, N=6 */
#define LL_TIM_BREAK2_FILTER_FDIV32_N8 0x00F00000U /*!< fSAMPLING=fDTS/32, N=8 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_OSSI OSSI
* @{
*/
#define LL_TIM_OSSI_DISABLE 0x00000000U /*!< When inactive, OCx/OCxN outputs are disabled */
#define LL_TIM_OSSI_ENABLE TIM_BDTR_OSSI /*!< When inactive, OxC/OCxN outputs are first forced with their inactive level then forced to their idle level after the deadtime */
/**
* @}
*/
/** @defgroup TIM_LL_EC_OSSR OSSR
* @{
*/
#define LL_TIM_OSSR_DISABLE 0x00000000U /*!< When inactive, OCx/OCxN outputs are disabled */
#define LL_TIM_OSSR_ENABLE TIM_BDTR_OSSR /*!< When inactive, OC/OCN outputs are enabled with their inactive level as soon as CCxE=1 or CCxNE=1 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BREAK_INPUT BREAK INPUT
* @{
*/
#define LL_TIM_BREAK_INPUT_BKIN 0x00000000U /*!< TIMx_BKIN input */
#define LL_TIM_BREAK_INPUT_BKIN2 0x00000004U /*!< TIMx_BKIN2 input */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BKIN_SOURCE BKIN SOURCE
* @{
*/
#define LL_TIM_BKIN_SOURCE_BKIN TIM1_AF1_BKINE /*!< BKIN input from AF controller */
#define LL_TIM_BKIN_SOURCE_BKCOMP1 TIM1_AF1_BKCMP1E /*!< internal signal: COMP1 output */
#define LL_TIM_BKIN_SOURCE_BKCOMP2 TIM1_AF1_BKCMP2E /*!< internal signal: COMP2 output */
#define LL_TIM_BKIN_SOURCE_BKCOMP3 TIM1_AF1_BKCMP3E /*!< internal signal: COMP3 output */
#define LL_TIM_BKIN_SOURCE_BKCOMP4 TIM1_AF1_BKCMP4E /*!< internal signal: COMP4 output */
#if defined(COMP5)
#define LL_TIM_BKIN_SOURCE_BKCOMP5 TIM1_AF1_BKCMP5E /*!< internal signal: COMP5 output */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_BKIN_SOURCE_BKCOMP6 TIM1_AF1_BKCMP6E /*!< internal signal: COMP6 output */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_BKIN_SOURCE_BKCOMP7 TIM1_AF1_BKCMP7E /*!< internal signal: COMP7 output */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BKIN_POLARITY BKIN POLARITY
* @{
*/
#define LL_TIM_BKIN_POLARITY_LOW TIM1_AF1_BKINP /*!< BRK BKIN input is active low */
#define LL_TIM_BKIN_POLARITY_HIGH 0x00000000U /*!< BRK BKIN input is active high */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BREAK_AFMODE BREAK AF MODE
* @{
*/
#define LL_TIM_BREAK_AFMODE_INPUT 0x00000000U /*!< Break input BRK in input mode */
#define LL_TIM_BREAK_AFMODE_BIDIRECTIONAL TIM_BDTR_BKBID /*!< Break input BRK in bidirectional mode */
/**
* @}
*/
/** @defgroup TIM_LL_EC_BREAK2_AFMODE BREAK2 AF MODE
* @{
*/
#define LL_TIM_BREAK2_AFMODE_INPUT 0x00000000U /*!< Break2 input BRK2 in input mode */
#define LL_TIM_BREAK2_AFMODE_BIDIRECTIONAL TIM_BDTR_BK2BID /*!< Break2 input BRK2 in bidirectional mode */
/**
* @}
*/
/** Legacy definitions for compatibility purpose
@cond 0
*/
#define LL_TIM_ReArmBRK(_PARAM_)
#define LL_TIM_ReArmBRK2(_PARAM_)
/**
@endcond
*/
/** @defgroup TIM_LL_EC_DMABURST_BASEADDR DMA Burst Base Address
* @{
*/
#define LL_TIM_DMABURST_BASEADDR_CR1 0x00000000U /*!< TIMx_CR1 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CR2 TIM_DCR_DBA_0 /*!< TIMx_CR2 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_SMCR TIM_DCR_DBA_1 /*!< TIMx_SMCR register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_DIER (TIM_DCR_DBA_1 | TIM_DCR_DBA_0) /*!< TIMx_DIER register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_SR TIM_DCR_DBA_2 /*!< TIMx_SR register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_EGR (TIM_DCR_DBA_2 | TIM_DCR_DBA_0) /*!< TIMx_EGR register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCMR1 (TIM_DCR_DBA_2 | TIM_DCR_DBA_1) /*!< TIMx_CCMR1 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCMR2 (TIM_DCR_DBA_2 | TIM_DCR_DBA_1 | TIM_DCR_DBA_0) /*!< TIMx_CCMR2 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCER TIM_DCR_DBA_3 /*!< TIMx_CCER register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CNT (TIM_DCR_DBA_3 | TIM_DCR_DBA_0) /*!< TIMx_CNT register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_PSC (TIM_DCR_DBA_3 | TIM_DCR_DBA_1) /*!< TIMx_PSC register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_ARR (TIM_DCR_DBA_3 | TIM_DCR_DBA_1 | TIM_DCR_DBA_0) /*!< TIMx_ARR register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_RCR (TIM_DCR_DBA_3 | TIM_DCR_DBA_2) /*!< TIMx_RCR register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCR1 (TIM_DCR_DBA_3 | TIM_DCR_DBA_2 | TIM_DCR_DBA_0) /*!< TIMx_CCR1 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCR2 (TIM_DCR_DBA_3 | TIM_DCR_DBA_2 | TIM_DCR_DBA_1) /*!< TIMx_CCR2 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCR3 (TIM_DCR_DBA_3 | TIM_DCR_DBA_2 | TIM_DCR_DBA_1 | TIM_DCR_DBA_0) /*!< TIMx_CCR3 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCR4 TIM_DCR_DBA_4 /*!< TIMx_CCR4 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_BDTR (TIM_DCR_DBA_4 | TIM_DCR_DBA_0) /*!< TIMx_BDTR register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCR5 (TIM_DCR_DBA_4 | TIM_DCR_DBA_1) /*!< TIMx_CCR5 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCR6 (TIM_DCR_DBA_4 | TIM_DCR_DBA_1 | TIM_DCR_DBA_0) /*!< TIMx_CCR6 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_CCMR3 (TIM_DCR_DBA_4 | TIM_DCR_DBA_2) /*!< TIMx_CCMR3 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_DTR2 (TIM_DCR_DBA_4 | TIM_DCR_DBA_2 | TIM_DCR_DBA_0) /*!< TIMx_DTR2 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_ECR (TIM_DCR_DBA_4 | TIM_DCR_DBA_2 | TIM_DCR_DBA_1) /*!< TIMx_ECR register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_TISEL (TIM_DCR_DBA_4 | TIM_DCR_DBA_2 | TIM_DCR_DBA_1 | TIM_DCR_DBA_0) /*!< TIMx_TISEL register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_AF1 (TIM_DCR_DBA_4 | TIM_DCR_DBA_3) /*!< TIMx_AF1 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_AF2 (TIM_DCR_DBA_4 | TIM_DCR_DBA_3 | TIM_DCR_DBA_0) /*!< TIMx_AF2 register is the DMA base address for DMA burst */
#define LL_TIM_DMABURST_BASEADDR_OR (TIM_DCR_DBA_4 | TIM_DCR_DBA_3 | TIM_DCR_DBA_1) /*!< TIMx_OR register is the DMA base address for DMA burst */
/**
* @}
*/
/** @defgroup TIM_LL_EC_DMABURST_LENGTH DMA Burst Length
* @{
*/
#define LL_TIM_DMABURST_LENGTH_1TRANSFER 0x00000000U /*!< Transfer is done to 1 register starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_2TRANSFERS TIM_DCR_DBL_0 /*!< Transfer is done to 2 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_3TRANSFERS TIM_DCR_DBL_1 /*!< Transfer is done to 3 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_4TRANSFERS (TIM_DCR_DBL_1 | TIM_DCR_DBL_0) /*!< Transfer is done to 4 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_5TRANSFERS TIM_DCR_DBL_2 /*!< Transfer is done to 5 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_6TRANSFERS (TIM_DCR_DBL_2 | TIM_DCR_DBL_0) /*!< Transfer is done to 6 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_7TRANSFERS (TIM_DCR_DBL_2 | TIM_DCR_DBL_1) /*!< Transfer is done to 7 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_8TRANSFERS (TIM_DCR_DBL_2 | TIM_DCR_DBL_1 | TIM_DCR_DBL_0) /*!< Transfer is done to 1 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_9TRANSFERS TIM_DCR_DBL_3 /*!< Transfer is done to 9 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_10TRANSFERS (TIM_DCR_DBL_3 | TIM_DCR_DBL_0) /*!< Transfer is done to 10 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_11TRANSFERS (TIM_DCR_DBL_3 | TIM_DCR_DBL_1) /*!< Transfer is done to 11 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_12TRANSFERS (TIM_DCR_DBL_3 | TIM_DCR_DBL_1 | TIM_DCR_DBL_0) /*!< Transfer is done to 12 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_13TRANSFERS (TIM_DCR_DBL_3 | TIM_DCR_DBL_2) /*!< Transfer is done to 13 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_14TRANSFERS (TIM_DCR_DBL_3 | TIM_DCR_DBL_2 | TIM_DCR_DBL_0) /*!< Transfer is done to 14 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_15TRANSFERS (TIM_DCR_DBL_3 | TIM_DCR_DBL_2 | TIM_DCR_DBL_1) /*!< Transfer is done to 15 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_16TRANSFERS (TIM_DCR_DBL_3 | TIM_DCR_DBL_2 | TIM_DCR_DBL_1 | TIM_DCR_DBL_0) /*!< Transfer is done to 16 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_17TRANSFERS TIM_DCR_DBL_4 /*!< Transfer is done to 17 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_18TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_0) /*!< Transfer is done to 18 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_19TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_1) /*!< Transfer is done to 19 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_20TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_1 | TIM_DCR_DBL_0) /*!< Transfer is done to 20 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_21TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_2) /*!< Transfer is done to 21 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_22TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_2 | TIM_DCR_DBL_0) /*!< Transfer is done to 22 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_23TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_2 | TIM_DCR_DBL_1) /*!< Transfer is done to 23 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_24TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_2 | TIM_DCR_DBL_1 | TIM_DCR_DBL_0) /*!< Transfer is done to 24 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_25TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_3) /*!< Transfer is done to 25 registers starting from the DMA burst base address */
#define LL_TIM_DMABURST_LENGTH_26TRANSFERS (TIM_DCR_DBL_4 | TIM_DCR_DBL_3 | TIM_DCR_DBL_0) /*!< Transfer is done to 26 registers starting from the DMA burst base address */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM1_TI1_RMP TIM1 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM1_TI1_RMP_GPIO 0x00000000U /*!< TIM1 input 1 is connected to GPIO */
#define LL_TIM_TIM1_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM1 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM1_TI1_RMP_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM1 input 1 is connected to COMP2_OUT */
#define LL_TIM_TIM1_TI1_RMP_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM1 input 1 is connected to COMP3_OUT */
#define LL_TIM_TIM1_TI1_RMP_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM1 input 1 is connected to COMP4_OUT */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM2_TI1_RMP TIM2 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM2_TI1_RMP_GPIO 0x00000000U /*!< TIM2 input 1 is connected to GPIO */
#define LL_TIM_TIM2_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM2 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM2_TI1_RMP_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM2 input 1 is connected to COMP2_OUT */
#define LL_TIM_TIM2_TI1_RMP_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM2 input 1 is connected to COMP3_OUT */
#define LL_TIM_TIM2_TI1_RMP_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM2 input 1 is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM2_TI1_RMP_COMP5 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM2 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM2_TI2_RMP TIM2 Timer Input Ch2 Remap
* @{
*/
#define LL_TIM_TIM2_TI2_RMP_GPIO 0x00000000U /*!< TIM2 input 2 is connected to GPIO */
#define LL_TIM_TIM2_TI2_RMP_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM2 input 2 is connected to COMP1_OUT */
#define LL_TIM_TIM2_TI2_RMP_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM2 input 2 is connected to COMP2_OUT */
#define LL_TIM_TIM2_TI2_RMP_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM2 input 2 is connected to COMP3_OUT */
#define LL_TIM_TIM2_TI2_RMP_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM2 input 2 is connected to COMP4_OUT */
#if defined(COMP6)
#define LL_TIM_TIM2_TI2_RMP_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM2 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM2_TI3_RMP TIM2 Timer Input Ch3 Remap
* @{
*/
#define LL_TIM_TIM2_TI3_RMP_GPIO 0x00000000U /*!< TIM2 input 3 is connected to GPIO */
#define LL_TIM_TIM2_TI3_RMP_COMP4 TIM_TISEL_TI3SEL_0 /*!< TIM2 input 3 is connected to COMP4_OUT */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM2_TI4_RMP TIM2 Timer Input Ch4 Remap
* @{
*/
#define LL_TIM_TIM2_TI4_RMP_GPIO 0x00000000U /*!< TIM2 input 4 is connected to GPIO */
#define LL_TIM_TIM2_TI4_RMP_COMP1 TIM_TISEL_TI4SEL_0 /*!< TIM2 input 4 is connected to COMP1_OUT */
#define LL_TIM_TIM2_TI4_RMP_COMP2 TIM_TISEL_TI4SEL_1 /*!< TIM2 input 4 is connected to COMP2_OUT */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM3_TI1_RMP TIM3 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM3_TI1_RMP_GPIO 0x00000000U /*!< TIM3 input 1 is connected to GPIO */
#define LL_TIM_TIM3_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM3 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM3_TI1_RMP_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM3 input 1 is connected to COMP2_OUT */
#define LL_TIM_TIM3_TI1_RMP_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM3 input 1 is connected to COMP3_OUT */
#define LL_TIM_TIM3_TI1_RMP_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM3 input 1 is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM3_TI1_RMP_COMP5 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM3 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM3_TI1_RMP_COMP6 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM3 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM3_TI1_RMP_COMP7 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM3 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM3_TI2_RMP TIM3 Timer Input Ch2 Remap
* @{
*/
#define LL_TIM_TIM3_TI2_RMP_GPIO 0x00000000U /*!< TIM3 input 2 is connected to GPIO */
#define LL_TIM_TIM3_TI2_RMP_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM3 input 2 is connected to COMP1_OUT */
#define LL_TIM_TIM3_TI2_RMP_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM3 input 2 is connected to COMP2_OUT */
#define LL_TIM_TIM3_TI2_RMP_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM3 input 2 is connected to COMP3_OUT */
#define LL_TIM_TIM3_TI2_RMP_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM3 input 2 is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM3_TI2_RMP_COMP5 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM3 input 2 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM3_TI2_RMP_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1) /*!< TIM3 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM3_TI2_RMP_COMP7 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM3 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM3_TI3_RMP TIM3 Timer Input Ch3 Remap
* @{
*/
#define LL_TIM_TIM3_TI3_RMP_GPIO 0x00000000U /*!< TIM3 input 3 is connected to GPIO */
#define LL_TIM_TIM3_TI3_RMP_COMP3 TIM_TISEL_TI3SEL_0 /*!< TIM3 input 3 is connected to COMP3_OUT */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM4_TI1_RMP TIM4 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM4_TI1_RMP_GPIO 0x00000000U /*!< TIM4 input 1 is connected to GPIO */
#define LL_TIM_TIM4_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM4 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM4_TI1_RMP_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM4 input 1 is connected to COMP2_OUT */
#define LL_TIM_TIM4_TI1_RMP_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM4 input 1 is connected to COMP3_OUT */
#define LL_TIM_TIM4_TI1_RMP_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM4 input 1 is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM4_TI1_RMP_COMP5 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM4 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM4_TI1_RMP_COMP6 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM4 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM4_TI1_RMP_COMP7 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM4 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM4_TI2_RMP TIM4 Timer Input Ch2 Remap
* @{
*/
#define LL_TIM_TIM4_TI2_RMP_GPIO 0x00000000U /*!< TIM4 input 2 is connected to GPIO */
#define LL_TIM_TIM4_TI2_RMP_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM4 input 2 is connected to COMP1_OUT */
#define LL_TIM_TIM4_TI2_RMP_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM4 input 2 is connected to COMP2_OUT */
#define LL_TIM_TIM4_TI2_RMP_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM4 input 2 is connected to COMP3_OUT */
#define LL_TIM_TIM4_TI2_RMP_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM4 input 2 is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM4_TI2_RMP_COMP5 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM4 input 2 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM4_TI2_RMP_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1) /*!< TIM4 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM4_TI2_RMP_COMP7 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM4 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM4_TI3_RMP TIM4 Timer Input Ch3 Remap
* @{
*/
#define LL_TIM_TIM4_TI3_RMP_GPIO 0x00000000U /*!< TIM4 input 3 is connected to GPIO */
#if defined(COMP5)
#define LL_TIM_TIM4_TI3_RMP_COMP5 TIM_TISEL_TI3SEL_0 /*!< TIM4 input 3 is connected to COMP5_OUT */
#endif /* COMP5 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM4_TI4_RMP TIM4 Timer Input Ch4 Remap
* @{
*/
#define LL_TIM_TIM4_TI4_RMP_GPIO 0x00000000U /*!< TIM4 input 4 is connected to GPIO */
#if defined(COMP6)
#define LL_TIM_TIM4_TI4_RMP_COMP6 TIM_TISEL_TI4SEL_0 /*!< TIM4 input 4 is connected to COMP6_OUT */
#endif /* COMP6 */
/**
* @}
*/
#if defined(TIM5)
/** @defgroup TIM_LL_EC_TIM5_TI1_RMP TIM5 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM5_TI1_RMP_GPIO 0x00000000U /*!< TIM5 input 1 is connected to GPIO */
#define LL_TIM_TIM5_TI1_RMP_LSI TIM_TISEL_TI1SEL_0 /*!< TIM5 input 1 is connected to LSI */
#define LL_TIM_TIM5_TI1_RMP_LSE TIM_TISEL_TI1SEL_1 /*!< TIM5 input 1 is connected to LSE */
#define LL_TIM_TIM5_TI1_RMP_RTC_WK (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to RTC_WAKEUP */
#define LL_TIM_TIM5_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_2 /*!< TIM5 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM5_TI1_RMP_COMP2 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to COMP2_OUT */
#define LL_TIM_TIM5_TI1_RMP_COMP3 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM5 input 1 is connected to COMP3_OUT */
#define LL_TIM_TIM5_TI1_RMP_COMP4 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM5_TI1_RMP_COMP5 TIM_TISEL_TI1SEL_3 /*!< TIM5 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM5_TI1_RMP_COMP6 (TIM_TISEL_TI1SEL_3 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM5_TI1_RMP_COMP7 (TIM_TISEL_TI1SEL_3 | TIM_TISEL_TI1SEL_1) /*!< TIM5 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM5_TI2_RMP TIM5 Timer Input Ch2 Remap
* @{
*/
#define LL_TIM_TIM5_TI2_RMP_GPIO 0x00000000U /*!< TIM5 input 2 is connected to GPIO */
#define LL_TIM_TIM5_TI2_RMP_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM5 input 2 is connected to COMP1_OUT */
#define LL_TIM_TIM5_TI2_RMP_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM5 input 2 is connected to COMP2_OUT */
#define LL_TIM_TIM5_TI2_RMP_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM5 input 2 is connected to COMP3_OUT */
#define LL_TIM_TIM5_TI2_RMP_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM5 input 2 is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_TIM5_TI2_RMP_COMP5 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM5 input 2 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_TIM5_TI2_RMP_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1) /*!< TIM5 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM5_TI2_RMP_COMP7 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM5 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
#endif /* TIM5 */
/** @defgroup TIM_LL_EC_TIM8_TI1_RMP TIM8 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM8_TI1_RMP_GPIO 0x00000000U /*!< TIM8 input 1 is connected to GPIO */
#define LL_TIM_TIM8_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM8 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM8_TI1_RMP_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM8 input 1 is connected to COMP2_OUT */
#define LL_TIM_TIM8_TI1_RMP_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM8 input 1 is connected to COMP3_OUT */
#define LL_TIM_TIM8_TI1_RMP_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM8 input 1 is connected to COMP4_OUT */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM15_TI1_RMP TIM15 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM15_TI1_RMP_GPIO 0x00000000U /*!< TIM15 input 1 is connected to GPIO */
#define LL_TIM_TIM15_TI1_RMP_LSE TIM_TISEL_TI1SEL_0 /*!< TIM15 input 1 is connected to LSE */
#define LL_TIM_TIM15_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_1 /*!< TIM15 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM15_TI1_RMP_COMP2 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM15 input 1 is connected to COMP2_OUT */
#if defined(COMP5)
#define LL_TIM_TIM15_TI1_RMP_COMP5 TIM_TISEL_TI1SEL_2 /*!< TIM15 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP7)
#define LL_TIM_TIM15_TI1_RMP_COMP7 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM15 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM15_TI2_RMP TIM15 Timer Input Ch2 Remap
* @{
*/
#define LL_TIM_TIM15_TI2_RMP_GPIO 0x00000000U /*!< TIM15 input 2 is connected to GPIO */
#define LL_TIM_TIM15_TI2_RMP_COMP2 TIM_TISEL_TI2SEL_0 /*!< TIM15 input 2 is connected to COMP2_OUT */
#define LL_TIM_TIM15_TI2_RMP_COMP3 TIM_TISEL_TI2SEL_1 /*!< TIM15 input 2 is connected to COMP3_OUT */
#if defined(COMP6)
#define LL_TIM_TIM15_TI2_RMP_COMP6 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM15 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_TIM15_TI2_RMP_COMP7 TIM_TISEL_TI2SEL_2 /*!< TIM15 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM16_TI1_RMP TIM16 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM16_TI1_RMP_GPIO 0x00000000U /*!< TIM16 input 1 is connected to GPIO */
#if defined(COMP6)
#define LL_TIM_TIM16_TI1_RMP_COMP6 TIM_TISEL_TI1SEL_0 /*!< TIM16 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#define LL_TIM_TIM16_TI1_RMP_MCO TIM_TISEL_TI1SEL_1 /*!< TIM16 input 1 is connected to MCO */
#define LL_TIM_TIM16_TI1_RMP_HSE_32 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM16 input 1 is connected to HSE/32 */
#define LL_TIM_TIM16_TI1_RMP_RTC_WK TIM_TISEL_TI1SEL_2 /*!< TIM16 input 1 is connected to RTC_WAKEUP */
#define LL_TIM_TIM16_TI1_RMP_LSE (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM16 input 1 is connected to LSE */
#define LL_TIM_TIM16_TI1_RMP_LSI (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM16 input 1 is connected to LSI */
/**
* @}
*/
/** @defgroup TIM_LL_EC_TIM17_TI1_RMP TIM17 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM17_TI1_RMP_GPIO 0x00000000U /*!< TIM17 input 1 is connected to GPIO */
#if defined(COMP5)
#define LL_TIM_TIM17_TI1_RMP_COMP5 TIM_TISEL_TI1SEL_0 /*!< TIM17 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#define LL_TIM_TIM17_TI1_RMP_MCO TIM_TISEL_TI1SEL_1 /*!< TIM17 input 1 is connected to MCO */
#define LL_TIM_TIM17_TI1_RMP_HSE_32 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM17 input 1 is connected to HSE/32 */
#define LL_TIM_TIM17_TI1_RMP_RTC_WK TIM_TISEL_TI1SEL_2 /*!< TIM17 input 1 is connected to RTC_WAKEUP */
#define LL_TIM_TIM17_TI1_RMP_LSE (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM17 input 1 is connected to LSE */
#define LL_TIM_TIM17_TI1_RMP_LSI (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM17 input 1 is connected to LSI */
/**
* @}
*/
#if defined(TIM20)
/** @defgroup TIM_LL_EC_TIM20_TI1_RMP TIM20 Timer Input Ch1 Remap
* @{
*/
#define LL_TIM_TIM20_TI1_RMP_GPIO 0x00000000U /*!< TIM20 input 1 is connected to GPIO */
#define LL_TIM_TIM20_TI1_RMP_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM20 input 1 is connected to COMP1_OUT */
#define LL_TIM_TIM20_TI1_RMP_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM20 input 1 is connected to COMP2_OUT */
#define LL_TIM_TIM20_TI1_RMP_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM20 input 1 is connected to COMP3_OUT */
#define LL_TIM_TIM20_TI1_RMP_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM20 input 1 is connected to COMP4_OUT */
/**
* @}
*/
#endif /* TIM20 */
/** @defgroup TIM_LL_EC_OCREF_CLR_INT OCREF clear input selection
* @{
*/
#define LL_TIM_OCREF_CLR_INT_ETR OCREF_CLEAR_SELECT_Msk /*!< OCREF_CLR_INT is connected to ETRF */
#define LL_TIM_OCREF_CLR_INT_COMP1 0x00000000U /*!< OCREF clear input is connected to COMP1_OUT */
#define LL_TIM_OCREF_CLR_INT_COMP2 TIM1_AF2_OCRSEL_0 /*!< OCREF clear input is connected to COMP2_OUT */
#define LL_TIM_OCREF_CLR_INT_COMP3 TIM1_AF2_OCRSEL_1 /*!< OCREF clear input is connected to COMP3_OUT */
#define LL_TIM_OCREF_CLR_INT_COMP4 (TIM1_AF2_OCRSEL_1 | TIM1_AF2_OCRSEL_0) /*!< OCREF clear input is connected to COMP4_OUT */
#if defined(COMP5)
#define LL_TIM_OCREF_CLR_INT_COMP5 TIM1_AF2_OCRSEL_2 /*!< OCREF clear input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define LL_TIM_OCREF_CLR_INT_COMP6 (TIM1_AF2_OCRSEL_2 | TIM1_AF2_OCRSEL_0) /*!< OCREF clear input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define LL_TIM_OCREF_CLR_INT_COMP7 (TIM1_AF2_OCRSEL_2 | TIM1_AF2_OCRSEL_1) /*!< OCREF clear input is connected to COMP7_OUT */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_INDEX_DIR index direction selection
* @{
*/
#define LL_TIM_INDEX_UP_DOWN 0x00000000U /*!< Index resets the counter whatever the direction */
#define LL_TIM_INDEX_UP TIM_ECR_IDIR_0 /*!< Index resets the counter when up-counting only */
#define LL_TIM_INDEX_DOWN TIM_ECR_IDIR_1 /*!< Index resets the counter when down-counting only */
/**
* @}
*/
/** @defgroup TIM_LL_EC_INDEX_POSITION index positioning selection
* @{
*/
#define LL_TIM_INDEX_POSITION_DOWN_DOWN 0x00000000U /*!< Index resets the counter when AB = 00 */
#define LL_TIM_INDEX_POSITION_DOWN_UP TIM_ECR_IPOS_0 /*!< Index resets the counter when AB = 01 */
#define LL_TIM_INDEX_POSITION_UP_DOWN TIM_ECR_IPOS_1 /*!< Index resets the counter when AB = 10 */
#define LL_TIM_INDEX_POSITION_UP_UP (TIM_ECR_IPOS_1 | TIM_ECR_IPOS_0) /*!< Index resets the counter when AB = 11 */
#define LL_TIM_INDEX_POSITION_DOWN 0x00000000U /*!< Index resets the counter when clock is 0 */
#define LL_TIM_INDEX_POSITION_UP TIM_ECR_IPOS_0 /*!< Index resets the counter when clock is 1 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_FIRST_INDEX first index selection
* @{
*/
#define LL_TIM_INDEX_ALL 0x00000000U /*!< Index is always active */
#define LL_TIM_INDEX_FIRST_ONLY TIM_ECR_FIDX /*!< The first Index only resets the counter */
/**
* @}
*/
/** @defgroup TIM_LL_EC_PWPRSC Pulse on compare pulse width prescaler
* @{
*/
#define LL_TIM_PWPRSC_X1 0x00000000U /*!< Pulse on compare pulse width prescaler 1 */
#define LL_TIM_PWPRSC_X2 TIM_ECR_PWPRSC_0 /*!< Pulse on compare pulse width prescaler 2 */
#define LL_TIM_PWPRSC_X4 TIM_ECR_PWPRSC_1 /*!< Pulse on compare pulse width prescaler 4 */
#define LL_TIM_PWPRSC_X8 (TIM_ECR_PWPRSC_1 | TIM_ECR_PWPRSC_0) /*!< Pulse on compare pulse width prescaler 8 */
#define LL_TIM_PWPRSC_X16 TIM_ECR_PWPRSC_2 /*!< Pulse on compare pulse width prescaler 16 */
#define LL_TIM_PWPRSC_X32 (TIM_ECR_PWPRSC_2 | TIM_ECR_PWPRSC_0) /*!< Pulse on compare pulse width prescaler 32 */
#define LL_TIM_PWPRSC_X64 (TIM_ECR_PWPRSC_2 | TIM_ECR_PWPRSC_1) /*!< Pulse on compare pulse width prescaler 64 */
#define LL_TIM_PWPRSC_X128 (TIM_ECR_PWPRSC_2 | TIM_ECR_PWPRSC_1 | TIM_ECR_PWPRSC_0) /*!< Pulse on compare pulse width prescaler 128 */
/**
* @}
*/
/** @defgroup TIM_LL_EC_HSE_32_REQUEST Clock HSE/32 request
* @{
*/
#define LL_TIM_HSE_32_NOT_REQUEST 0x00000000U /*!< Clock HSE/32 not requested */
#define LL_TIM_HSE_32_REQUEST TIM_OR_HSE32EN /*!< Clock HSE/32 requested for TIM16/17 TI1SEL remap */
/**
* @}
*/
/** Legacy definitions for compatibility purpose
@cond 0
*/
#define LL_TIM_BKIN_SOURCE_DFBK LL_TIM_BKIN_SOURCE_DF1BK
/**
@endcond
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup TIM_LL_Exported_Macros TIM Exported Macros
* @{
*/
/** @defgroup TIM_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in TIM register.
* @param __INSTANCE__ TIM Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_TIM_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG((__INSTANCE__)->__REG__, (__VALUE__))
/**
* @brief Read a value in TIM register.
* @param __INSTANCE__ TIM Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_TIM_ReadReg(__INSTANCE__, __REG__) READ_REG((__INSTANCE__)->__REG__)
/**
* @}
*/
/**
* @brief HELPER macro retrieving the UIFCPY flag from the counter value.
* @note ex: @ref __LL_TIM_GETFLAG_UIFCPY (@ref LL_TIM_GetCounter ());
* @note Relevant only if UIF flag remapping has been enabled (UIF status bit is copied
* to TIMx_CNT register bit 31)
* @param __CNT__ Counter value
* @retval UIF status bit
*/
#define __LL_TIM_GETFLAG_UIFCPY(__CNT__) \
(READ_BIT((__CNT__), TIM_CNT_UIFCPY) >> TIM_CNT_UIFCPY_Pos)
/**
* @brief HELPER macro calculating DTG[0:7] in the TIMx_BDTR register to achieve the requested dead time duration.
* @note ex: @ref __LL_TIM_CALC_DEADTIME (80000000, @ref LL_TIM_GetClockDivision (), 120);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __CKD__ This parameter can be one of the following values:
* @arg @ref LL_TIM_CLOCKDIVISION_DIV1
* @arg @ref LL_TIM_CLOCKDIVISION_DIV2
* @arg @ref LL_TIM_CLOCKDIVISION_DIV4
* @param __DT__ deadtime duration (in ns)
* @retval DTG[0:7]
*/
#define __LL_TIM_CALC_DEADTIME(__TIMCLK__, __CKD__, __DT__) \
( (((uint64_t)((__DT__)*1000U)) < ((DT_DELAY_1+1U) * TIM_CALC_DTS((__TIMCLK__), (__CKD__)))) ? \
(uint8_t)(((uint64_t)((__DT__)*1000U) / TIM_CALC_DTS((__TIMCLK__), (__CKD__))) & DT_DELAY_1) : \
(((uint64_t)((__DT__)*1000U)) < ((64U + (DT_DELAY_2+1U)) * 2U * TIM_CALC_DTS((__TIMCLK__), (__CKD__)))) ? \
(uint8_t)(DT_RANGE_2 | ((uint8_t)((uint8_t)((((uint64_t)((__DT__)*1000U))/ TIM_CALC_DTS((__TIMCLK__), \
(__CKD__))) >> 1U) - (uint8_t) 64) & DT_DELAY_2)) :\
(((uint64_t)((__DT__)*1000U)) < ((32U + (DT_DELAY_3+1U)) * 8U * TIM_CALC_DTS((__TIMCLK__), (__CKD__)))) ? \
(uint8_t)(DT_RANGE_3 | ((uint8_t)((uint8_t)(((((uint64_t)(__DT__)*1000U))/ TIM_CALC_DTS((__TIMCLK__), \
(__CKD__))) >> 3U) - (uint8_t) 32) & DT_DELAY_3)) :\
(((uint64_t)((__DT__)*1000U)) < ((32U + (DT_DELAY_4+1U)) * 16U * TIM_CALC_DTS((__TIMCLK__), (__CKD__)))) ? \
(uint8_t)(DT_RANGE_4 | ((uint8_t)((uint8_t)(((((uint64_t)(__DT__)*1000U))/ TIM_CALC_DTS((__TIMCLK__), \
(__CKD__))) >> 4U) - (uint8_t) 32) & DT_DELAY_4)) :\
0U)
/**
* @brief HELPER macro calculating the prescaler value to achieve the required counter clock frequency.
* @note ex: @ref __LL_TIM_CALC_PSC (80000000, 1000000);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __CNTCLK__ counter clock frequency (in Hz)
* @retval Prescaler value (between Min_Data=0 and Max_Data=65535)
*/
#define __LL_TIM_CALC_PSC(__TIMCLK__, __CNTCLK__) \
(((__TIMCLK__) >= (__CNTCLK__)) ? (uint32_t)((((__TIMCLK__) + (__CNTCLK__)/2U)/(__CNTCLK__)) - 1U) : 0U)
/**
* @brief HELPER macro calculating the auto-reload value to achieve the required output signal frequency.
* @note ex: @ref __LL_TIM_CALC_ARR (1000000, @ref LL_TIM_GetPrescaler (), 10000);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __FREQ__ output signal frequency (in Hz)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65535)
*/
#define __LL_TIM_CALC_ARR(__TIMCLK__, __PSC__, __FREQ__) \
((((__TIMCLK__)/((__PSC__) + 1U)) >= (__FREQ__)) ? (((__TIMCLK__)/((__FREQ__) * ((__PSC__) + 1U))) - 1U) : 0U)
/**
* @brief HELPER macro calculating the auto-reload value, with dithering feature enabled, to achieve the required
* output signal frequency.
* @note ex: @ref __LL_TIM_CALC_ARR_DITHER (1000000, @ref LL_TIM_GetPrescaler (), 10000);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __FREQ__ output signal frequency (in Hz)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65535)
*/
#define __LL_TIM_CALC_ARR_DITHER(__TIMCLK__, __PSC__, __FREQ__) \
((((__TIMCLK__)/((__PSC__) + 1U)) >= (__FREQ__)) ? \
(uint32_t)((((uint64_t)(__TIMCLK__) * 16U/((__FREQ__) * ((__PSC__) + 1U))) - 16U)) : 0U)
/**
* @brief HELPER macro calculating the compare value required to achieve the required timer output compare
* active/inactive delay.
* @note ex: @ref __LL_TIM_CALC_DELAY (1000000, @ref LL_TIM_GetPrescaler (), 10);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @retval Compare value (between Min_Data=0 and Max_Data=65535)
*/
#define __LL_TIM_CALC_DELAY(__TIMCLK__, __PSC__, __DELAY__) \
((uint32_t)(((uint64_t)(__TIMCLK__) * (uint64_t)(__DELAY__)) \
/ ((uint64_t)1000000U * (uint64_t)((__PSC__) + 1U))))
/**
* @brief HELPER macro calculating the compare value, with dithering feature enabled, to achieve the required timer
* output compare active/inactive delay.
* @note ex: @ref __LL_TIM_CALC_DELAY_DITHER (1000000, @ref LL_TIM_GetPrescaler (), 10);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @retval Compare value (between Min_Data=0 and Max_Data=65535)
*/
#define __LL_TIM_CALC_DELAY_DITHER(__TIMCLK__, __PSC__, __DELAY__) \
((uint32_t)(((uint64_t)(__TIMCLK__) * (uint64_t)(__DELAY__) * 16U) \
/ ((uint64_t)1000000U * (uint64_t)((__PSC__) + 1U))))
/**
* @brief HELPER macro calculating the auto-reload value to achieve the required pulse duration
* (when the timer operates in one pulse mode).
* @note ex: @ref __LL_TIM_CALC_PULSE (1000000, @ref LL_TIM_GetPrescaler (), 10, 20);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @param __PULSE__ pulse duration (in us)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65535)
*/
#define __LL_TIM_CALC_PULSE(__TIMCLK__, __PSC__, __DELAY__, __PULSE__) \
((uint32_t)(__LL_TIM_CALC_DELAY((__TIMCLK__), (__PSC__), (__PULSE__)) \
+ __LL_TIM_CALC_DELAY((__TIMCLK__), (__PSC__), (__DELAY__))))
/**
* @brief HELPER macro calculating the auto-reload value, with dithering feature enabled, to achieve the required
* pulse duration (when the timer operates in one pulse mode).
* @note ex: @ref __LL_TIM_CALC_PULSE_DITHER (1000000, @ref LL_TIM_GetPrescaler (), 10, 20);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @param __PULSE__ pulse duration (in us)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65535)
*/
#define __LL_TIM_CALC_PULSE_DITHER(__TIMCLK__, __PSC__, __DELAY__, __PULSE__) \
((uint32_t)(__LL_TIM_CALC_DELAY_DITHER((__TIMCLK__), (__PSC__), (__PULSE__)) \
+ __LL_TIM_CALC_DELAY_DITHER((__TIMCLK__), (__PSC__), (__DELAY__))))
/**
* @brief HELPER macro retrieving the ratio of the input capture prescaler
* @note ex: @ref __LL_TIM_GET_ICPSC_RATIO (@ref LL_TIM_IC_GetPrescaler ());
* @param __ICPSC__ This parameter can be one of the following values:
* @arg @ref LL_TIM_ICPSC_DIV1
* @arg @ref LL_TIM_ICPSC_DIV2
* @arg @ref LL_TIM_ICPSC_DIV4
* @arg @ref LL_TIM_ICPSC_DIV8
* @retval Input capture prescaler ratio (1, 2, 4 or 8)
*/
#define __LL_TIM_GET_ICPSC_RATIO(__ICPSC__) \
((uint32_t)(0x01U << (((__ICPSC__) >> 16U) >> TIM_CCMR1_IC1PSC_Pos)))
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup TIM_LL_Exported_Functions TIM Exported Functions
* @{
*/
/** @defgroup TIM_LL_EF_Time_Base Time Base configuration
* @{
*/
/**
* @brief Enable timer counter.
* @rmtoll CR1 CEN LL_TIM_EnableCounter
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableCounter(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->CR1, TIM_CR1_CEN);
}
/**
* @brief Disable timer counter.
* @rmtoll CR1 CEN LL_TIM_DisableCounter
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableCounter(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->CR1, TIM_CR1_CEN);
}
/**
* @brief Indicates whether the timer counter is enabled.
* @rmtoll CR1 CEN LL_TIM_IsEnabledCounter
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledCounter(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->CR1, TIM_CR1_CEN) == (TIM_CR1_CEN)) ? 1UL : 0UL);
}
/**
* @brief Enable update event generation.
* @rmtoll CR1 UDIS LL_TIM_EnableUpdateEvent
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableUpdateEvent(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->CR1, TIM_CR1_UDIS);
}
/**
* @brief Disable update event generation.
* @rmtoll CR1 UDIS LL_TIM_DisableUpdateEvent
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableUpdateEvent(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->CR1, TIM_CR1_UDIS);
}
/**
* @brief Indicates whether update event generation is enabled.
* @rmtoll CR1 UDIS LL_TIM_IsEnabledUpdateEvent
* @param TIMx Timer instance
* @retval Inverted state of bit (0 or 1).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledUpdateEvent(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->CR1, TIM_CR1_UDIS) == (uint32_t)RESET) ? 1UL : 0UL);
}
/**
* @brief Set update event source
* @note Update event source set to LL_TIM_UPDATESOURCE_REGULAR: any of the following events
* generate an update interrupt or DMA request if enabled:
* - Counter overflow/underflow
* - Setting the UG bit
* - Update generation through the slave mode controller
* @note Update event source set to LL_TIM_UPDATESOURCE_COUNTER: only counter
* overflow/underflow generates an update interrupt or DMA request if enabled.
* @rmtoll CR1 URS LL_TIM_SetUpdateSource
* @param TIMx Timer instance
* @param UpdateSource This parameter can be one of the following values:
* @arg @ref LL_TIM_UPDATESOURCE_REGULAR
* @arg @ref LL_TIM_UPDATESOURCE_COUNTER
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetUpdateSource(TIM_TypeDef *TIMx, uint32_t UpdateSource)
{
MODIFY_REG(TIMx->CR1, TIM_CR1_URS, UpdateSource);
}
/**
* @brief Get actual event update source
* @rmtoll CR1 URS LL_TIM_GetUpdateSource
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_UPDATESOURCE_REGULAR
* @arg @ref LL_TIM_UPDATESOURCE_COUNTER
*/
__STATIC_INLINE uint32_t LL_TIM_GetUpdateSource(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->CR1, TIM_CR1_URS));
}
/**
* @brief Set one pulse mode (one shot v.s. repetitive).
* @rmtoll CR1 OPM LL_TIM_SetOnePulseMode
* @param TIMx Timer instance
* @param OnePulseMode This parameter can be one of the following values:
* @arg @ref LL_TIM_ONEPULSEMODE_SINGLE
* @arg @ref LL_TIM_ONEPULSEMODE_REPETITIVE
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetOnePulseMode(TIM_TypeDef *TIMx, uint32_t OnePulseMode)
{
MODIFY_REG(TIMx->CR1, TIM_CR1_OPM, OnePulseMode);
}
/**
* @brief Get actual one pulse mode.
* @rmtoll CR1 OPM LL_TIM_GetOnePulseMode
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_ONEPULSEMODE_SINGLE
* @arg @ref LL_TIM_ONEPULSEMODE_REPETITIVE
*/
__STATIC_INLINE uint32_t LL_TIM_GetOnePulseMode(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->CR1, TIM_CR1_OPM));
}
/**
* @brief Set the timer counter counting mode.
* @note Macro IS_TIM_COUNTER_MODE_SELECT_INSTANCE(TIMx) can be used to
* check whether or not the counter mode selection feature is supported
* by a timer instance.
* @note Switching from Center Aligned counter mode to Edge counter mode (or reverse)
* requires a timer reset to avoid unexpected direction
* due to DIR bit readonly in center aligned mode.
* @rmtoll CR1 DIR LL_TIM_SetCounterMode\n
* CR1 CMS LL_TIM_SetCounterMode
* @param TIMx Timer instance
* @param CounterMode This parameter can be one of the following values:
* @arg @ref LL_TIM_COUNTERMODE_UP
* @arg @ref LL_TIM_COUNTERMODE_DOWN
* @arg @ref LL_TIM_COUNTERMODE_CENTER_UP
* @arg @ref LL_TIM_COUNTERMODE_CENTER_DOWN
* @arg @ref LL_TIM_COUNTERMODE_CENTER_UP_DOWN
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetCounterMode(TIM_TypeDef *TIMx, uint32_t CounterMode)
{
MODIFY_REG(TIMx->CR1, (TIM_CR1_DIR | TIM_CR1_CMS), CounterMode);
}
/**
* @brief Get actual counter mode.
* @note Macro IS_TIM_COUNTER_MODE_SELECT_INSTANCE(TIMx) can be used to
* check whether or not the counter mode selection feature is supported
* by a timer instance.
* @rmtoll CR1 DIR LL_TIM_GetCounterMode\n
* CR1 CMS LL_TIM_GetCounterMode
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_COUNTERMODE_UP
* @arg @ref LL_TIM_COUNTERMODE_DOWN
* @arg @ref LL_TIM_COUNTERMODE_CENTER_UP
* @arg @ref LL_TIM_COUNTERMODE_CENTER_DOWN
* @arg @ref LL_TIM_COUNTERMODE_CENTER_UP_DOWN
*/
__STATIC_INLINE uint32_t LL_TIM_GetCounterMode(const TIM_TypeDef *TIMx)
{
uint32_t counter_mode;
counter_mode = (uint32_t)(READ_BIT(TIMx->CR1, TIM_CR1_CMS));
if (counter_mode == 0U)
{
counter_mode = (uint32_t)(READ_BIT(TIMx->CR1, TIM_CR1_DIR));
}
return counter_mode;
}
/**
* @brief Enable auto-reload (ARR) preload.
* @rmtoll CR1 ARPE LL_TIM_EnableARRPreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableARRPreload(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->CR1, TIM_CR1_ARPE);
}
/**
* @brief Disable auto-reload (ARR) preload.
* @rmtoll CR1 ARPE LL_TIM_DisableARRPreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableARRPreload(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->CR1, TIM_CR1_ARPE);
}
/**
* @brief Indicates whether auto-reload (ARR) preload is enabled.
* @rmtoll CR1 ARPE LL_TIM_IsEnabledARRPreload
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledARRPreload(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->CR1, TIM_CR1_ARPE) == (TIM_CR1_ARPE)) ? 1UL : 0UL);
}
/**
* @brief Set the division ratio between the timer clock and the sampling clock used by the dead-time generators
* (when supported) and the digital filters.
* @note Macro IS_TIM_CLOCK_DIVISION_INSTANCE(TIMx) can be used to check
* whether or not the clock division feature is supported by the timer
* instance.
* @rmtoll CR1 CKD LL_TIM_SetClockDivision
* @param TIMx Timer instance
* @param ClockDivision This parameter can be one of the following values:
* @arg @ref LL_TIM_CLOCKDIVISION_DIV1
* @arg @ref LL_TIM_CLOCKDIVISION_DIV2
* @arg @ref LL_TIM_CLOCKDIVISION_DIV4
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetClockDivision(TIM_TypeDef *TIMx, uint32_t ClockDivision)
{
MODIFY_REG(TIMx->CR1, TIM_CR1_CKD, ClockDivision);
}
/**
* @brief Get the actual division ratio between the timer clock and the sampling clock used by the dead-time
* generators (when supported) and the digital filters.
* @note Macro IS_TIM_CLOCK_DIVISION_INSTANCE(TIMx) can be used to check
* whether or not the clock division feature is supported by the timer
* instance.
* @rmtoll CR1 CKD LL_TIM_GetClockDivision
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_CLOCKDIVISION_DIV1
* @arg @ref LL_TIM_CLOCKDIVISION_DIV2
* @arg @ref LL_TIM_CLOCKDIVISION_DIV4
*/
__STATIC_INLINE uint32_t LL_TIM_GetClockDivision(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->CR1, TIM_CR1_CKD));
}
/**
* @brief Set the counter value.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note If dithering is activated, pay attention to the Counter value interpretation
* @rmtoll CNT CNT LL_TIM_SetCounter
* @param TIMx Timer instance
* @param Counter Counter value (between Min_Data=0 and Max_Data=0xFFFF or 0xFFFFFFFF)
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetCounter(TIM_TypeDef *TIMx, uint32_t Counter)
{
WRITE_REG(TIMx->CNT, Counter);
}
/**
* @brief Get the counter value.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note If dithering is activated, pay attention to the Counter value interpretation
* @rmtoll CNT CNT LL_TIM_GetCounter
* @param TIMx Timer instance
* @retval Counter value (between Min_Data=0 and Max_Data=0xFFFF or 0xFFFFFFFF)
*/
__STATIC_INLINE uint32_t LL_TIM_GetCounter(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CNT));
}
/**
* @brief Get the current direction of the counter
* @rmtoll CR1 DIR LL_TIM_GetDirection
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_COUNTERDIRECTION_UP
* @arg @ref LL_TIM_COUNTERDIRECTION_DOWN
*/
__STATIC_INLINE uint32_t LL_TIM_GetDirection(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->CR1, TIM_CR1_DIR));
}
/**
* @brief Set the prescaler value.
* @note The counter clock frequency CK_CNT is equal to fCK_PSC / (PSC[15:0] + 1).
* @note The prescaler can be changed on the fly as this control register is buffered. The new
* prescaler ratio is taken into account at the next update event.
* @note Helper macro @ref __LL_TIM_CALC_PSC can be used to calculate the Prescaler parameter
* @rmtoll PSC PSC LL_TIM_SetPrescaler
* @param TIMx Timer instance
* @param Prescaler between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetPrescaler(TIM_TypeDef *TIMx, uint32_t Prescaler)
{
WRITE_REG(TIMx->PSC, Prescaler);
}
/**
* @brief Get the prescaler value.
* @rmtoll PSC PSC LL_TIM_GetPrescaler
* @param TIMx Timer instance
* @retval Prescaler value between Min_Data=0 and Max_Data=65535
*/
__STATIC_INLINE uint32_t LL_TIM_GetPrescaler(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->PSC));
}
/**
* @brief Set the auto-reload value.
* @note The counter is blocked while the auto-reload value is null.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Helper macro @ref __LL_TIM_CALC_ARR can be used to calculate the AutoReload parameter
* In case dithering is activated,macro __LL_TIM_CALC_ARR_DITHER can be used instead, to calculate the AutoReload
* parameter.
* @rmtoll ARR ARR LL_TIM_SetAutoReload
* @param TIMx Timer instance
* @param AutoReload between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetAutoReload(TIM_TypeDef *TIMx, uint32_t AutoReload)
{
WRITE_REG(TIMx->ARR, AutoReload);
}
/**
* @brief Get the auto-reload value.
* @rmtoll ARR ARR LL_TIM_GetAutoReload
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note If dithering is activated, pay attention to the returned value interpretation
* @param TIMx Timer instance
* @retval Auto-reload value
*/
__STATIC_INLINE uint32_t LL_TIM_GetAutoReload(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->ARR));
}
/**
* @brief Set the repetition counter value.
* @note For advanced timer instances RepetitionCounter can be up to 65535.
* @note Macro IS_TIM_REPETITION_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a repetition counter.
* @rmtoll RCR REP LL_TIM_SetRepetitionCounter
* @param TIMx Timer instance
* @param RepetitionCounter between Min_Data=0 and Max_Data=255 or 65535 for advanced timer.
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetRepetitionCounter(TIM_TypeDef *TIMx, uint32_t RepetitionCounter)
{
WRITE_REG(TIMx->RCR, RepetitionCounter);
}
/**
* @brief Get the repetition counter value.
* @note Macro IS_TIM_REPETITION_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a repetition counter.
* @rmtoll RCR REP LL_TIM_GetRepetitionCounter
* @param TIMx Timer instance
* @retval Repetition counter value
*/
__STATIC_INLINE uint32_t LL_TIM_GetRepetitionCounter(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->RCR));
}
/**
* @brief Force a continuous copy of the update interrupt flag (UIF) into the timer counter register (bit 31).
* @note This allows both the counter value and a potential roll-over condition signalled by the UIFCPY flag to be read
* in an atomic way.
* @rmtoll CR1 UIFREMAP LL_TIM_EnableUIFRemap
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableUIFRemap(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->CR1, TIM_CR1_UIFREMAP);
}
/**
* @brief Disable update interrupt flag (UIF) remapping.
* @rmtoll CR1 UIFREMAP LL_TIM_DisableUIFRemap
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableUIFRemap(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->CR1, TIM_CR1_UIFREMAP);
}
/**
* @brief Indicate whether update interrupt flag (UIF) copy is set.
* @param Counter Counter value
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveUIFCPY(const uint32_t Counter)
{
return (((Counter & TIM_CNT_UIFCPY) == (TIM_CNT_UIFCPY)) ? 1UL : 0UL);
}
/**
* @brief Enable dithering.
* @note Macro IS_TIM_DITHERING_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides dithering.
* @rmtoll CR1 DITHEN LL_TIM_EnableDithering
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDithering(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->CR1, TIM_CR1_DITHEN);
}
/**
* @brief Disable dithering.
* @note Macro IS_TIM_DITHERING_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides dithering.
* @rmtoll CR1 DITHEN LL_TIM_DisableDithering
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDithering(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->CR1, TIM_CR1_DITHEN);
}
/**
* @brief Indicates whether dithering is activated.
* @note Macro IS_TIM_DITHERING_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides dithering.
* @rmtoll CR1 DITHEN LL_TIM_IsEnabledDithering
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDithering(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->CR1, TIM_CR1_DITHEN) == (TIM_CR1_DITHEN)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Capture_Compare Capture Compare configuration
* @{
*/
/**
* @brief Enable the capture/compare control bits (CCxE, CCxNE and OCxM) preload.
* @note CCxE, CCxNE and OCxM bits are preloaded, after having been written,
* they are updated only when a commutation event (COM) occurs.
* @note Only on channels that have a complementary output.
* @note Macro IS_TIM_COMMUTATION_EVENT_INSTANCE(TIMx) can be used to check
* whether or not a timer instance is able to generate a commutation event.
* @rmtoll CR2 CCPC LL_TIM_CC_EnablePreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_CC_EnablePreload(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->CR2, TIM_CR2_CCPC);
}
/**
* @brief Disable the capture/compare control bits (CCxE, CCxNE and OCxM) preload.
* @note Macro IS_TIM_COMMUTATION_EVENT_INSTANCE(TIMx) can be used to check
* whether or not a timer instance is able to generate a commutation event.
* @rmtoll CR2 CCPC LL_TIM_CC_DisablePreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_CC_DisablePreload(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->CR2, TIM_CR2_CCPC);
}
/**
* @brief Indicates whether the capture/compare control bits (CCxE, CCxNE and OCxM) preload is enabled.
* @rmtoll CR2 CCPC LL_TIM_CC_IsEnabledPreload
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_CC_IsEnabledPreload(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->CR2, TIM_CR2_CCPC) == (TIM_CR2_CCPC)) ? 1UL : 0UL);
}
/**
* @brief Set the updated source of the capture/compare control bits (CCxE, CCxNE and OCxM).
* @note Macro IS_TIM_COMMUTATION_EVENT_INSTANCE(TIMx) can be used to check
* whether or not a timer instance is able to generate a commutation event.
* @rmtoll CR2 CCUS LL_TIM_CC_SetUpdate
* @param TIMx Timer instance
* @param CCUpdateSource This parameter can be one of the following values:
* @arg @ref LL_TIM_CCUPDATESOURCE_COMG_ONLY
* @arg @ref LL_TIM_CCUPDATESOURCE_COMG_AND_TRGI
* @retval None
*/
__STATIC_INLINE void LL_TIM_CC_SetUpdate(TIM_TypeDef *TIMx, uint32_t CCUpdateSource)
{
MODIFY_REG(TIMx->CR2, TIM_CR2_CCUS, CCUpdateSource);
}
/**
* @brief Set the trigger of the capture/compare DMA request.
* @rmtoll CR2 CCDS LL_TIM_CC_SetDMAReqTrigger
* @param TIMx Timer instance
* @param DMAReqTrigger This parameter can be one of the following values:
* @arg @ref LL_TIM_CCDMAREQUEST_CC
* @arg @ref LL_TIM_CCDMAREQUEST_UPDATE
* @retval None
*/
__STATIC_INLINE void LL_TIM_CC_SetDMAReqTrigger(TIM_TypeDef *TIMx, uint32_t DMAReqTrigger)
{
MODIFY_REG(TIMx->CR2, TIM_CR2_CCDS, DMAReqTrigger);
}
/**
* @brief Get actual trigger of the capture/compare DMA request.
* @rmtoll CR2 CCDS LL_TIM_CC_GetDMAReqTrigger
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_CCDMAREQUEST_CC
* @arg @ref LL_TIM_CCDMAREQUEST_UPDATE
*/
__STATIC_INLINE uint32_t LL_TIM_CC_GetDMAReqTrigger(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->CR2, TIM_CR2_CCDS));
}
/**
* @brief Set the lock level to freeze the
* configuration of several capture/compare parameters.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* the lock mechanism is supported by a timer instance.
* @rmtoll BDTR LOCK LL_TIM_CC_SetLockLevel
* @param TIMx Timer instance
* @param LockLevel This parameter can be one of the following values:
* @arg @ref LL_TIM_LOCKLEVEL_OFF
* @arg @ref LL_TIM_LOCKLEVEL_1
* @arg @ref LL_TIM_LOCKLEVEL_2
* @arg @ref LL_TIM_LOCKLEVEL_3
* @retval None
*/
__STATIC_INLINE void LL_TIM_CC_SetLockLevel(TIM_TypeDef *TIMx, uint32_t LockLevel)
{
MODIFY_REG(TIMx->BDTR, TIM_BDTR_LOCK, LockLevel);
}
/**
* @brief Enable capture/compare channels.
* @rmtoll CCER CC1E LL_TIM_CC_EnableChannel\n
* CCER CC1NE LL_TIM_CC_EnableChannel\n
* CCER CC2E LL_TIM_CC_EnableChannel\n
* CCER CC2NE LL_TIM_CC_EnableChannel\n
* CCER CC3E LL_TIM_CC_EnableChannel\n
* CCER CC3NE LL_TIM_CC_EnableChannel\n
* CCER CC4E LL_TIM_CC_EnableChannel\n
* CCER CC4NE LL_TIM_CC_EnableChannel\n
* CCER CC5E LL_TIM_CC_EnableChannel\n
* CCER CC6E LL_TIM_CC_EnableChannel
* @param TIMx Timer instance
* @param Channels This parameter can be a combination of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_CC_EnableChannel(TIM_TypeDef *TIMx, uint32_t Channels)
{
SET_BIT(TIMx->CCER, Channels);
}
/**
* @brief Disable capture/compare channels.
* @rmtoll CCER CC1E LL_TIM_CC_DisableChannel\n
* CCER CC1NE LL_TIM_CC_DisableChannel\n
* CCER CC2E LL_TIM_CC_DisableChannel\n
* CCER CC2NE LL_TIM_CC_DisableChannel\n
* CCER CC3E LL_TIM_CC_DisableChannel\n
* CCER CC3NE LL_TIM_CC_DisableChannel\n
* CCER CC4E LL_TIM_CC_DisableChannel\n
* CCER CC4NE LL_TIM_CC_DisableChannel\n
* CCER CC5E LL_TIM_CC_DisableChannel\n
* CCER CC6E LL_TIM_CC_DisableChannel
* @param TIMx Timer instance
* @param Channels This parameter can be a combination of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_CC_DisableChannel(TIM_TypeDef *TIMx, uint32_t Channels)
{
CLEAR_BIT(TIMx->CCER, Channels);
}
/**
* @brief Indicate whether channel(s) is(are) enabled.
* @rmtoll CCER CC1E LL_TIM_CC_IsEnabledChannel\n
* CCER CC1NE LL_TIM_CC_IsEnabledChannel\n
* CCER CC2E LL_TIM_CC_IsEnabledChannel\n
* CCER CC2NE LL_TIM_CC_IsEnabledChannel\n
* CCER CC3E LL_TIM_CC_IsEnabledChannel\n
* CCER CC3NE LL_TIM_CC_IsEnabledChannel\n
* CCER CC4E LL_TIM_CC_IsEnabledChannel\n
* CCER CC4NE LL_TIM_CC_IsEnabledChannel\n
* CCER CC5E LL_TIM_CC_IsEnabledChannel\n
* CCER CC6E LL_TIM_CC_IsEnabledChannel
* @param TIMx Timer instance
* @param Channels This parameter can be a combination of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_CC_IsEnabledChannel(const TIM_TypeDef *TIMx, uint32_t Channels)
{
return ((READ_BIT(TIMx->CCER, Channels) == (Channels)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Output_Channel Output channel configuration
* @{
*/
/**
* @brief Configure an output channel.
* @rmtoll CCMR1 CC1S LL_TIM_OC_ConfigOutput\n
* CCMR1 CC2S LL_TIM_OC_ConfigOutput\n
* CCMR2 CC3S LL_TIM_OC_ConfigOutput\n
* CCMR2 CC4S LL_TIM_OC_ConfigOutput\n
* CCMR3 CC5S LL_TIM_OC_ConfigOutput\n
* CCMR3 CC6S LL_TIM_OC_ConfigOutput\n
* CCER CC1P LL_TIM_OC_ConfigOutput\n
* CCER CC2P LL_TIM_OC_ConfigOutput\n
* CCER CC3P LL_TIM_OC_ConfigOutput\n
* CCER CC4P LL_TIM_OC_ConfigOutput\n
* CCER CC5P LL_TIM_OC_ConfigOutput\n
* CCER CC6P LL_TIM_OC_ConfigOutput\n
* CR2 OIS1 LL_TIM_OC_ConfigOutput\n
* CR2 OIS2 LL_TIM_OC_ConfigOutput\n
* CR2 OIS3 LL_TIM_OC_ConfigOutput\n
* CR2 OIS4 LL_TIM_OC_ConfigOutput\n
* CR2 OIS5 LL_TIM_OC_ConfigOutput\n
* CR2 OIS6 LL_TIM_OC_ConfigOutput
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @param Configuration This parameter must be a combination of all the following values:
* @arg @ref LL_TIM_OCPOLARITY_HIGH or @ref LL_TIM_OCPOLARITY_LOW
* @arg @ref LL_TIM_OCIDLESTATE_LOW or @ref LL_TIM_OCIDLESTATE_HIGH
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_ConfigOutput(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t Configuration)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
CLEAR_BIT(*pReg, (TIM_CCMR1_CC1S << SHIFT_TAB_OCxx[iChannel]));
MODIFY_REG(TIMx->CCER, (TIM_CCER_CC1P << SHIFT_TAB_CCxP[iChannel]),
(Configuration & TIM_CCER_CC1P) << SHIFT_TAB_CCxP[iChannel]);
MODIFY_REG(TIMx->CR2, (TIM_CR2_OIS1 << SHIFT_TAB_OISx[iChannel]),
(Configuration & TIM_CR2_OIS1) << SHIFT_TAB_OISx[iChannel]);
}
/**
* @brief Define the behavior of the output reference signal OCxREF from which
* OCx and OCxN (when relevant) are derived.
* @rmtoll CCMR1 OC1M LL_TIM_OC_SetMode\n
* CCMR1 OC2M LL_TIM_OC_SetMode\n
* CCMR2 OC3M LL_TIM_OC_SetMode\n
* CCMR2 OC4M LL_TIM_OC_SetMode\n
* CCMR3 OC5M LL_TIM_OC_SetMode\n
* CCMR3 OC6M LL_TIM_OC_SetMode
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @param Mode This parameter can be one of the following values:
* @arg @ref LL_TIM_OCMODE_FROZEN
* @arg @ref LL_TIM_OCMODE_ACTIVE
* @arg @ref LL_TIM_OCMODE_INACTIVE
* @arg @ref LL_TIM_OCMODE_TOGGLE
* @arg @ref LL_TIM_OCMODE_FORCED_INACTIVE
* @arg @ref LL_TIM_OCMODE_FORCED_ACTIVE
* @arg @ref LL_TIM_OCMODE_PWM1
* @arg @ref LL_TIM_OCMODE_PWM2
* @arg @ref LL_TIM_OCMODE_RETRIG_OPM1
* @arg @ref LL_TIM_OCMODE_RETRIG_OPM2
* @arg @ref LL_TIM_OCMODE_COMBINED_PWM1
* @arg @ref LL_TIM_OCMODE_COMBINED_PWM2
* @arg @ref LL_TIM_OCMODE_ASYMMETRIC_PWM1
* @arg @ref LL_TIM_OCMODE_ASYMMETRIC_PWM2
* @arg @ref LL_TIM_OCMODE_PULSE_ON_COMPARE (for channel 3 or channel 4 only)
* @arg @ref LL_TIM_OCMODE_DIRECTION_OUTPUT (for channel 3 or channel 4 only)
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetMode(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t Mode)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
MODIFY_REG(*pReg, ((TIM_CCMR1_OC1M | TIM_CCMR1_CC1S) << SHIFT_TAB_OCxx[iChannel]), Mode << SHIFT_TAB_OCxx[iChannel]);
}
/**
* @brief Get the output compare mode of an output channel.
* @rmtoll CCMR1 OC1M LL_TIM_OC_GetMode\n
* CCMR1 OC2M LL_TIM_OC_GetMode\n
* CCMR2 OC3M LL_TIM_OC_GetMode\n
* CCMR2 OC4M LL_TIM_OC_GetMode\n
* CCMR3 OC5M LL_TIM_OC_GetMode\n
* CCMR3 OC6M LL_TIM_OC_GetMode
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_OCMODE_FROZEN
* @arg @ref LL_TIM_OCMODE_ACTIVE
* @arg @ref LL_TIM_OCMODE_INACTIVE
* @arg @ref LL_TIM_OCMODE_TOGGLE
* @arg @ref LL_TIM_OCMODE_FORCED_INACTIVE
* @arg @ref LL_TIM_OCMODE_FORCED_ACTIVE
* @arg @ref LL_TIM_OCMODE_PWM1
* @arg @ref LL_TIM_OCMODE_PWM2
* @arg @ref LL_TIM_OCMODE_RETRIG_OPM1
* @arg @ref LL_TIM_OCMODE_RETRIG_OPM2
* @arg @ref LL_TIM_OCMODE_COMBINED_PWM1
* @arg @ref LL_TIM_OCMODE_COMBINED_PWM2
* @arg @ref LL_TIM_OCMODE_ASYMMETRIC_PWM1
* @arg @ref LL_TIM_OCMODE_ASYMMETRIC_PWM2
* @arg @ref LL_TIM_OCMODE_PULSE_ON_COMPARE (for channel 3 or channel 4 only)
* @arg @ref LL_TIM_OCMODE_DIRECTION_OUTPUT (for channel 3 or channel 4 only)
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetMode(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
const __IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
return (READ_BIT(*pReg, ((TIM_CCMR1_OC1M | TIM_CCMR1_CC1S) << SHIFT_TAB_OCxx[iChannel])) >> SHIFT_TAB_OCxx[iChannel]);
}
/**
* @brief Set the polarity of an output channel.
* @rmtoll CCER CC1P LL_TIM_OC_SetPolarity\n
* CCER CC1NP LL_TIM_OC_SetPolarity\n
* CCER CC2P LL_TIM_OC_SetPolarity\n
* CCER CC2NP LL_TIM_OC_SetPolarity\n
* CCER CC3P LL_TIM_OC_SetPolarity\n
* CCER CC3NP LL_TIM_OC_SetPolarity\n
* CCER CC4P LL_TIM_OC_SetPolarity\n
* CCER CC4NP LL_TIM_OC_SetPolarity\n
* CCER CC5P LL_TIM_OC_SetPolarity\n
* CCER CC6P LL_TIM_OC_SetPolarity
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_TIM_OCPOLARITY_HIGH
* @arg @ref LL_TIM_OCPOLARITY_LOW
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetPolarity(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t Polarity)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
MODIFY_REG(TIMx->CCER, (TIM_CCER_CC1P << SHIFT_TAB_CCxP[iChannel]), Polarity << SHIFT_TAB_CCxP[iChannel]);
}
/**
* @brief Get the polarity of an output channel.
* @rmtoll CCER CC1P LL_TIM_OC_GetPolarity\n
* CCER CC1NP LL_TIM_OC_GetPolarity\n
* CCER CC2P LL_TIM_OC_GetPolarity\n
* CCER CC2NP LL_TIM_OC_GetPolarity\n
* CCER CC3P LL_TIM_OC_GetPolarity\n
* CCER CC3NP LL_TIM_OC_GetPolarity\n
* CCER CC4P LL_TIM_OC_GetPolarity\n
* CCER CC4NP LL_TIM_OC_GetPolarity\n
* CCER CC5P LL_TIM_OC_GetPolarity\n
* CCER CC6P LL_TIM_OC_GetPolarity
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_OCPOLARITY_HIGH
* @arg @ref LL_TIM_OCPOLARITY_LOW
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetPolarity(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
return (READ_BIT(TIMx->CCER, (TIM_CCER_CC1P << SHIFT_TAB_CCxP[iChannel])) >> SHIFT_TAB_CCxP[iChannel]);
}
/**
* @brief Set the IDLE state of an output channel
* @note This function is significant only for the timer instances
* supporting the break feature. Macro IS_TIM_BREAK_INSTANCE(TIMx)
* can be used to check whether or not a timer instance provides
* a break input.
* @rmtoll CR2 OIS1 LL_TIM_OC_SetIdleState\n
* CR2 OIS2N LL_TIM_OC_SetIdleState\n
* CR2 OIS2 LL_TIM_OC_SetIdleState\n
* CR2 OIS2N LL_TIM_OC_SetIdleState\n
* CR2 OIS3 LL_TIM_OC_SetIdleState\n
* CR2 OIS3N LL_TIM_OC_SetIdleState\n
* CR2 OIS4 LL_TIM_OC_SetIdleState\n
* CR2 OIS4N LL_TIM_OC_SetIdleState\n
* CR2 OIS5 LL_TIM_OC_SetIdleState\n
* CR2 OIS6 LL_TIM_OC_SetIdleState
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @param IdleState This parameter can be one of the following values:
* @arg @ref LL_TIM_OCIDLESTATE_LOW
* @arg @ref LL_TIM_OCIDLESTATE_HIGH
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetIdleState(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t IdleState)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
MODIFY_REG(TIMx->CR2, (TIM_CR2_OIS1 << SHIFT_TAB_OISx[iChannel]), IdleState << SHIFT_TAB_OISx[iChannel]);
}
/**
* @brief Get the IDLE state of an output channel
* @rmtoll CR2 OIS1 LL_TIM_OC_GetIdleState\n
* CR2 OIS2N LL_TIM_OC_GetIdleState\n
* CR2 OIS2 LL_TIM_OC_GetIdleState\n
* CR2 OIS2N LL_TIM_OC_GetIdleState\n
* CR2 OIS3 LL_TIM_OC_GetIdleState\n
* CR2 OIS3N LL_TIM_OC_GetIdleState\n
* CR2 OIS4 LL_TIM_OC_GetIdleState\n
* CR2 OIS4N LL_TIM_OC_GetIdleState\n
* CR2 OIS5 LL_TIM_OC_GetIdleState\n
* CR2 OIS6 LL_TIM_OC_GetIdleState
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH1N
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH2N
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH3N
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH4N
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_OCIDLESTATE_LOW
* @arg @ref LL_TIM_OCIDLESTATE_HIGH
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetIdleState(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
return (READ_BIT(TIMx->CR2, (TIM_CR2_OIS1 << SHIFT_TAB_OISx[iChannel])) >> SHIFT_TAB_OISx[iChannel]);
}
/**
* @brief Enable fast mode for the output channel.
* @note Acts only if the channel is configured in PWM1 or PWM2 mode.
* @rmtoll CCMR1 OC1FE LL_TIM_OC_EnableFast\n
* CCMR1 OC2FE LL_TIM_OC_EnableFast\n
* CCMR2 OC3FE LL_TIM_OC_EnableFast\n
* CCMR2 OC4FE LL_TIM_OC_EnableFast\n
* CCMR3 OC5FE LL_TIM_OC_EnableFast\n
* CCMR3 OC6FE LL_TIM_OC_EnableFast
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_EnableFast(TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
SET_BIT(*pReg, (TIM_CCMR1_OC1FE << SHIFT_TAB_OCxx[iChannel]));
}
/**
* @brief Disable fast mode for the output channel.
* @rmtoll CCMR1 OC1FE LL_TIM_OC_DisableFast\n
* CCMR1 OC2FE LL_TIM_OC_DisableFast\n
* CCMR2 OC3FE LL_TIM_OC_DisableFast\n
* CCMR2 OC4FE LL_TIM_OC_DisableFast\n
* CCMR3 OC5FE LL_TIM_OC_DisableFast\n
* CCMR3 OC6FE LL_TIM_OC_DisableFast
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_DisableFast(TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
CLEAR_BIT(*pReg, (TIM_CCMR1_OC1FE << SHIFT_TAB_OCxx[iChannel]));
}
/**
* @brief Indicates whether fast mode is enabled for the output channel.
* @rmtoll CCMR1 OC1FE LL_TIM_OC_IsEnabledFast\n
* CCMR1 OC2FE LL_TIM_OC_IsEnabledFast\n
* CCMR2 OC3FE LL_TIM_OC_IsEnabledFast\n
* CCMR2 OC4FE LL_TIM_OC_IsEnabledFast\n
* CCMR3 OC5FE LL_TIM_OC_IsEnabledFast\n
* CCMR3 OC6FE LL_TIM_OC_IsEnabledFast
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_OC_IsEnabledFast(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
const __IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
uint32_t bitfield = TIM_CCMR1_OC1FE << SHIFT_TAB_OCxx[iChannel];
return ((READ_BIT(*pReg, bitfield) == bitfield) ? 1UL : 0UL);
}
/**
* @brief Enable compare register (TIMx_CCRx) preload for the output channel.
* @rmtoll CCMR1 OC1PE LL_TIM_OC_EnablePreload\n
* CCMR1 OC2PE LL_TIM_OC_EnablePreload\n
* CCMR2 OC3PE LL_TIM_OC_EnablePreload\n
* CCMR2 OC4PE LL_TIM_OC_EnablePreload\n
* CCMR3 OC5PE LL_TIM_OC_EnablePreload\n
* CCMR3 OC6PE LL_TIM_OC_EnablePreload
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_EnablePreload(TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
SET_BIT(*pReg, (TIM_CCMR1_OC1PE << SHIFT_TAB_OCxx[iChannel]));
}
/**
* @brief Disable compare register (TIMx_CCRx) preload for the output channel.
* @rmtoll CCMR1 OC1PE LL_TIM_OC_DisablePreload\n
* CCMR1 OC2PE LL_TIM_OC_DisablePreload\n
* CCMR2 OC3PE LL_TIM_OC_DisablePreload\n
* CCMR2 OC4PE LL_TIM_OC_DisablePreload\n
* CCMR3 OC5PE LL_TIM_OC_DisablePreload\n
* CCMR3 OC6PE LL_TIM_OC_DisablePreload
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_DisablePreload(TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
CLEAR_BIT(*pReg, (TIM_CCMR1_OC1PE << SHIFT_TAB_OCxx[iChannel]));
}
/**
* @brief Indicates whether compare register (TIMx_CCRx) preload is enabled for the output channel.
* @rmtoll CCMR1 OC1PE LL_TIM_OC_IsEnabledPreload\n
* CCMR1 OC2PE LL_TIM_OC_IsEnabledPreload\n
* CCMR2 OC3PE LL_TIM_OC_IsEnabledPreload\n
* CCMR2 OC4PE LL_TIM_OC_IsEnabledPreload\n
* CCMR3 OC5PE LL_TIM_OC_IsEnabledPreload\n
* CCMR3 OC6PE LL_TIM_OC_IsEnabledPreload
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_OC_IsEnabledPreload(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
const __IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
uint32_t bitfield = TIM_CCMR1_OC1PE << SHIFT_TAB_OCxx[iChannel];
return ((READ_BIT(*pReg, bitfield) == bitfield) ? 1UL : 0UL);
}
/**
* @brief Enable clearing the output channel on an external event.
* @note This function can only be used in Output compare and PWM modes. It does not work in Forced mode.
* @note Macro IS_TIM_OCXREF_CLEAR_INSTANCE(TIMx) can be used to check whether
* or not a timer instance can clear the OCxREF signal on an external event.
* @rmtoll CCMR1 OC1CE LL_TIM_OC_EnableClear\n
* CCMR1 OC2CE LL_TIM_OC_EnableClear\n
* CCMR2 OC3CE LL_TIM_OC_EnableClear\n
* CCMR2 OC4CE LL_TIM_OC_EnableClear\n
* CCMR3 OC5CE LL_TIM_OC_EnableClear\n
* CCMR3 OC6CE LL_TIM_OC_EnableClear
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_EnableClear(TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
SET_BIT(*pReg, (TIM_CCMR1_OC1CE << SHIFT_TAB_OCxx[iChannel]));
}
/**
* @brief Disable clearing the output channel on an external event.
* @note Macro IS_TIM_OCXREF_CLEAR_INSTANCE(TIMx) can be used to check whether
* or not a timer instance can clear the OCxREF signal on an external event.
* @rmtoll CCMR1 OC1CE LL_TIM_OC_DisableClear\n
* CCMR1 OC2CE LL_TIM_OC_DisableClear\n
* CCMR2 OC3CE LL_TIM_OC_DisableClear\n
* CCMR2 OC4CE LL_TIM_OC_DisableClear\n
* CCMR3 OC5CE LL_TIM_OC_DisableClear\n
* CCMR3 OC6CE LL_TIM_OC_DisableClear
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_DisableClear(TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
CLEAR_BIT(*pReg, (TIM_CCMR1_OC1CE << SHIFT_TAB_OCxx[iChannel]));
}
/**
* @brief Indicates clearing the output channel on an external event is enabled for the output channel.
* @note This function enables clearing the output channel on an external event.
* @note This function can only be used in Output compare and PWM modes. It does not work in Forced mode.
* @note Macro IS_TIM_OCXREF_CLEAR_INSTANCE(TIMx) can be used to check whether
* or not a timer instance can clear the OCxREF signal on an external event.
* @rmtoll CCMR1 OC1CE LL_TIM_OC_IsEnabledClear\n
* CCMR1 OC2CE LL_TIM_OC_IsEnabledClear\n
* CCMR2 OC3CE LL_TIM_OC_IsEnabledClear\n
* CCMR2 OC4CE LL_TIM_OC_IsEnabledClear\n
* CCMR3 OC5CE LL_TIM_OC_IsEnabledClear\n
* CCMR3 OC6CE LL_TIM_OC_IsEnabledClear
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @arg @ref LL_TIM_CHANNEL_CH5
* @arg @ref LL_TIM_CHANNEL_CH6
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_OC_IsEnabledClear(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
const __IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
uint32_t bitfield = TIM_CCMR1_OC1CE << SHIFT_TAB_OCxx[iChannel];
return ((READ_BIT(*pReg, bitfield) == bitfield) ? 1UL : 0UL);
}
/**
* @brief Set the dead-time delay (delay inserted between the rising edge of the OCxREF signal and the rising edge of
* the Ocx and OCxN signals).
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* dead-time insertion feature is supported by a timer instance.
* @note Helper macro @ref __LL_TIM_CALC_DEADTIME can be used to calculate the DeadTime parameter
* @rmtoll BDTR DTG LL_TIM_OC_SetDeadTime
* @param TIMx Timer instance
* @param DeadTime between Min_Data=0 and Max_Data=255
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetDeadTime(TIM_TypeDef *TIMx, uint32_t DeadTime)
{
MODIFY_REG(TIMx->BDTR, TIM_BDTR_DTG, DeadTime);
}
/**
* @brief Set compare value for output channel 1 (TIMx_CCR1).
* @note In 32-bit timer implementations compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC1_INSTANCE(TIMx) can be used to check whether or not
* output channel 1 is supported by a timer instance.
* @note If dithering is activated, CompareValue can be calculated with macro @ref __LL_TIM_CALC_DELAY_DITHER .
* @rmtoll CCR1 CCR1 LL_TIM_OC_SetCompareCH1
* @param TIMx Timer instance
* @param CompareValue between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetCompareCH1(TIM_TypeDef *TIMx, uint32_t CompareValue)
{
WRITE_REG(TIMx->CCR1, CompareValue);
}
/**
* @brief Set compare value for output channel 2 (TIMx_CCR2).
* @note In 32-bit timer implementations compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC2_INSTANCE(TIMx) can be used to check whether or not
* output channel 2 is supported by a timer instance.
* @note If dithering is activated, CompareValue can be calculated with macro @ref __LL_TIM_CALC_DELAY_DITHER .
* @rmtoll CCR2 CCR2 LL_TIM_OC_SetCompareCH2
* @param TIMx Timer instance
* @param CompareValue between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetCompareCH2(TIM_TypeDef *TIMx, uint32_t CompareValue)
{
WRITE_REG(TIMx->CCR2, CompareValue);
}
/**
* @brief Set compare value for output channel 3 (TIMx_CCR3).
* @note In 32-bit timer implementations compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC3_INSTANCE(TIMx) can be used to check whether or not
* output channel is supported by a timer instance.
* @note If dithering is activated, CompareValue can be calculated with macro @ref __LL_TIM_CALC_DELAY_DITHER .
* @rmtoll CCR3 CCR3 LL_TIM_OC_SetCompareCH3
* @param TIMx Timer instance
* @param CompareValue between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetCompareCH3(TIM_TypeDef *TIMx, uint32_t CompareValue)
{
WRITE_REG(TIMx->CCR3, CompareValue);
}
/**
* @brief Set compare value for output channel 4 (TIMx_CCR4).
* @note In 32-bit timer implementations compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC4_INSTANCE(TIMx) can be used to check whether or not
* output channel 4 is supported by a timer instance.
* @note If dithering is activated, CompareValue can be calculated with macro @ref __LL_TIM_CALC_DELAY_DITHER .
* @rmtoll CCR4 CCR4 LL_TIM_OC_SetCompareCH4
* @param TIMx Timer instance
* @param CompareValue between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetCompareCH4(TIM_TypeDef *TIMx, uint32_t CompareValue)
{
WRITE_REG(TIMx->CCR4, CompareValue);
}
/**
* @brief Set compare value for output channel 5 (TIMx_CCR5).
* @note Macro IS_TIM_CC5_INSTANCE(TIMx) can be used to check whether or not
* output channel 5 is supported by a timer instance.
* @note If dithering is activated, CompareValue can be calculated with macro @ref __LL_TIM_CALC_DELAY_DITHER .
* @rmtoll CCR5 CCR5 LL_TIM_OC_SetCompareCH5
* @param TIMx Timer instance
* @param CompareValue between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetCompareCH5(TIM_TypeDef *TIMx, uint32_t CompareValue)
{
MODIFY_REG(TIMx->CCR5, TIM_CCR5_CCR5, CompareValue);
}
/**
* @brief Set compare value for output channel 6 (TIMx_CCR6).
* @note Macro IS_TIM_CC6_INSTANCE(TIMx) can be used to check whether or not
* output channel 6 is supported by a timer instance.
* @note If dithering is activated, CompareValue can be calculated with macro @ref __LL_TIM_CALC_DELAY_DITHER .
* @rmtoll CCR6 CCR6 LL_TIM_OC_SetCompareCH6
* @param TIMx Timer instance
* @param CompareValue between Min_Data=0 and Max_Data=65535
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetCompareCH6(TIM_TypeDef *TIMx, uint32_t CompareValue)
{
WRITE_REG(TIMx->CCR6, CompareValue);
}
/**
* @brief Get compare value (TIMx_CCR1) set for output channel 1.
* @note In 32-bit timer implementations returned compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC1_INSTANCE(TIMx) can be used to check whether or not
* output channel 1 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR1 CCR1 LL_TIM_OC_GetCompareCH1
* @param TIMx Timer instance
* @retval CompareValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetCompareCH1(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR1));
}
/**
* @brief Get compare value (TIMx_CCR2) set for output channel 2.
* @note In 32-bit timer implementations returned compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC2_INSTANCE(TIMx) can be used to check whether or not
* output channel 2 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR2 CCR2 LL_TIM_OC_GetCompareCH2
* @param TIMx Timer instance
* @retval CompareValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetCompareCH2(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR2));
}
/**
* @brief Get compare value (TIMx_CCR3) set for output channel 3.
* @note In 32-bit timer implementations returned compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC3_INSTANCE(TIMx) can be used to check whether or not
* output channel 3 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR3 CCR3 LL_TIM_OC_GetCompareCH3
* @param TIMx Timer instance
* @retval CompareValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetCompareCH3(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR3));
}
/**
* @brief Get compare value (TIMx_CCR4) set for output channel 4.
* @note In 32-bit timer implementations returned compare value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC4_INSTANCE(TIMx) can be used to check whether or not
* output channel 4 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR4 CCR4 LL_TIM_OC_GetCompareCH4
* @param TIMx Timer instance
* @retval CompareValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetCompareCH4(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR4));
}
/**
* @brief Get compare value (TIMx_CCR5) set for output channel 5.
* @note Macro IS_TIM_CC5_INSTANCE(TIMx) can be used to check whether or not
* output channel 5 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR5 CCR5 LL_TIM_OC_GetCompareCH5
* @param TIMx Timer instance
* @retval CompareValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetCompareCH5(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->CCR5, TIM_CCR5_CCR5));
}
/**
* @brief Get compare value (TIMx_CCR6) set for output channel 6.
* @note Macro IS_TIM_CC6_INSTANCE(TIMx) can be used to check whether or not
* output channel 6 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR6 CCR6 LL_TIM_OC_GetCompareCH6
* @param TIMx Timer instance
* @retval CompareValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetCompareCH6(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR6));
}
/**
* @brief Select on which reference signal the OC5REF is combined to.
* @note Macro IS_TIM_COMBINED3PHASEPWM_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports the combined 3-phase PWM mode.
* @rmtoll CCR5 GC5C3 LL_TIM_SetCH5CombinedChannels\n
* CCR5 GC5C2 LL_TIM_SetCH5CombinedChannels\n
* CCR5 GC5C1 LL_TIM_SetCH5CombinedChannels
* @param TIMx Timer instance
* @param GroupCH5 This parameter can be a combination of the following values:
* @arg @ref LL_TIM_GROUPCH5_NONE
* @arg @ref LL_TIM_GROUPCH5_OC1REFC
* @arg @ref LL_TIM_GROUPCH5_OC2REFC
* @arg @ref LL_TIM_GROUPCH5_OC3REFC
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetCH5CombinedChannels(TIM_TypeDef *TIMx, uint32_t GroupCH5)
{
MODIFY_REG(TIMx->CCR5, (TIM_CCR5_GC5C3 | TIM_CCR5_GC5C2 | TIM_CCR5_GC5C1), GroupCH5);
}
/**
* @brief Set the pulse on compare pulse width prescaler.
* @note Macro IS_TIM_PULSEONCOMPARE_INSTANCE(TIMx) can be used to check
* whether or not the pulse on compare feature is supported by the timer
* instance.
* @rmtoll ECR PWPRSC LL_TIM_OC_SetPulseWidthPrescaler
* @param TIMx Timer instance
* @param PulseWidthPrescaler This parameter can be one of the following values:
* @arg @ref LL_TIM_PWPRSC_X1
* @arg @ref LL_TIM_PWPRSC_X2
* @arg @ref LL_TIM_PWPRSC_X4
* @arg @ref LL_TIM_PWPRSC_X8
* @arg @ref LL_TIM_PWPRSC_X16
* @arg @ref LL_TIM_PWPRSC_X32
* @arg @ref LL_TIM_PWPRSC_X64
* @arg @ref LL_TIM_PWPRSC_X128
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetPulseWidthPrescaler(TIM_TypeDef *TIMx, uint32_t PulseWidthPrescaler)
{
MODIFY_REG(TIMx->ECR, TIM_ECR_PWPRSC, PulseWidthPrescaler);
}
/**
* @brief Get the pulse on compare pulse width prescaler.
* @note Macro IS_TIM_PULSEONCOMPARE_INSTANCE(TIMx) can be used to check
* whether or not the pulse on compare feature is supported by the timer
* instance.
* @rmtoll ECR PWPRSC LL_TIM_OC_GetPulseWidthPrescaler
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_PWPRSC_X1
* @arg @ref LL_TIM_PWPRSC_X2
* @arg @ref LL_TIM_PWPRSC_X4
* @arg @ref LL_TIM_PWPRSC_X8
* @arg @ref LL_TIM_PWPRSC_X16
* @arg @ref LL_TIM_PWPRSC_X32
* @arg @ref LL_TIM_PWPRSC_X64
* @arg @ref LL_TIM_PWPRSC_X128
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetPulseWidthPrescaler(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->ECR, TIM_ECR_PWPRSC));
}
/**
* @brief Set the pulse on compare pulse width duration.
* @note Macro IS_TIM_PULSEONCOMPARE_INSTANCE(TIMx) can be used to check
* whether or not the pulse on compare feature is supported by the timer
* instance.
* @rmtoll ECR PW LL_TIM_OC_SetPulseWidth
* @param TIMx Timer instance
* @param PulseWidth This parameter can be between Min_Data=0 and Max_Data=255
* @retval None
*/
__STATIC_INLINE void LL_TIM_OC_SetPulseWidth(TIM_TypeDef *TIMx, uint32_t PulseWidth)
{
MODIFY_REG(TIMx->ECR, TIM_ECR_PW, PulseWidth << TIM_ECR_PW_Pos);
}
/**
* @brief Get the pulse on compare pulse width duration.
* @note Macro IS_TIM_PULSEONCOMPARE_INSTANCE(TIMx) can be used to check
* whether or not the pulse on compare feature is supported by the timer
* instance.
* @rmtoll ECR PW LL_TIM_OC_GetPulseWidth
* @param TIMx Timer instance
* @retval Returned value can be between Min_Data=0 and Max_Data=255:
*/
__STATIC_INLINE uint32_t LL_TIM_OC_GetPulseWidth(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->ECR, TIM_ECR_PW));
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Input_Channel Input channel configuration
* @{
*/
/**
* @brief Configure input channel.
* @rmtoll CCMR1 CC1S LL_TIM_IC_Config\n
* CCMR1 IC1PSC LL_TIM_IC_Config\n
* CCMR1 IC1F LL_TIM_IC_Config\n
* CCMR1 CC2S LL_TIM_IC_Config\n
* CCMR1 IC2PSC LL_TIM_IC_Config\n
* CCMR1 IC2F LL_TIM_IC_Config\n
* CCMR2 CC3S LL_TIM_IC_Config\n
* CCMR2 IC3PSC LL_TIM_IC_Config\n
* CCMR2 IC3F LL_TIM_IC_Config\n
* CCMR2 CC4S LL_TIM_IC_Config\n
* CCMR2 IC4PSC LL_TIM_IC_Config\n
* CCMR2 IC4F LL_TIM_IC_Config\n
* CCER CC1P LL_TIM_IC_Config\n
* CCER CC1NP LL_TIM_IC_Config\n
* CCER CC2P LL_TIM_IC_Config\n
* CCER CC2NP LL_TIM_IC_Config\n
* CCER CC3P LL_TIM_IC_Config\n
* CCER CC3NP LL_TIM_IC_Config\n
* CCER CC4P LL_TIM_IC_Config\n
* CCER CC4NP LL_TIM_IC_Config
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @param Configuration This parameter must be a combination of all the following values:
* @arg @ref LL_TIM_ACTIVEINPUT_DIRECTTI or @ref LL_TIM_ACTIVEINPUT_INDIRECTTI or @ref LL_TIM_ACTIVEINPUT_TRC
* @arg @ref LL_TIM_ICPSC_DIV1 or ... or @ref LL_TIM_ICPSC_DIV8
* @arg @ref LL_TIM_IC_FILTER_FDIV1 or ... or @ref LL_TIM_IC_FILTER_FDIV32_N8
* @arg @ref LL_TIM_IC_POLARITY_RISING or @ref LL_TIM_IC_POLARITY_FALLING or @ref LL_TIM_IC_POLARITY_BOTHEDGE
* @retval None
*/
__STATIC_INLINE void LL_TIM_IC_Config(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t Configuration)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
MODIFY_REG(*pReg, ((TIM_CCMR1_IC1F | TIM_CCMR1_IC1PSC | TIM_CCMR1_CC1S) << SHIFT_TAB_ICxx[iChannel]),
((Configuration >> 16U) & (TIM_CCMR1_IC1F | TIM_CCMR1_IC1PSC | TIM_CCMR1_CC1S)) \
<< SHIFT_TAB_ICxx[iChannel]);
MODIFY_REG(TIMx->CCER, ((TIM_CCER_CC1NP | TIM_CCER_CC1P) << SHIFT_TAB_CCxP[iChannel]),
(Configuration & (TIM_CCER_CC1NP | TIM_CCER_CC1P)) << SHIFT_TAB_CCxP[iChannel]);
}
/**
* @brief Set the active input.
* @rmtoll CCMR1 CC1S LL_TIM_IC_SetActiveInput\n
* CCMR1 CC2S LL_TIM_IC_SetActiveInput\n
* CCMR2 CC3S LL_TIM_IC_SetActiveInput\n
* CCMR2 CC4S LL_TIM_IC_SetActiveInput
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @param ICActiveInput This parameter can be one of the following values:
* @arg @ref LL_TIM_ACTIVEINPUT_DIRECTTI
* @arg @ref LL_TIM_ACTIVEINPUT_INDIRECTTI
* @arg @ref LL_TIM_ACTIVEINPUT_TRC
* @retval None
*/
__STATIC_INLINE void LL_TIM_IC_SetActiveInput(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ICActiveInput)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
MODIFY_REG(*pReg, ((TIM_CCMR1_CC1S) << SHIFT_TAB_ICxx[iChannel]), (ICActiveInput >> 16U) << SHIFT_TAB_ICxx[iChannel]);
}
/**
* @brief Get the current active input.
* @rmtoll CCMR1 CC1S LL_TIM_IC_GetActiveInput\n
* CCMR1 CC2S LL_TIM_IC_GetActiveInput\n
* CCMR2 CC3S LL_TIM_IC_GetActiveInput\n
* CCMR2 CC4S LL_TIM_IC_GetActiveInput
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_ACTIVEINPUT_DIRECTTI
* @arg @ref LL_TIM_ACTIVEINPUT_INDIRECTTI
* @arg @ref LL_TIM_ACTIVEINPUT_TRC
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetActiveInput(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
const __IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
return ((READ_BIT(*pReg, ((TIM_CCMR1_CC1S) << SHIFT_TAB_ICxx[iChannel])) >> SHIFT_TAB_ICxx[iChannel]) << 16U);
}
/**
* @brief Set the prescaler of input channel.
* @rmtoll CCMR1 IC1PSC LL_TIM_IC_SetPrescaler\n
* CCMR1 IC2PSC LL_TIM_IC_SetPrescaler\n
* CCMR2 IC3PSC LL_TIM_IC_SetPrescaler\n
* CCMR2 IC4PSC LL_TIM_IC_SetPrescaler
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @param ICPrescaler This parameter can be one of the following values:
* @arg @ref LL_TIM_ICPSC_DIV1
* @arg @ref LL_TIM_ICPSC_DIV2
* @arg @ref LL_TIM_ICPSC_DIV4
* @arg @ref LL_TIM_ICPSC_DIV8
* @retval None
*/
__STATIC_INLINE void LL_TIM_IC_SetPrescaler(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ICPrescaler)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
MODIFY_REG(*pReg, ((TIM_CCMR1_IC1PSC) << SHIFT_TAB_ICxx[iChannel]), (ICPrescaler >> 16U) << SHIFT_TAB_ICxx[iChannel]);
}
/**
* @brief Get the current prescaler value acting on an input channel.
* @rmtoll CCMR1 IC1PSC LL_TIM_IC_GetPrescaler\n
* CCMR1 IC2PSC LL_TIM_IC_GetPrescaler\n
* CCMR2 IC3PSC LL_TIM_IC_GetPrescaler\n
* CCMR2 IC4PSC LL_TIM_IC_GetPrescaler
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_ICPSC_DIV1
* @arg @ref LL_TIM_ICPSC_DIV2
* @arg @ref LL_TIM_ICPSC_DIV4
* @arg @ref LL_TIM_ICPSC_DIV8
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetPrescaler(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
const __IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
return ((READ_BIT(*pReg, ((TIM_CCMR1_IC1PSC) << SHIFT_TAB_ICxx[iChannel])) >> SHIFT_TAB_ICxx[iChannel]) << 16U);
}
/**
* @brief Set the input filter duration.
* @rmtoll CCMR1 IC1F LL_TIM_IC_SetFilter\n
* CCMR1 IC2F LL_TIM_IC_SetFilter\n
* CCMR2 IC3F LL_TIM_IC_SetFilter\n
* CCMR2 IC4F LL_TIM_IC_SetFilter
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @param ICFilter This parameter can be one of the following values:
* @arg @ref LL_TIM_IC_FILTER_FDIV1
* @arg @ref LL_TIM_IC_FILTER_FDIV1_N2
* @arg @ref LL_TIM_IC_FILTER_FDIV1_N4
* @arg @ref LL_TIM_IC_FILTER_FDIV1_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV2_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV2_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV4_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV4_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV8_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV8_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV16_N5
* @arg @ref LL_TIM_IC_FILTER_FDIV16_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV16_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV32_N5
* @arg @ref LL_TIM_IC_FILTER_FDIV32_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV32_N8
* @retval None
*/
__STATIC_INLINE void LL_TIM_IC_SetFilter(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ICFilter)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
MODIFY_REG(*pReg, ((TIM_CCMR1_IC1F) << SHIFT_TAB_ICxx[iChannel]), (ICFilter >> 16U) << SHIFT_TAB_ICxx[iChannel]);
}
/**
* @brief Get the input filter duration.
* @rmtoll CCMR1 IC1F LL_TIM_IC_GetFilter\n
* CCMR1 IC2F LL_TIM_IC_GetFilter\n
* CCMR2 IC3F LL_TIM_IC_GetFilter\n
* CCMR2 IC4F LL_TIM_IC_GetFilter
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_IC_FILTER_FDIV1
* @arg @ref LL_TIM_IC_FILTER_FDIV1_N2
* @arg @ref LL_TIM_IC_FILTER_FDIV1_N4
* @arg @ref LL_TIM_IC_FILTER_FDIV1_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV2_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV2_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV4_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV4_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV8_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV8_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV16_N5
* @arg @ref LL_TIM_IC_FILTER_FDIV16_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV16_N8
* @arg @ref LL_TIM_IC_FILTER_FDIV32_N5
* @arg @ref LL_TIM_IC_FILTER_FDIV32_N6
* @arg @ref LL_TIM_IC_FILTER_FDIV32_N8
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetFilter(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
const __IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->CCMR1) + OFFSET_TAB_CCMRx[iChannel]));
return ((READ_BIT(*pReg, ((TIM_CCMR1_IC1F) << SHIFT_TAB_ICxx[iChannel])) >> SHIFT_TAB_ICxx[iChannel]) << 16U);
}
/**
* @brief Set the input channel polarity.
* @rmtoll CCER CC1P LL_TIM_IC_SetPolarity\n
* CCER CC1NP LL_TIM_IC_SetPolarity\n
* CCER CC2P LL_TIM_IC_SetPolarity\n
* CCER CC2NP LL_TIM_IC_SetPolarity\n
* CCER CC3P LL_TIM_IC_SetPolarity\n
* CCER CC3NP LL_TIM_IC_SetPolarity\n
* CCER CC4P LL_TIM_IC_SetPolarity\n
* CCER CC4NP LL_TIM_IC_SetPolarity
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @param ICPolarity This parameter can be one of the following values:
* @arg @ref LL_TIM_IC_POLARITY_RISING
* @arg @ref LL_TIM_IC_POLARITY_FALLING
* @arg @ref LL_TIM_IC_POLARITY_BOTHEDGE
* @retval None
*/
__STATIC_INLINE void LL_TIM_IC_SetPolarity(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ICPolarity)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
MODIFY_REG(TIMx->CCER, ((TIM_CCER_CC1NP | TIM_CCER_CC1P) << SHIFT_TAB_CCxP[iChannel]),
ICPolarity << SHIFT_TAB_CCxP[iChannel]);
}
/**
* @brief Get the current input channel polarity.
* @rmtoll CCER CC1P LL_TIM_IC_GetPolarity\n
* CCER CC1NP LL_TIM_IC_GetPolarity\n
* CCER CC2P LL_TIM_IC_GetPolarity\n
* CCER CC2NP LL_TIM_IC_GetPolarity\n
* CCER CC3P LL_TIM_IC_GetPolarity\n
* CCER CC3NP LL_TIM_IC_GetPolarity\n
* CCER CC4P LL_TIM_IC_GetPolarity\n
* CCER CC4NP LL_TIM_IC_GetPolarity
* @param TIMx Timer instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_TIM_CHANNEL_CH1
* @arg @ref LL_TIM_CHANNEL_CH2
* @arg @ref LL_TIM_CHANNEL_CH3
* @arg @ref LL_TIM_CHANNEL_CH4
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_IC_POLARITY_RISING
* @arg @ref LL_TIM_IC_POLARITY_FALLING
* @arg @ref LL_TIM_IC_POLARITY_BOTHEDGE
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetPolarity(const TIM_TypeDef *TIMx, uint32_t Channel)
{
uint8_t iChannel = TIM_GET_CHANNEL_INDEX(Channel);
return (READ_BIT(TIMx->CCER, ((TIM_CCER_CC1NP | TIM_CCER_CC1P) << SHIFT_TAB_CCxP[iChannel])) >>
SHIFT_TAB_CCxP[iChannel]);
}
/**
* @brief Connect the TIMx_CH1, CH2 and CH3 pins to the TI1 input (XOR combination).
* @note Macro IS_TIM_XOR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an XOR input.
* @rmtoll CR2 TI1S LL_TIM_IC_EnableXORCombination
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_IC_EnableXORCombination(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->CR2, TIM_CR2_TI1S);
}
/**
* @brief Disconnect the TIMx_CH1, CH2 and CH3 pins from the TI1 input.
* @note Macro IS_TIM_XOR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an XOR input.
* @rmtoll CR2 TI1S LL_TIM_IC_DisableXORCombination
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_IC_DisableXORCombination(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->CR2, TIM_CR2_TI1S);
}
/**
* @brief Indicates whether the TIMx_CH1, CH2 and CH3 pins are connectected to the TI1 input.
* @note Macro IS_TIM_XOR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an XOR input.
* @rmtoll CR2 TI1S LL_TIM_IC_IsEnabledXORCombination
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IC_IsEnabledXORCombination(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->CR2, TIM_CR2_TI1S) == (TIM_CR2_TI1S)) ? 1UL : 0UL);
}
/**
* @brief Get captured value for input channel 1.
* @note In 32-bit timer implementations returned captured value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC1_INSTANCE(TIMx) can be used to check whether or not
* input channel 1 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR1 CCR1 LL_TIM_IC_GetCaptureCH1
* @param TIMx Timer instance
* @retval CapturedValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetCaptureCH1(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR1));
}
/**
* @brief Get captured value for input channel 2.
* @note In 32-bit timer implementations returned captured value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC2_INSTANCE(TIMx) can be used to check whether or not
* input channel 2 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR2 CCR2 LL_TIM_IC_GetCaptureCH2
* @param TIMx Timer instance
* @retval CapturedValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetCaptureCH2(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR2));
}
/**
* @brief Get captured value for input channel 3.
* @note In 32-bit timer implementations returned captured value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC3_INSTANCE(TIMx) can be used to check whether or not
* input channel 3 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR3 CCR3 LL_TIM_IC_GetCaptureCH3
* @param TIMx Timer instance
* @retval CapturedValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetCaptureCH3(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR3));
}
/**
* @brief Get captured value for input channel 4.
* @note In 32-bit timer implementations returned captured value can be between 0x00000000 and 0xFFFFFFFF.
* @note Macro IS_TIM_32B_COUNTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports a 32 bits counter.
* @note Macro IS_TIM_CC4_INSTANCE(TIMx) can be used to check whether or not
* input channel 4 is supported by a timer instance.
* @note If dithering is activated, pay attention to the returned value interpretation.
* @rmtoll CCR4 CCR4 LL_TIM_IC_GetCaptureCH4
* @param TIMx Timer instance
* @retval CapturedValue (between Min_Data=0 and Max_Data=65535)
*/
__STATIC_INLINE uint32_t LL_TIM_IC_GetCaptureCH4(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_REG(TIMx->CCR4));
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Clock_Selection Counter clock selection
* @{
*/
/**
* @brief Enable external clock mode 2.
* @note When external clock mode 2 is enabled the counter is clocked by any active edge on the ETRF signal.
* @note Macro IS_TIM_CLOCKSOURCE_ETRMODE2_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports external clock mode2.
* @rmtoll SMCR ECE LL_TIM_EnableExternalClock
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableExternalClock(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->SMCR, TIM_SMCR_ECE);
}
/**
* @brief Disable external clock mode 2.
* @note Macro IS_TIM_CLOCKSOURCE_ETRMODE2_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports external clock mode2.
* @rmtoll SMCR ECE LL_TIM_DisableExternalClock
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableExternalClock(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->SMCR, TIM_SMCR_ECE);
}
/**
* @brief Indicate whether external clock mode 2 is enabled.
* @note Macro IS_TIM_CLOCKSOURCE_ETRMODE2_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports external clock mode2.
* @rmtoll SMCR ECE LL_TIM_IsEnabledExternalClock
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledExternalClock(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SMCR, TIM_SMCR_ECE) == (TIM_SMCR_ECE)) ? 1UL : 0UL);
}
/**
* @brief Set the clock source of the counter clock.
* @note when selected clock source is external clock mode 1, the timer input
* the external clock is applied is selected by calling the @ref LL_TIM_SetTriggerInput()
* function. This timer input must be configured by calling
* the @ref LL_TIM_IC_Config() function.
* @note Macro IS_TIM_CLOCKSOURCE_ETRMODE1_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports external clock mode1.
* @note Macro IS_TIM_CLOCKSOURCE_ETRMODE2_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports external clock mode2.
* @rmtoll SMCR SMS LL_TIM_SetClockSource\n
* SMCR ECE LL_TIM_SetClockSource
* @param TIMx Timer instance
* @param ClockSource This parameter can be one of the following values:
* @arg @ref LL_TIM_CLOCKSOURCE_INTERNAL
* @arg @ref LL_TIM_CLOCKSOURCE_EXT_MODE1
* @arg @ref LL_TIM_CLOCKSOURCE_EXT_MODE2
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetClockSource(TIM_TypeDef *TIMx, uint32_t ClockSource)
{
MODIFY_REG(TIMx->SMCR, TIM_SMCR_SMS | TIM_SMCR_ECE, ClockSource);
}
/**
* @brief Set the encoder interface mode.
* @note Macro IS_TIM_ENCODER_INTERFACE_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports the encoder mode.
* @rmtoll SMCR SMS LL_TIM_SetEncoderMode
* @param TIMx Timer instance
* @param EncoderMode This parameter can be one of the following values:
* @arg @ref LL_TIM_ENCODERMODE_X2_TI1
* @arg @ref LL_TIM_ENCODERMODE_X2_TI2
* @arg @ref LL_TIM_ENCODERMODE_X4_TI12
* @arg @ref LL_TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X2
* @arg @ref LL_TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X1
* @arg @ref LL_TIM_ENCODERMODE_DIRECTIONALCLOCK_X2
* @arg @ref LL_TIM_ENCODERMODE_DIRECTIONALCLOCK_X1_TI12
* @arg @ref LL_TIM_ENCODERMODE_X1_TI1
* @arg @ref LL_TIM_ENCODERMODE_X1_TI2
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetEncoderMode(TIM_TypeDef *TIMx, uint32_t EncoderMode)
{
MODIFY_REG(TIMx->SMCR, TIM_SMCR_SMS, EncoderMode);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Timer_Synchronization Timer synchronisation configuration
* @{
*/
/**
* @brief Set the trigger output (TRGO) used for timer synchronization .
* @note Macro IS_TIM_MASTER_INSTANCE(TIMx) can be used to check
* whether or not a timer instance can operate as a master timer.
* @rmtoll CR2 MMS LL_TIM_SetTriggerOutput
* @param TIMx Timer instance
* @param TimerSynchronization This parameter can be one of the following values:
* @arg @ref LL_TIM_TRGO_RESET
* @arg @ref LL_TIM_TRGO_ENABLE
* @arg @ref LL_TIM_TRGO_UPDATE
* @arg @ref LL_TIM_TRGO_CC1IF
* @arg @ref LL_TIM_TRGO_OC1REF
* @arg @ref LL_TIM_TRGO_OC2REF
* @arg @ref LL_TIM_TRGO_OC3REF
* @arg @ref LL_TIM_TRGO_OC4REF
* @arg @ref LL_TIM_TRGO_ENCODERCLK
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetTriggerOutput(TIM_TypeDef *TIMx, uint32_t TimerSynchronization)
{
MODIFY_REG(TIMx->CR2, TIM_CR2_MMS, TimerSynchronization);
}
/**
* @brief Set the trigger output 2 (TRGO2) used for ADC synchronization .
* @note Macro IS_TIM_TRGO2_INSTANCE(TIMx) can be used to check
* whether or not a timer instance can be used for ADC synchronization.
* @rmtoll CR2 MMS2 LL_TIM_SetTriggerOutput2
* @param TIMx Timer Instance
* @param ADCSynchronization This parameter can be one of the following values:
* @arg @ref LL_TIM_TRGO2_RESET
* @arg @ref LL_TIM_TRGO2_ENABLE
* @arg @ref LL_TIM_TRGO2_UPDATE
* @arg @ref LL_TIM_TRGO2_CC1F
* @arg @ref LL_TIM_TRGO2_OC1
* @arg @ref LL_TIM_TRGO2_OC2
* @arg @ref LL_TIM_TRGO2_OC3
* @arg @ref LL_TIM_TRGO2_OC4
* @arg @ref LL_TIM_TRGO2_OC5
* @arg @ref LL_TIM_TRGO2_OC6
* @arg @ref LL_TIM_TRGO2_OC4_RISINGFALLING
* @arg @ref LL_TIM_TRGO2_OC6_RISINGFALLING
* @arg @ref LL_TIM_TRGO2_OC4_RISING_OC6_RISING
* @arg @ref LL_TIM_TRGO2_OC4_RISING_OC6_FALLING
* @arg @ref LL_TIM_TRGO2_OC5_RISING_OC6_RISING
* @arg @ref LL_TIM_TRGO2_OC5_RISING_OC6_FALLING
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetTriggerOutput2(TIM_TypeDef *TIMx, uint32_t ADCSynchronization)
{
MODIFY_REG(TIMx->CR2, TIM_CR2_MMS2, ADCSynchronization);
}
/**
* @brief Set the synchronization mode of a slave timer.
* @note Macro IS_TIM_SLAVE_INSTANCE(TIMx) can be used to check whether or not
* a timer instance can operate as a slave timer.
* @rmtoll SMCR SMS LL_TIM_SetSlaveMode
* @param TIMx Timer instance
* @param SlaveMode This parameter can be one of the following values:
* @arg @ref LL_TIM_SLAVEMODE_DISABLED
* @arg @ref LL_TIM_SLAVEMODE_RESET
* @arg @ref LL_TIM_SLAVEMODE_GATED
* @arg @ref LL_TIM_SLAVEMODE_TRIGGER
* @arg @ref LL_TIM_SLAVEMODE_COMBINED_RESETTRIGGER
* @arg @ref LL_TIM_SLAVEMODE_COMBINED_GATEDRESET
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetSlaveMode(TIM_TypeDef *TIMx, uint32_t SlaveMode)
{
MODIFY_REG(TIMx->SMCR, TIM_SMCR_SMS, SlaveMode);
}
/**
* @brief Set the selects the trigger input to be used to synchronize the counter.
* @note Macro IS_TIM_SLAVE_INSTANCE(TIMx) can be used to check whether or not
* a timer instance can operate as a slave timer.
* @rmtoll SMCR TS LL_TIM_SetTriggerInput
* @param TIMx Timer instance
* @param TriggerInput This parameter can be one of the following values:
* @arg @ref LL_TIM_TS_ITR0
* @arg @ref LL_TIM_TS_ITR1
* @arg @ref LL_TIM_TS_ITR2
* @arg @ref LL_TIM_TS_ITR3
* @arg @ref LL_TIM_TS_ITR4
* @arg @ref LL_TIM_TS_ITR5
* @arg @ref LL_TIM_TS_ITR6
* @arg @ref LL_TIM_TS_ITR7
* @arg @ref LL_TIM_TS_ITR8
* @arg @ref LL_TIM_TS_ITR9
* @arg @ref LL_TIM_TS_ITR10
* @arg @ref LL_TIM_TS_ITR11
* @arg @ref LL_TIM_TS_TI1F_ED
* @arg @ref LL_TIM_TS_TI1FP1
* @arg @ref LL_TIM_TS_TI2FP2
* @arg @ref LL_TIM_TS_ETRF
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetTriggerInput(TIM_TypeDef *TIMx, uint32_t TriggerInput)
{
MODIFY_REG(TIMx->SMCR, TIM_SMCR_TS, TriggerInput);
}
/**
* @brief Enable the Master/Slave mode.
* @note Macro IS_TIM_SLAVE_INSTANCE(TIMx) can be used to check whether or not
* a timer instance can operate as a slave timer.
* @rmtoll SMCR MSM LL_TIM_EnableMasterSlaveMode
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableMasterSlaveMode(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->SMCR, TIM_SMCR_MSM);
}
/**
* @brief Disable the Master/Slave mode.
* @note Macro IS_TIM_SLAVE_INSTANCE(TIMx) can be used to check whether or not
* a timer instance can operate as a slave timer.
* @rmtoll SMCR MSM LL_TIM_DisableMasterSlaveMode
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableMasterSlaveMode(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->SMCR, TIM_SMCR_MSM);
}
/**
* @brief Indicates whether the Master/Slave mode is enabled.
* @note Macro IS_TIM_SLAVE_INSTANCE(TIMx) can be used to check whether or not
* a timer instance can operate as a slave timer.
* @rmtoll SMCR MSM LL_TIM_IsEnabledMasterSlaveMode
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledMasterSlaveMode(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SMCR, TIM_SMCR_MSM) == (TIM_SMCR_MSM)) ? 1UL : 0UL);
}
/**
* @brief Configure the external trigger (ETR) input.
* @note Macro IS_TIM_ETR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an external trigger input.
* @rmtoll SMCR ETP LL_TIM_ConfigETR\n
* SMCR ETPS LL_TIM_ConfigETR\n
* SMCR ETF LL_TIM_ConfigETR
* @param TIMx Timer instance
* @param ETRPolarity This parameter can be one of the following values:
* @arg @ref LL_TIM_ETR_POLARITY_NONINVERTED
* @arg @ref LL_TIM_ETR_POLARITY_INVERTED
* @param ETRPrescaler This parameter can be one of the following values:
* @arg @ref LL_TIM_ETR_PRESCALER_DIV1
* @arg @ref LL_TIM_ETR_PRESCALER_DIV2
* @arg @ref LL_TIM_ETR_PRESCALER_DIV4
* @arg @ref LL_TIM_ETR_PRESCALER_DIV8
* @param ETRFilter This parameter can be one of the following values:
* @arg @ref LL_TIM_ETR_FILTER_FDIV1
* @arg @ref LL_TIM_ETR_FILTER_FDIV1_N2
* @arg @ref LL_TIM_ETR_FILTER_FDIV1_N4
* @arg @ref LL_TIM_ETR_FILTER_FDIV1_N8
* @arg @ref LL_TIM_ETR_FILTER_FDIV2_N6
* @arg @ref LL_TIM_ETR_FILTER_FDIV2_N8
* @arg @ref LL_TIM_ETR_FILTER_FDIV4_N6
* @arg @ref LL_TIM_ETR_FILTER_FDIV4_N8
* @arg @ref LL_TIM_ETR_FILTER_FDIV8_N6
* @arg @ref LL_TIM_ETR_FILTER_FDIV8_N8
* @arg @ref LL_TIM_ETR_FILTER_FDIV16_N5
* @arg @ref LL_TIM_ETR_FILTER_FDIV16_N6
* @arg @ref LL_TIM_ETR_FILTER_FDIV16_N8
* @arg @ref LL_TIM_ETR_FILTER_FDIV32_N5
* @arg @ref LL_TIM_ETR_FILTER_FDIV32_N6
* @arg @ref LL_TIM_ETR_FILTER_FDIV32_N8
* @retval None
*/
__STATIC_INLINE void LL_TIM_ConfigETR(TIM_TypeDef *TIMx, uint32_t ETRPolarity, uint32_t ETRPrescaler,
uint32_t ETRFilter)
{
MODIFY_REG(TIMx->SMCR, TIM_SMCR_ETP | TIM_SMCR_ETPS | TIM_SMCR_ETF, ETRPolarity | ETRPrescaler | ETRFilter);
}
/**
* @brief Select the external trigger (ETR) input source.
* @note Macro IS_TIM_ETRSEL_INSTANCE(TIMx) can be used to check whether or
* not a timer instance supports ETR source selection.
* @rmtoll AF1 ETRSEL LL_TIM_SetETRSource
* @param TIMx Timer instance
* @param ETRSource This parameter can be one of the following values:
*
* TIM1: any combination of ETR_RMP where
*
* @arg @ref LL_TIM_TIM1_ETRSOURCE_GPIO
* @arg @ref LL_TIM_TIM1_ETRSOURCE_COMP1
* @arg @ref LL_TIM_TIM1_ETRSOURCE_COMP2
* @arg @ref LL_TIM_TIM1_ETRSOURCE_COMP3
* @arg @ref LL_TIM_TIM1_ETRSOURCE_COMP4
* @arg @ref LL_TIM_TIM1_ETRSOURCE_COMP5 (*)
* @arg @ref LL_TIM_TIM1_ETRSOURCE_COMP6 (*)
* @arg @ref LL_TIM_TIM1_ETRSOURCE_COMP7 (*)
* @arg @ref LL_TIM_TIM1_ETRSOURCE_ADC1_AWD1
* @arg @ref LL_TIM_TIM1_ETRSOURCE_ADC1_AWD2
* @arg @ref LL_TIM_TIM1_ETRSOURCE_ADC1_AWD3
* @arg @ref LL_TIM_TIM1_ETRSOURCE_ADC4_AWD1 (*)
* @arg @ref LL_TIM_TIM1_ETRSOURCE_ADC4_AWD2 (*)
* @arg @ref LL_TIM_TIM1_ETRSOURCE_ADC4_AWD3 (*)
*
* TIM2: any combination of ETR_RMP where
*
* @arg @ref LL_TIM_TIM2_ETRSOURCE_GPIO
* @arg @ref LL_TIM_TIM2_ETRSOURCE_COMP1
* @arg @ref LL_TIM_TIM2_ETRSOURCE_COMP2
* @arg @ref LL_TIM_TIM2_ETRSOURCE_COMP3
* @arg @ref LL_TIM_TIM2_ETRSOURCE_COMP4
* @arg @ref LL_TIM_TIM2_ETRSOURCE_COMP5 (*)
* @arg @ref LL_TIM_TIM2_ETRSOURCE_COMP6 (*)
* @arg @ref LL_TIM_TIM2_ETRSOURCE_COMP7 (*)
* @arg @ref LL_TIM_TIM2_ETRSOURCE_TIM3_ETR
* @arg @ref LL_TIM_TIM2_ETRSOURCE_TIM4_ETR
* @arg @ref LL_TIM_TIM2_ETRSOURCE_TIM5_ETR (*)
* @arg @ref LL_TIM_TIM2_ETRSOURCE_LSE
*
* TIM3: any combination of ETR_RMP where
*
* @arg @ref LL_TIM_TIM3_ETRSOURCE_GPIO
* @arg @ref LL_TIM_TIM3_ETRSOURCE_COMP1
* @arg @ref LL_TIM_TIM3_ETRSOURCE_COMP2
* @arg @ref LL_TIM_TIM3_ETRSOURCE_COMP3
* @arg @ref LL_TIM_TIM3_ETRSOURCE_COMP4
* @arg @ref LL_TIM_TIM3_ETRSOURCE_COMP5 (*)
* @arg @ref LL_TIM_TIM3_ETRSOURCE_COMP6 (*)
* @arg @ref LL_TIM_TIM3_ETRSOURCE_COMP7 (*)
* @arg @ref LL_TIM_TIM3_ETRSOURCE_TIM2_ETR
* @arg @ref LL_TIM_TIM3_ETRSOURCE_TIM4_ETR
* @arg @ref LL_TIM_TIM3_ETRSOURCE_ADC2_AWD1
* @arg @ref LL_TIM_TIM3_ETRSOURCE_ADC2_AWD2
* @arg @ref LL_TIM_TIM3_ETRSOURCE_ADC2_AWD3
*
* TIM4: any combination of ETR_RMP where
*
* @arg @ref LL_TIM_TIM4_ETRSOURCE_GPIO
* @arg @ref LL_TIM_TIM4_ETRSOURCE_COMP1
* @arg @ref LL_TIM_TIM4_ETRSOURCE_COMP2
* @arg @ref LL_TIM_TIM4_ETRSOURCE_COMP3
* @arg @ref LL_TIM_TIM4_ETRSOURCE_COMP4
* @arg @ref LL_TIM_TIM4_ETRSOURCE_COMP5 (*)
* @arg @ref LL_TIM_TIM4_ETRSOURCE_COMP6 (*)
* @arg @ref LL_TIM_TIM4_ETRSOURCE_COMP7 (*)
* @arg @ref LL_TIM_TIM4_ETRSOURCE_TIM3_ETR
* @arg @ref LL_TIM_TIM4_ETRSOURCE_TIM5_ETR (*)
*
* TIM5: any combination of ETR_RMP where (**)
*
* @arg @ref LL_TIM_TIM5_ETRSOURCE_GPIO (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_COMP1 (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_COMP2 (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_COMP3 (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_COMP4 (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_COMP5 (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_COMP6 (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_COMP7 (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_TIM2_ETR (*)
* @arg @ref LL_TIM_TIM5_ETRSOURCE_TIM3_ETR (*)
*
* TIM8: any combination of ETR_RMP where
*
* . . ETR_RMP can be one of the following values
* @arg @ref LL_TIM_TIM8_ETRSOURCE_GPIO
* @arg @ref LL_TIM_TIM8_ETRSOURCE_COMP1
* @arg @ref LL_TIM_TIM8_ETRSOURCE_COMP2
* @arg @ref LL_TIM_TIM8_ETRSOURCE_COMP3
* @arg @ref LL_TIM_TIM8_ETRSOURCE_COMP4
* @arg @ref LL_TIM_TIM8_ETRSOURCE_COMP5 (*)
* @arg @ref LL_TIM_TIM8_ETRSOURCE_COMP6 (*)
* @arg @ref LL_TIM_TIM8_ETRSOURCE_COMP7 (*)
* @arg @ref LL_TIM_TIM8_ETRSOURCE_ADC2_AWD1
* @arg @ref LL_TIM_TIM8_ETRSOURCE_ADC2_AWD2
* @arg @ref LL_TIM_TIM8_ETRSOURCE_ADC2_AWD3
* @arg @ref LL_TIM_TIM8_ETRSOURCE_ADC3_AWD1 (*)
* @arg @ref LL_TIM_TIM8_ETRSOURCE_ADC3_AWD2 (*)
* @arg @ref LL_TIM_TIM8_ETRSOURCE_ADC3_AWD3 (*)
*
* TIM20: any combination of ETR_RMP where (**)
*
* . . ETR_RMP can be one of the following values
* @arg @ref LL_TIM_TIM20_ETRSOURCE_GPIO (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_COMP1 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_COMP2 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_COMP3 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_COMP4 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_COMP5 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_COMP6 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_COMP7 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_ADC3_AWD1 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_ADC3_AWD2 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_ADC3_AWD3 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_ADC5_AWD1 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_ADC5_AWD2 (*)
* @arg @ref LL_TIM_TIM20_ETRSOURCE_ADC5_AWD3 (*)
*
* (*) Value not defined in all devices. \n
* (**) Register not available in all devices.
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetETRSource(TIM_TypeDef *TIMx, uint32_t ETRSource)
{
MODIFY_REG(TIMx->AF1, TIMx_AF1_ETRSEL, ETRSource);
}
/**
* @brief Enable SMS preload.
* @note Macro IS_TIM_SMS_PRELOAD_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports the preload of SMS field in SMCR register.
* @rmtoll SMCR SMSPE LL_TIM_EnableSMSPreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableSMSPreload(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->SMCR, TIM_SMCR_SMSPE);
}
/**
* @brief Disable SMS preload.
* @note Macro IS_TIM_SMS_PRELOAD_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports the preload of SMS field in SMCR register.
* @rmtoll SMCR SMSPE LL_TIM_DisableSMSPreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableSMSPreload(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->SMCR, TIM_SMCR_SMSPE);
}
/**
* @brief Indicate whether SMS preload is enabled.
* @note Macro IS_TIM_SMS_PRELOAD_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports the preload of SMS field in SMCR register.
* @rmtoll SMCR SMSPE LL_TIM_IsEnabledSMSPreload
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledSMSPreload(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SMCR, TIM_SMCR_SMSPE) == (TIM_SMCR_SMSPE)) ? 1UL : 0UL);
}
/**
* @brief Set the preload source of SMS.
* @note Macro IS_TIM_SMS_PRELOAD_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports the preload of SMS field in SMCR register.
* @rmtoll SMCR SMSPS LL_TIM_SetSMSPreloadSource\n
* @param TIMx Timer instance
* @param PreloadSource This parameter can be one of the following values:
* @arg @ref LL_TIM_SMSPS_TIMUPDATE
* @arg @ref LL_TIM_SMSPS_INDEX
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetSMSPreloadSource(TIM_TypeDef *TIMx, uint32_t PreloadSource)
{
MODIFY_REG(TIMx->SMCR, TIM_SMCR_SMSPS, PreloadSource);
}
/**
* @brief Get the preload source of SMS.
* @note Macro IS_TIM_SMS_PRELOAD_INSTANCE(TIMx) can be used to check
* whether or not a timer instance supports the preload of SMS field in SMCR register.
* @rmtoll SMCR SMSPS LL_TIM_GetSMSPreloadSource\n
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_SMSPS_TIMUPDATE
* @arg @ref LL_TIM_SMSPS_INDEX
*/
__STATIC_INLINE uint32_t LL_TIM_GetSMSPreloadSource(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->SMCR, TIM_SMCR_SMSPS));
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Break_Function Break function configuration
* @{
*/
/**
* @brief Enable the break function.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR BKE LL_TIM_EnableBRK
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableBRK(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->BDTR, TIM_BDTR_BKE);
}
/**
* @brief Disable the break function.
* @rmtoll BDTR BKE LL_TIM_DisableBRK
* @param TIMx Timer instance
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableBRK(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->BDTR, TIM_BDTR_BKE);
}
/**
* @brief Configure the break input.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @note Bidirectional mode is only supported by advanced timer instances.
* Macro IS_TIM_ADVANCED_INSTANCE(TIMx) can be used to check whether or not
* a timer instance is an advanced-control timer.
* @note In bidirectional mode (BKBID bit set), the Break input is configured both
* in input mode and in open drain output mode. Any active Break event will
* assert a low logic level on the Break input to indicate an internal break
* event to external devices.
* @note When bidirectional mode isn't supported, BreakAFMode must be set to
* LL_TIM_BREAK_AFMODE_INPUT.
* @rmtoll BDTR BKP LL_TIM_ConfigBRK\n
* BDTR BKF LL_TIM_ConfigBRK\n
* BDTR BKBID LL_TIM_ConfigBRK
* @param TIMx Timer instance
* @param BreakPolarity This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK_POLARITY_LOW
* @arg @ref LL_TIM_BREAK_POLARITY_HIGH
* @param BreakFilter This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK_FILTER_FDIV1
* @arg @ref LL_TIM_BREAK_FILTER_FDIV1_N2
* @arg @ref LL_TIM_BREAK_FILTER_FDIV1_N4
* @arg @ref LL_TIM_BREAK_FILTER_FDIV1_N8
* @arg @ref LL_TIM_BREAK_FILTER_FDIV2_N6
* @arg @ref LL_TIM_BREAK_FILTER_FDIV2_N8
* @arg @ref LL_TIM_BREAK_FILTER_FDIV4_N6
* @arg @ref LL_TIM_BREAK_FILTER_FDIV4_N8
* @arg @ref LL_TIM_BREAK_FILTER_FDIV8_N6
* @arg @ref LL_TIM_BREAK_FILTER_FDIV8_N8
* @arg @ref LL_TIM_BREAK_FILTER_FDIV16_N5
* @arg @ref LL_TIM_BREAK_FILTER_FDIV16_N6
* @arg @ref LL_TIM_BREAK_FILTER_FDIV16_N8
* @arg @ref LL_TIM_BREAK_FILTER_FDIV32_N5
* @arg @ref LL_TIM_BREAK_FILTER_FDIV32_N6
* @arg @ref LL_TIM_BREAK_FILTER_FDIV32_N8
* @param BreakAFMode This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK_AFMODE_INPUT
* @arg @ref LL_TIM_BREAK_AFMODE_BIDIRECTIONAL
* @retval None
*/
__STATIC_INLINE void LL_TIM_ConfigBRK(TIM_TypeDef *TIMx, uint32_t BreakPolarity, uint32_t BreakFilter,
uint32_t BreakAFMode)
{
MODIFY_REG(TIMx->BDTR, TIM_BDTR_BKP | TIM_BDTR_BKF | TIM_BDTR_BKBID, BreakPolarity | BreakFilter | BreakAFMode);
}
/**
* @brief Disarm the break input (when it operates in bidirectional mode).
* @note The break input can be disarmed only when it is configured in
* bidirectional mode and when when MOE is reset.
* @note Purpose is to be able to have the input voltage back to high-state,
* whatever the time constant on the output .
* @rmtoll BDTR BKDSRM LL_TIM_DisarmBRK
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisarmBRK(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->BDTR, TIM_BDTR_BKDSRM);
}
/**
* @brief Enable the break 2 function.
* @note Macro IS_TIM_BKIN2_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a second break input.
* @rmtoll BDTR BK2E LL_TIM_EnableBRK2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableBRK2(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->BDTR, TIM_BDTR_BK2E);
}
/**
* @brief Disable the break 2 function.
* @note Macro IS_TIM_BKIN2_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a second break input.
* @rmtoll BDTR BK2E LL_TIM_DisableBRK2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableBRK2(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->BDTR, TIM_BDTR_BK2E);
}
/**
* @brief Configure the break 2 input.
* @note Macro IS_TIM_BKIN2_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a second break input.
* @note Bidirectional mode is only supported by advanced timer instances.
* Macro IS_TIM_ADVANCED_INSTANCE(TIMx) can be used to check whether or not
* a timer instance is an advanced-control timer.
* @note In bidirectional mode (BK2BID bit set), the Break 2 input is configured both
* in input mode and in open drain output mode. Any active Break event will
* assert a low logic level on the Break 2 input to indicate an internal break
* event to external devices.
* @note When bidirectional mode isn't supported, Break2AFMode must be set to
* LL_TIM_BREAK2_AFMODE_INPUT.
* @rmtoll BDTR BK2P LL_TIM_ConfigBRK2\n
* BDTR BK2F LL_TIM_ConfigBRK2\n
* BDTR BK2BID LL_TIM_ConfigBRK2
* @param TIMx Timer instance
* @param Break2Polarity This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK2_POLARITY_LOW
* @arg @ref LL_TIM_BREAK2_POLARITY_HIGH
* @param Break2Filter This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV1
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV1_N2
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV1_N4
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV1_N8
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV2_N6
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV2_N8
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV4_N6
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV4_N8
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV8_N6
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV8_N8
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV16_N5
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV16_N6
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV16_N8
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV32_N5
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV32_N6
* @arg @ref LL_TIM_BREAK2_FILTER_FDIV32_N8
* @param Break2AFMode This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK2_AFMODE_INPUT
* @arg @ref LL_TIM_BREAK2_AFMODE_BIDIRECTIONAL
* @retval None
*/
__STATIC_INLINE void LL_TIM_ConfigBRK2(TIM_TypeDef *TIMx, uint32_t Break2Polarity, uint32_t Break2Filter,
uint32_t Break2AFMode)
{
MODIFY_REG(TIMx->BDTR, TIM_BDTR_BK2P | TIM_BDTR_BK2F | TIM_BDTR_BK2BID, Break2Polarity | Break2Filter | Break2AFMode);
}
/**
* @brief Disarm the break 2 input (when it operates in bidirectional mode).
* @note The break 2 input can be disarmed only when it is configured in
* bidirectional mode and when when MOE is reset.
* @note Purpose is to be able to have the input voltage back to high-state,
* whatever the time constant on the output.
* @rmtoll BDTR BK2DSRM LL_TIM_DisarmBRK2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisarmBRK2(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->BDTR, TIM_BDTR_BK2DSRM);
}
/**
* @brief Select the outputs off state (enabled v.s. disabled) in Idle and Run modes.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR OSSI LL_TIM_SetOffStates\n
* BDTR OSSR LL_TIM_SetOffStates
* @param TIMx Timer instance
* @param OffStateIdle This parameter can be one of the following values:
* @arg @ref LL_TIM_OSSI_DISABLE
* @arg @ref LL_TIM_OSSI_ENABLE
* @param OffStateRun This parameter can be one of the following values:
* @arg @ref LL_TIM_OSSR_DISABLE
* @arg @ref LL_TIM_OSSR_ENABLE
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetOffStates(TIM_TypeDef *TIMx, uint32_t OffStateIdle, uint32_t OffStateRun)
{
MODIFY_REG(TIMx->BDTR, TIM_BDTR_OSSI | TIM_BDTR_OSSR, OffStateIdle | OffStateRun);
}
/**
* @brief Enable automatic output (MOE can be set by software or automatically when a break input is active).
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR AOE LL_TIM_EnableAutomaticOutput
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableAutomaticOutput(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->BDTR, TIM_BDTR_AOE);
}
/**
* @brief Disable automatic output (MOE can be set only by software).
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR AOE LL_TIM_DisableAutomaticOutput
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableAutomaticOutput(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->BDTR, TIM_BDTR_AOE);
}
/**
* @brief Indicate whether automatic output is enabled.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR AOE LL_TIM_IsEnabledAutomaticOutput
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledAutomaticOutput(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->BDTR, TIM_BDTR_AOE) == (TIM_BDTR_AOE)) ? 1UL : 0UL);
}
/**
* @brief Enable the outputs (set the MOE bit in TIMx_BDTR register).
* @note The MOE bit in TIMx_BDTR register allows to enable /disable the outputs by
* software and is reset in case of break or break2 event
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR MOE LL_TIM_EnableAllOutputs
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableAllOutputs(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->BDTR, TIM_BDTR_MOE);
}
/**
* @brief Disable the outputs (reset the MOE bit in TIMx_BDTR register).
* @note The MOE bit in TIMx_BDTR register allows to enable /disable the outputs by
* software and is reset in case of break or break2 event.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR MOE LL_TIM_DisableAllOutputs
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableAllOutputs(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->BDTR, TIM_BDTR_MOE);
}
/**
* @brief Indicates whether outputs are enabled.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides a break input.
* @rmtoll BDTR MOE LL_TIM_IsEnabledAllOutputs
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledAllOutputs(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->BDTR, TIM_BDTR_MOE) == (TIM_BDTR_MOE)) ? 1UL : 0UL);
}
/**
* @brief Enable the signals connected to the designated timer break input.
* @note Macro IS_TIM_BREAKSOURCE_INSTANCE(TIMx) can be used to check whether
* or not a timer instance allows for break input selection.
* @rmtoll AF1 BKINE LL_TIM_EnableBreakInputSource\n
* AF1 BKCMP1E LL_TIM_EnableBreakInputSource\n
* AF1 BKCMP2E LL_TIM_EnableBreakInputSource\n
* AF1 BKCMP3E LL_TIM_EnableBreakInputSource\n
* AF1 BKCMP4E LL_TIM_EnableBreakInputSource\n
* AF1 BKCMP5E LL_TIM_EnableBreakInputSource\n
* AF1 BKCMP6E LL_TIM_EnableBreakInputSource\n
* AF1 BKCMP7E LL_TIM_EnableBreakInputSource\n
* AF2 BK2NE LL_TIM_EnableBreakInputSource\n
* AF2 BK2CMP1E LL_TIM_EnableBreakInputSource\n
* AF2 BK2CMP2E LL_TIM_EnableBreakInputSource\n
* AF2 BK2CMP3E LL_TIM_EnableBreakInputSource\n
* AF2 BK2CMP4E LL_TIM_EnableBreakInputSource\n
* AF2 BK2CMP5E LL_TIM_EnableBreakInputSource\n
* AF2 BK2CMP6E LL_TIM_EnableBreakInputSource\n
* AF2 BK2CMP7E LL_TIM_EnableBreakInputSource
* @param TIMx Timer instance
* @param BreakInput This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK_INPUT_BKIN
* @arg @ref LL_TIM_BREAK_INPUT_BKIN2
* @param Source This parameter can be one of the following values:
* @arg @ref LL_TIM_BKIN_SOURCE_BKIN
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP1
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP2
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP3
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP4
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP5 (*)
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP6 (*)
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP7 (*)
*
* (*) Value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableBreakInputSource(TIM_TypeDef *TIMx, uint32_t BreakInput, uint32_t Source)
{
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->AF1) + BreakInput));
SET_BIT(*pReg, Source);
}
/**
* @brief Disable the signals connected to the designated timer break input.
* @note Macro IS_TIM_BREAKSOURCE_INSTANCE(TIMx) can be used to check whether
* or not a timer instance allows for break input selection.
* @rmtoll AF1 BKINE LL_TIM_DisableBreakInputSource\n
* AF1 BKCMP1E LL_TIM_DisableBreakInputSource\n
* AF1 BKCMP2E LL_TIM_DisableBreakInputSource\n
* AF1 BKCMP3E LL_TIM_DisableBreakInputSource\n
* AF1 BKCMP4E LL_TIM_DisableBreakInputSource\n
* AF1 BKCMP5E LL_TIM_DisableBreakInputSource\n
* AF1 BKCMP6E LL_TIM_DisableBreakInputSource\n
* AF1 BKCMP7E LL_TIM_DisableBreakInputSource\n
* AF2 BK2INE LL_TIM_DisableBreakInputSource\n
* AF2 BK2CMP1E LL_TIM_DisableBreakInputSource\n
* AF2 BK2CMP2E LL_TIM_DisableBreakInputSource\n
* AF2 BK2CMP3E LL_TIM_DisableBreakInputSource\n
* AF2 BK2CMP4E LL_TIM_DisableBreakInputSource\n
* AF2 BK2CMP5E LL_TIM_DisableBreakInputSource\n
* AF2 BK2CMP6E LL_TIM_DisableBreakInputSource\n
* AF2 BK2CMP7E LL_TIM_DisableBreakInputSource
* @param TIMx Timer instance
* @param BreakInput This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK_INPUT_BKIN
* @arg @ref LL_TIM_BREAK_INPUT_BKIN2
* @param Source This parameter can be one of the following values:
* @arg @ref LL_TIM_BKIN_SOURCE_BKIN
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP1
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP2
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP3
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP4
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP5 (*)
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP6 (*)
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP7 (*)
*
* (*) Value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableBreakInputSource(TIM_TypeDef *TIMx, uint32_t BreakInput, uint32_t Source)
{
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->AF1) + BreakInput));
CLEAR_BIT(*pReg, Source);
}
/**
* @brief Set the polarity of the break signal for the timer break input.
* @note Macro IS_TIM_BREAKSOURCE_INSTANCE(TIMx) can be used to check whether
* or not a timer instance allows for break input selection.
* @rmtoll AF1 BKINP LL_TIM_SetBreakInputSourcePolarity\n
* AF1 BKCMP1P LL_TIM_SetBreakInputSourcePolarity\n
* AF1 BKCMP2P LL_TIM_SetBreakInputSourcePolarity\n
* AF1 BKCMP3P LL_TIM_SetBreakInputSourcePolarity\n
* AF1 BKCMP4P LL_TIM_SetBreakInputSourcePolarity\n
* AF1 BKCMP5P LL_TIM_SetBreakInputSourcePolarity\n
* AF1 BKCMP6P LL_TIM_SetBreakInputSourcePolarity\n
* AF1 BKCMP7P LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2INP LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2CMP1P LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2CMP2P LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2CMP3P LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2CMP4P LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2CMP5P LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2CMP6P LL_TIM_SetBreakInputSourcePolarity\n
* AF2 BK2CMP7P LL_TIM_SetBreakInputSourcePolarity
* @param TIMx Timer instance
* @param BreakInput This parameter can be one of the following values:
* @arg @ref LL_TIM_BREAK_INPUT_BKIN
* @arg @ref LL_TIM_BREAK_INPUT_BKIN2
* @param Source This parameter can be one of the following values:
* @arg @ref LL_TIM_BKIN_SOURCE_BKIN
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP1
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP2
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP3
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP4
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP5 (*)
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP6 (*)
* @arg @ref LL_TIM_BKIN_SOURCE_BKCOMP7 (*)
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_TIM_BKIN_POLARITY_LOW
* @arg @ref LL_TIM_BKIN_POLARITY_HIGH
*
* (*) Value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetBreakInputSourcePolarity(TIM_TypeDef *TIMx, uint32_t BreakInput, uint32_t Source,
uint32_t Polarity)
{
__IO uint32_t *pReg = (__IO uint32_t *)((uint32_t)((uint32_t)(&TIMx->AF1) + BreakInput));
MODIFY_REG(*pReg, (TIMx_AF1_BKINP << TIM_POSITION_BRK_SOURCE), (Polarity << TIM_POSITION_BRK_SOURCE));
}
/**
* @brief Enable asymmetrical deadtime.
* @note Macro IS_TIM_DEADTIME_ASYMMETRICAL_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides asymmetrical deadtime.
* @rmtoll DTR2 DTAE LL_TIM_EnableAsymmetricalDeadTime
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableAsymmetricalDeadTime(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DTR2, TIM_DTR2_DTAE);
}
/**
* @brief Disable asymmetrical dead-time.
* @note Macro IS_TIM_DEADTIME_ASYMMETRICAL_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides asymmetrical deadtime.
* @rmtoll DTR2 DTAE LL_TIM_DisableAsymmetricalDeadTime
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableAsymmetricalDeadTime(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DTR2, TIM_DTR2_DTAE);
}
/**
* @brief Indicates whether asymmetrical deadtime is activated.
* @note Macro IS_TIM_DEADTIME_ASYMMETRICAL_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides asymmetrical deadtime.
* @rmtoll DTR2 DTAE LL_TIM_IsEnabledAsymmetricalDeadTime
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledAsymmetricalDeadTime(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DTR2, TIM_DTR2_DTAE) == (TIM_DTR2_DTAE)) ? 1UL : 0UL);
}
/**
* @brief Set the falling edge dead-time delay (delay inserted between the falling edge of the OCxREF signal and the
* rising edge of OCxN signals).
* @note Macro IS_TIM_DEADTIME_ASYMMETRICAL_INSTANCE(TIMx) can be used to check whether or not
* asymmetrical dead-time insertion feature is supported by a timer instance.
* @note Helper macro @ref __LL_TIM_CALC_DEADTIME can be used to calculate the DeadTime parameter
* @note This bit-field can not be modified as long as LOCK level 1, 2 or 3 has been programmed
* (LOCK bits in TIMx_BDTR register).
* @rmtoll DTR2 DTGF LL_TIM_SetFallingDeadTime
* @param TIMx Timer instance
* @param DeadTime between Min_Data=0 and Max_Data=255
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetFallingDeadTime(TIM_TypeDef *TIMx, uint32_t DeadTime)
{
MODIFY_REG(TIMx->DTR2, TIM_DTR2_DTGF, DeadTime);
}
/**
* @brief Get the falling edge dead-time delay (delay inserted between the falling edge of the OCxREF signal and
* the rising edge of OCxN signals).
* @note Macro IS_TIM_DEADTIME_ASYMMETRICAL_INSTANCE(TIMx) can be used to check whether or not
* asymmetrical dead-time insertion feature is supported by a timer instance.
* @note This bit-field can not be modified as long as LOCK level 1, 2 or 3 has been programmed
* (LOCK bits in TIMx_BDTR register).
* @rmtoll DTR2 DTGF LL_TIM_GetFallingDeadTime
* @param TIMx Timer instance
* @retval Returned value can be between Min_Data=0 and Max_Data=255:
*/
__STATIC_INLINE uint32_t LL_TIM_GetFallingDeadTime(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->DTR2, TIM_DTR2_DTGF));
}
/**
* @brief Enable deadtime preload.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides deadtime preload.
* @rmtoll DTR2 DTPE LL_TIM_EnableDeadTimePreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDeadTimePreload(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DTR2, TIM_DTR2_DTPE);
}
/**
* @brief Disable dead-time preload.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides deadtime preload.
* @rmtoll DTR2 DTPE LL_TIM_DisableDeadTimePreload
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDeadTimePreload(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DTR2, TIM_DTR2_DTPE);
}
/**
* @brief Indicates whether deadtime preload is activated.
* @note Macro IS_TIM_BREAK_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides deadtime preload.
* @rmtoll DTR2 DTPE LL_TIM_IsEnabledDeadTimePreload
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDeadTimePreload(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DTR2, TIM_DTR2_DTPE) == (TIM_DTR2_DTPE)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_DMA_Burst_Mode DMA burst mode configuration
* @{
*/
/**
* @brief Configures the timer DMA burst feature.
* @note Macro IS_TIM_DMABURST_INSTANCE(TIMx) can be used to check whether or
* not a timer instance supports the DMA burst mode.
* @rmtoll DCR DBL LL_TIM_ConfigDMABurst\n
* DCR DBA LL_TIM_ConfigDMABurst
* @param TIMx Timer instance
* @param DMABurstBaseAddress This parameter can be one of the following values:
* @arg @ref LL_TIM_DMABURST_BASEADDR_CR1
* @arg @ref LL_TIM_DMABURST_BASEADDR_CR2
* @arg @ref LL_TIM_DMABURST_BASEADDR_SMCR
* @arg @ref LL_TIM_DMABURST_BASEADDR_DIER
* @arg @ref LL_TIM_DMABURST_BASEADDR_SR
* @arg @ref LL_TIM_DMABURST_BASEADDR_EGR
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCMR1
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCMR2
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCER
* @arg @ref LL_TIM_DMABURST_BASEADDR_CNT
* @arg @ref LL_TIM_DMABURST_BASEADDR_PSC
* @arg @ref LL_TIM_DMABURST_BASEADDR_ARR
* @arg @ref LL_TIM_DMABURST_BASEADDR_RCR
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCR1
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCR2
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCR3
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCR4
* @arg @ref LL_TIM_DMABURST_BASEADDR_BDTR
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCMR3
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCR5
* @arg @ref LL_TIM_DMABURST_BASEADDR_CCR6
* @arg @ref LL_TIM_DMABURST_BASEADDR_DTR2
* @arg @ref LL_TIM_DMABURST_BASEADDR_ECR
* @arg @ref LL_TIM_DMABURST_BASEADDR_TISEL
* @arg @ref LL_TIM_DMABURST_BASEADDR_AF1
* @arg @ref LL_TIM_DMABURST_BASEADDR_AF2
* @arg @ref LL_TIM_DMABURST_BASEADDR_OR
* @param DMABurstLength This parameter can be one of the following values:
* @arg @ref LL_TIM_DMABURST_LENGTH_1TRANSFER
* @arg @ref LL_TIM_DMABURST_LENGTH_2TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_3TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_4TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_5TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_6TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_7TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_8TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_9TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_10TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_11TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_12TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_13TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_14TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_15TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_16TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_17TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_18TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_19TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_20TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_21TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_22TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_23TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_24TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_25TRANSFERS
* @arg @ref LL_TIM_DMABURST_LENGTH_26TRANSFERS
* @retval None
*/
__STATIC_INLINE void LL_TIM_ConfigDMABurst(TIM_TypeDef *TIMx, uint32_t DMABurstBaseAddress, uint32_t DMABurstLength)
{
MODIFY_REG(TIMx->DCR, (TIM_DCR_DBL | TIM_DCR_DBA), (DMABurstBaseAddress | DMABurstLength));
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Encoder Encoder configuration
* @{
*/
/**
* @brief Enable encoder index.
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IE LL_TIM_EnableEncoderIndex
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableEncoderIndex(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->ECR, TIM_ECR_IE);
}
/**
* @brief Disable encoder index.
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IE LL_TIM_DisableEncoderIndex
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableEncoderIndex(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->ECR, TIM_ECR_IE);
}
/**
* @brief Indicate whether encoder index is enabled.
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IE LL_TIM_IsEnabledEncoderIndex
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledEncoderIndex(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->ECR, TIM_ECR_IE) == (TIM_ECR_IE)) ? 1U : 0U);
}
/**
* @brief Set index direction
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IDIR LL_TIM_SetIndexDirection
* @param TIMx Timer instance
* @param IndexDirection This parameter can be one of the following values:
* @arg @ref LL_TIM_INDEX_UP_DOWN
* @arg @ref LL_TIM_INDEX_UP
* @arg @ref LL_TIM_INDEX_DOWN
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetIndexDirection(TIM_TypeDef *TIMx, uint32_t IndexDirection)
{
MODIFY_REG(TIMx->ECR, TIM_ECR_IDIR, IndexDirection);
}
/**
* @brief Get actual index direction
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IDIR LL_TIM_GetIndexDirection
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_INDEX_UP_DOWN
* @arg @ref LL_TIM_INDEX_UP
* @arg @ref LL_TIM_INDEX_DOWN
*/
__STATIC_INLINE uint32_t LL_TIM_GetIndexDirection(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->ECR, TIM_ECR_IDIR));
}
/**
* @brief Enable first index.
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR FIDX LL_TIM_EnableFirstIndex
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableFirstIndex(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->ECR, TIM_ECR_FIDX);
}
/**
* @brief Disable first index.
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR FIDX LL_TIM_DisableFirstIndex
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableFirstIndex(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->ECR, TIM_ECR_FIDX);
}
/**
* @brief Indicates whether first index is enabled.
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR FIDX LL_TIM_IsEnabledFirstIndex
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledFirstIndex(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->ECR, TIM_ECR_FIDX) == (TIM_ECR_FIDX)) ? 1UL : 0UL);
}
/**
* @brief Set index positioning
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IPOS LL_TIM_SetIndexPositionning
* @param TIMx Timer instance
* @param IndexPositionning This parameter can be one of the following values:
* @arg @ref LL_TIM_INDEX_POSITION_DOWN_DOWN
* @arg @ref LL_TIM_INDEX_POSITION_DOWN_UP
* @arg @ref LL_TIM_INDEX_POSITION_UP_DOWN
* @arg @ref LL_TIM_INDEX_POSITION_UP_UP
* @arg @ref LL_TIM_INDEX_POSITION_DOWN
* @arg @ref LL_TIM_INDEX_POSITION_UP
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetIndexPositionning(TIM_TypeDef *TIMx, uint32_t IndexPositionning)
{
MODIFY_REG(TIMx->ECR, TIM_ECR_IPOS, IndexPositionning);
}
/**
* @brief Get actual index positioning
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IPOS LL_TIM_GetIndexPositionning
* @param TIMx Timer instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_TIM_INDEX_POSITION_DOWN_DOWN
* @arg @ref LL_TIM_INDEX_POSITION_DOWN_UP
* @arg @ref LL_TIM_INDEX_POSITION_UP_DOWN
* @arg @ref LL_TIM_INDEX_POSITION_UP_UP
* @arg @ref LL_TIM_INDEX_POSITION_DOWN
* @arg @ref LL_TIM_INDEX_POSITION_UP
*/
__STATIC_INLINE uint32_t LL_TIM_GetIndexPositionning(const TIM_TypeDef *TIMx)
{
return (uint32_t)(READ_BIT(TIMx->ECR, TIM_ECR_IPOS));
}
/**
* @brief Configure encoder index.
* @note Macro IS_TIM_INDEX_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides an index input.
* @rmtoll ECR IDIR LL_TIM_ConfigIDX\n
* ECR FIDX LL_TIM_ConfigIDX\n
* ECR IPOS LL_TIM_ConfigIDX
* @param TIMx Timer instance
* @param Configuration This parameter must be a combination of all the following values:
* @arg @ref LL_TIM_INDEX_UP or @ref LL_TIM_INDEX_DOWN or @ref LL_TIM_INDEX_UP_DOWN
* @arg @ref LL_TIM_INDEX_ALL or @ref LL_TIM_INDEX_FIRST_ONLY
* @arg @ref LL_TIM_INDEX_POSITION_DOWN_DOWN or ... or @ref LL_TIM_INDEX_POSITION_UP
* @retval None
*/
__STATIC_INLINE void LL_TIM_ConfigIDX(TIM_TypeDef *TIMx, uint32_t Configuration)
{
MODIFY_REG(TIMx->ECR, TIM_ECR_IDIR | TIM_ECR_FIDX | TIM_ECR_IPOS, Configuration);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_Timer_Inputs_Remapping Timer input remapping
* @{
*/
/**
* @brief Remap TIM inputs (input channel, internal/external triggers).
* @note Macro IS_TIM_REMAP_INSTANCE(TIMx) can be used to check whether or not
* a some timer inputs can be remapped.
* @rmtoll TIM1_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM2_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM2_TISEL TI2SEL LL_TIM_SetRemap\n
* TIM2_TISEL TI3SEL LL_TIM_SetRemap\n
* TIM2_TISEL TI4SEL LL_TIM_SetRemap\n
* TIM3_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM3_TISEL TI2SEL LL_TIM_SetRemap\n
* TIM3_TISEL TI3SEL LL_TIM_SetRemap\n
* TIM4_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM4_TISEL TI2SEL LL_TIM_SetRemap\n
* TIM4_TISEL TI3SEL LL_TIM_SetRemap\n
* TIM4_TISEL TI4SEL LL_TIM_SetRemap\n
* TIM5_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM5_TISEL TI2SEL LL_TIM_SetRemap\n
* TIM8_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM15_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM15_TISEL TI2SEL LL_TIM_SetRemap\n
* TIM16_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM17_TISEL TI1SEL LL_TIM_SetRemap\n
* TIM20_TISEL TI1SEL LL_TIM_SetRemap
* @param TIMx Timer instance
* @param Remap Remap param depends on the TIMx. Description available only
* in CHM version of the User Manual (not in .pdf).
* Otherwise see Reference Manual description of TISEL registers.
*
* Below description summarizes "Timer Instance" and "Remap" param combinations:
*
* TIM1: one of the following values
*
* @arg @ref LL_TIM_TIM1_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM1_TI1_RMP_COMP1
* @arg @ref LL_TIM_TIM1_TI1_RMP_COMP2
* @arg @ref LL_TIM_TIM1_TI1_RMP_COMP3
* @arg @ref LL_TIM_TIM1_TI1_RMP_COMP4
*
* TIM2: any combination of TI1_RMP, TI2_RMP, TI3_RMP and TI4_RMP where
*
* . . TI1_RMP can be one of the following values
* @arg @ref LL_TIM_TIM2_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM2_TI1_RMP_COMP1
* @arg @ref LL_TIM_TIM2_TI1_RMP_COMP2
* @arg @ref LL_TIM_TIM2_TI1_RMP_COMP3
* @arg @ref LL_TIM_TIM2_TI1_RMP_COMP4
* @arg @ref LL_TIM_TIM2_TI1_RMP_COMP5 (*)
*
* . . TI2_RMP can be one of the following values
* @arg @ref LL_TIM_TIM2_TI2_RMP_GPIO
* @arg @ref LL_TIM_TIM2_TI2_RMP_COMP1
* @arg @ref LL_TIM_TIM2_TI2_RMP_COMP2
* @arg @ref LL_TIM_TIM2_TI2_RMP_COMP3
* @arg @ref LL_TIM_TIM2_TI2_RMP_COMP4
* @arg @ref LL_TIM_TIM2_TI2_RMP_COMP6 (*)
*
* . . TI3_RMP can be one of the following values
* @arg @ref LL_TIM_TIM2_TI3_RMP_GPIO
* @arg @ref LL_TIM_TIM2_TI3_RMP_COMP4
*
* . . TI4_RMP can be one of the following values
* @arg @ref LL_TIM_TIM2_TI4_RMP_GPIO
* @arg @ref LL_TIM_TIM2_TI4_RMP_COMP1
* @arg @ref LL_TIM_TIM2_TI4_RMP_COMP2
*
* TIM3: any combination of TI1_RMP and TI2_RMP where
*
* . . TI1_RMP can be one of the following values
* @arg @ref LL_TIM_TIM3_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM3_TI1_RMP_COMP1
* @arg @ref LL_TIM_TIM3_TI1_RMP_COMP2
* @arg @ref LL_TIM_TIM3_TI1_RMP_COMP3
* @arg @ref LL_TIM_TIM3_TI1_RMP_COMP4
* @arg @ref LL_TIM_TIM3_TI1_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM3_TI1_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM3_TI1_RMP_COMP7 (*)
*
* . . TI2_RMP can be one of the following values
* @arg @ref LL_TIM_TIM3_TI2_RMP_GPIO
* @arg @ref LL_TIM_TIM3_TI2_RMP_COMP1
* @arg @ref LL_TIM_TIM3_TI2_RMP_COMP2
* @arg @ref LL_TIM_TIM3_TI2_RMP_COMP3
* @arg @ref LL_TIM_TIM3_TI2_RMP_COMP4
* @arg @ref LL_TIM_TIM3_TI2_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM3_TI2_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM3_TI2_RMP_COMP7 (*)
*
* . . TI3_RMP can be one of the following values
* @arg @ref LL_TIM_TIM3_TI3_RMP_GPIO
* @arg @ref LL_TIM_TIM3_TI3_RMP_COMP3
*
* TIM4: any combination of TI1_RMP, TI2_RMP, TI3_RMP and TI4_RMP where
*
* . . TI1_RMP can be one of the following values
* @arg @ref LL_TIM_TIM4_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM4_TI1_RMP_COMP1
* @arg @ref LL_TIM_TIM4_TI1_RMP_COMP2
* @arg @ref LL_TIM_TIM4_TI1_RMP_COMP3
* @arg @ref LL_TIM_TIM4_TI1_RMP_COMP4
* @arg @ref LL_TIM_TIM4_TI1_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM4_TI1_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM4_TI1_RMP_COMP7 (*)
*
* . . TI2_RMP can be one of the following values
* @arg @ref LL_TIM_TIM4_TI2_RMP_GPIO
* @arg @ref LL_TIM_TIM4_TI2_RMP_COMP1
* @arg @ref LL_TIM_TIM4_TI2_RMP_COMP2
* @arg @ref LL_TIM_TIM4_TI2_RMP_COMP3
* @arg @ref LL_TIM_TIM4_TI2_RMP_COMP4
* @arg @ref LL_TIM_TIM4_TI2_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM4_TI2_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM4_TI2_RMP_COMP7 (*)
*
* . . TI3_RMP can be one of the following values
* @arg @ref LL_TIM_TIM4_TI3_RMP_GPIO
* @arg @ref LL_TIM_TIM4_TI3_RMP_COMP5 (*)
*
* . . TI4_RMP can be one of the following values
* @arg @ref LL_TIM_TIM4_TI4_RMP_GPIO
* @arg @ref LL_TIM_TIM4_TI4_RMP_COMP6 (*)
*
* TIM5: any combination of TI1_RMP and TI2_RMP where (**)
*
* . . TI1_RMP can be one of the following values
* @arg @ref LL_TIM_TIM5_TI1_RMP_GPIO (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_LSI (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_LSE (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_RTC_WK (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_COMP1 (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_COMP2 (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_COMP3 (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_COMP4 (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM5_TI1_RMP_COMP7 (*)
*
* . . TI2_RMP can be one of the following values
* @arg @ref LL_TIM_TIM5_TI2_RMP_GPIO (*)
* @arg @ref LL_TIM_TIM5_TI2_RMP_COMP1 (*)
* @arg @ref LL_TIM_TIM5_TI2_RMP_COMP2 (*)
* @arg @ref LL_TIM_TIM5_TI2_RMP_COMP3 (*)
* @arg @ref LL_TIM_TIM5_TI2_RMP_COMP4 (*)
* @arg @ref LL_TIM_TIM5_TI2_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM5_TI2_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM5_TI2_RMP_COMP7 (*)
*
* TIM8: one of the following values
*
* @arg @ref LL_TIM_TIM8_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM8_TI1_RMP_COMP1
* @arg @ref LL_TIM_TIM8_TI1_RMP_COMP2
* @arg @ref LL_TIM_TIM8_TI1_RMP_COMP3
* @arg @ref LL_TIM_TIM8_TI1_RMP_COMP4
*
* TIM15: any combination of TI1_RMP and TI2_RMP where
*
* . . TI1_RMP can be one of the following values
* @arg @ref LL_TIM_TIM15_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM15_TI1_RMP_LSE
* @arg @ref LL_TIM_TIM15_TI1_RMP_COMP1
* @arg @ref LL_TIM_TIM15_TI1_RMP_COMP2
* @arg @ref LL_TIM_TIM15_TI1_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM15_TI1_RMP_COMP7 (*)
*
* . . TI2_RMP can be one of the following values
* @arg @ref LL_TIM_TIM15_TI2_RMP_GPIO
* @arg @ref LL_TIM_TIM15_TI2_RMP_COMP2
* @arg @ref LL_TIM_TIM15_TI2_RMP_COMP3
* @arg @ref LL_TIM_TIM15_TI2_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM15_TI2_RMP_COMP7 (*)
*
* TIM16: one of the following values
*
* @arg @ref LL_TIM_TIM16_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM16_TI1_RMP_COMP6 (*)
* @arg @ref LL_TIM_TIM16_TI1_RMP_MCO
* @arg @ref LL_TIM_TIM16_TI1_RMP_HSE_32
* @arg @ref LL_TIM_TIM16_TI1_RMP_RTC_WK
* @arg @ref LL_TIM_TIM16_TI1_RMP_LSE
* @arg @ref LL_TIM_TIM16_TI1_RMP_LSI
*
* TIM17: one of the following values
*
* @arg @ref LL_TIM_TIM17_TI1_RMP_GPIO
* @arg @ref LL_TIM_TIM17_TI1_RMP_COMP5 (*)
* @arg @ref LL_TIM_TIM17_TI1_RMP_MCO
* @arg @ref LL_TIM_TIM17_TI1_RMP_HSE_32
* @arg @ref LL_TIM_TIM17_TI1_RMP_RTC_WK
* @arg @ref LL_TIM_TIM17_TI1_RMP_LSE
* @arg @ref LL_TIM_TIM17_TI1_RMP_LSI
*
* TIM20: one of the following values (**)
*
* @arg @ref LL_TIM_TIM20_TI1_RMP_GPIO (*)
* @arg @ref LL_TIM_TIM20_TI1_RMP_COMP1 (*)
* @arg @ref LL_TIM_TIM20_TI1_RMP_COMP2 (*)
* @arg @ref LL_TIM_TIM20_TI1_RMP_COMP3 (*)
* @arg @ref LL_TIM_TIM20_TI1_RMP_COMP4 (*)
*
* (*) Value not defined in all devices. \n
* (**) Register not available in all devices.
*
*
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetRemap(TIM_TypeDef *TIMx, uint32_t Remap)
{
MODIFY_REG(TIMx->TISEL, (TIM_TISEL_TI1SEL | TIM_TISEL_TI2SEL | TIM_TISEL_TI3SEL | TIM_TISEL_TI4SEL), Remap);
}
/**
* @brief Enable request for HSE/32 clock used for TISEL remap.
* @note Only TIM16 and TIM17 support HSE/32 remap
* @rmtoll OR HSE32EN LL_TIM_EnableHSE32
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableHSE32(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->OR, TIM_OR_HSE32EN);
}
/**
* @brief Disable request for HSE/32 clock used for TISEL remap.
* @note Only TIM16 and TIM17 support HSE/32 remap
* @rmtoll OR HSE32EN LL_TIM_DisableHSE32
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableHSE32(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->OR, TIM_OR_HSE32EN);
}
/**
* @brief Indicate whether request for HSE/32 clock is enabled.
* @note Only TIM16 and TIM17 support HSE/32 remap
* @rmtoll OR HSE32EN LL_TIM_IsEnabledHSE32
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledHSE32(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->OR, TIM_OR_HSE32EN) == (TIM_OR_HSE32EN)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_OCREF_Clear OCREF_Clear_Management
* @{
*/
/**
* @brief Set the OCREF clear input source
* @note The OCxREF signal of a given channel can be cleared when a high level is applied on the OCREF_CLR_INPUT
* @note This function can only be used in Output compare and PWM modes.
* @note Macro IS_TIM_OCCS_INSTANCE(TIMx) can be used to check whether
* or not a timer instance can configure OCREF clear input source.
* @rmtoll SMCR OCCS LL_TIM_SetOCRefClearInputSource
* @rmtoll AF2 OCRSEL LL_TIM_SetOCRefClearInputSource
* @param TIMx Timer instance
* @param OCRefClearInputSource This parameter can be one of the following values:
* @arg @ref LL_TIM_OCREF_CLR_INT_ETR
* @arg @ref LL_TIM_OCREF_CLR_INT_COMP1
* @arg @ref LL_TIM_OCREF_CLR_INT_COMP2
* @arg @ref LL_TIM_OCREF_CLR_INT_COMP3
* @arg @ref LL_TIM_OCREF_CLR_INT_COMP4
* @arg @ref LL_TIM_OCREF_CLR_INT_COMP5 (*)
* @arg @ref LL_TIM_OCREF_CLR_INT_COMP6 (*)
* @arg @ref LL_TIM_OCREF_CLR_INT_COMP7 (*)
*
* (*) Value not defined in all devices. \n
* @retval None
*/
__STATIC_INLINE void LL_TIM_SetOCRefClearInputSource(TIM_TypeDef *TIMx, uint32_t OCRefClearInputSource)
{
MODIFY_REG(TIMx->SMCR, TIM_SMCR_OCCS,
((OCRefClearInputSource & OCREF_CLEAR_SELECT_Msk) >> OCREF_CLEAR_SELECT_Pos) << TIM_SMCR_OCCS_Pos);
MODIFY_REG(TIMx->AF2, TIM1_AF2_OCRSEL, OCRefClearInputSource);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_FLAG_Management FLAG-Management
* @{
*/
/**
* @brief Clear the update interrupt flag (UIF).
* @rmtoll SR UIF LL_TIM_ClearFlag_UPDATE
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_UPDATE(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_UIF));
}
/**
* @brief Indicate whether update interrupt flag (UIF) is set (update interrupt is pending).
* @rmtoll SR UIF LL_TIM_IsActiveFlag_UPDATE
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_UPDATE(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_UIF) == (TIM_SR_UIF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 1 interrupt flag (CC1F).
* @rmtoll SR CC1IF LL_TIM_ClearFlag_CC1
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC1(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC1IF));
}
/**
* @brief Indicate whether Capture/Compare 1 interrupt flag (CC1F) is set (Capture/Compare 1 interrupt is pending).
* @rmtoll SR CC1IF LL_TIM_IsActiveFlag_CC1
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC1(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC1IF) == (TIM_SR_CC1IF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 2 interrupt flag (CC2F).
* @rmtoll SR CC2IF LL_TIM_ClearFlag_CC2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC2(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC2IF));
}
/**
* @brief Indicate whether Capture/Compare 2 interrupt flag (CC2F) is set (Capture/Compare 2 interrupt is pending).
* @rmtoll SR CC2IF LL_TIM_IsActiveFlag_CC2
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC2(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC2IF) == (TIM_SR_CC2IF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 3 interrupt flag (CC3F).
* @rmtoll SR CC3IF LL_TIM_ClearFlag_CC3
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC3(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC3IF));
}
/**
* @brief Indicate whether Capture/Compare 3 interrupt flag (CC3F) is set (Capture/Compare 3 interrupt is pending).
* @rmtoll SR CC3IF LL_TIM_IsActiveFlag_CC3
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC3(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC3IF) == (TIM_SR_CC3IF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 4 interrupt flag (CC4F).
* @rmtoll SR CC4IF LL_TIM_ClearFlag_CC4
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC4(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC4IF));
}
/**
* @brief Indicate whether Capture/Compare 4 interrupt flag (CC4F) is set (Capture/Compare 4 interrupt is pending).
* @rmtoll SR CC4IF LL_TIM_IsActiveFlag_CC4
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC4(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC4IF) == (TIM_SR_CC4IF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 5 interrupt flag (CC5F).
* @rmtoll SR CC5IF LL_TIM_ClearFlag_CC5
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC5(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC5IF));
}
/**
* @brief Indicate whether Capture/Compare 5 interrupt flag (CC5F) is set (Capture/Compare 5 interrupt is pending).
* @rmtoll SR CC5IF LL_TIM_IsActiveFlag_CC5
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC5(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC5IF) == (TIM_SR_CC5IF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 6 interrupt flag (CC6F).
* @rmtoll SR CC6IF LL_TIM_ClearFlag_CC6
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC6(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC6IF));
}
/**
* @brief Indicate whether Capture/Compare 6 interrupt flag (CC6F) is set (Capture/Compare 6 interrupt is pending).
* @rmtoll SR CC6IF LL_TIM_IsActiveFlag_CC6
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC6(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC6IF) == (TIM_SR_CC6IF)) ? 1UL : 0UL);
}
/**
* @brief Clear the commutation interrupt flag (COMIF).
* @rmtoll SR COMIF LL_TIM_ClearFlag_COM
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_COM(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_COMIF));
}
/**
* @brief Indicate whether commutation interrupt flag (COMIF) is set (commutation interrupt is pending).
* @rmtoll SR COMIF LL_TIM_IsActiveFlag_COM
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_COM(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_COMIF) == (TIM_SR_COMIF)) ? 1UL : 0UL);
}
/**
* @brief Clear the trigger interrupt flag (TIF).
* @rmtoll SR TIF LL_TIM_ClearFlag_TRIG
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_TRIG(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_TIF));
}
/**
* @brief Indicate whether trigger interrupt flag (TIF) is set (trigger interrupt is pending).
* @rmtoll SR TIF LL_TIM_IsActiveFlag_TRIG
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_TRIG(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_TIF) == (TIM_SR_TIF)) ? 1UL : 0UL);
}
/**
* @brief Clear the break interrupt flag (BIF).
* @rmtoll SR BIF LL_TIM_ClearFlag_BRK
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_BRK(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_BIF));
}
/**
* @brief Indicate whether break interrupt flag (BIF) is set (break interrupt is pending).
* @rmtoll SR BIF LL_TIM_IsActiveFlag_BRK
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_BRK(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_BIF) == (TIM_SR_BIF)) ? 1UL : 0UL);
}
/**
* @brief Clear the break 2 interrupt flag (B2IF).
* @rmtoll SR B2IF LL_TIM_ClearFlag_BRK2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_BRK2(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_B2IF));
}
/**
* @brief Indicate whether break 2 interrupt flag (B2IF) is set (break 2 interrupt is pending).
* @rmtoll SR B2IF LL_TIM_IsActiveFlag_BRK2
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_BRK2(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_B2IF) == (TIM_SR_B2IF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 1 over-capture interrupt flag (CC1OF).
* @rmtoll SR CC1OF LL_TIM_ClearFlag_CC1OVR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC1OVR(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC1OF));
}
/**
* @brief Indicate whether Capture/Compare 1 over-capture interrupt flag (CC1OF) is set
* (Capture/Compare 1 interrupt is pending).
* @rmtoll SR CC1OF LL_TIM_IsActiveFlag_CC1OVR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC1OVR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC1OF) == (TIM_SR_CC1OF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 2 over-capture interrupt flag (CC2OF).
* @rmtoll SR CC2OF LL_TIM_ClearFlag_CC2OVR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC2OVR(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC2OF));
}
/**
* @brief Indicate whether Capture/Compare 2 over-capture interrupt flag (CC2OF) is set
* (Capture/Compare 2 over-capture interrupt is pending).
* @rmtoll SR CC2OF LL_TIM_IsActiveFlag_CC2OVR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC2OVR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC2OF) == (TIM_SR_CC2OF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 3 over-capture interrupt flag (CC3OF).
* @rmtoll SR CC3OF LL_TIM_ClearFlag_CC3OVR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC3OVR(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC3OF));
}
/**
* @brief Indicate whether Capture/Compare 3 over-capture interrupt flag (CC3OF) is set
* (Capture/Compare 3 over-capture interrupt is pending).
* @rmtoll SR CC3OF LL_TIM_IsActiveFlag_CC3OVR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC3OVR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC3OF) == (TIM_SR_CC3OF)) ? 1UL : 0UL);
}
/**
* @brief Clear the Capture/Compare 4 over-capture interrupt flag (CC4OF).
* @rmtoll SR CC4OF LL_TIM_ClearFlag_CC4OVR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_CC4OVR(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_CC4OF));
}
/**
* @brief Indicate whether Capture/Compare 4 over-capture interrupt flag (CC4OF) is set
* (Capture/Compare 4 over-capture interrupt is pending).
* @rmtoll SR CC4OF LL_TIM_IsActiveFlag_CC4OVR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_CC4OVR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_CC4OF) == (TIM_SR_CC4OF)) ? 1UL : 0UL);
}
/**
* @brief Clear the system break interrupt flag (SBIF).
* @rmtoll SR SBIF LL_TIM_ClearFlag_SYSBRK
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_SYSBRK(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_SBIF));
}
/**
* @brief Indicate whether system break interrupt flag (SBIF) is set (system break interrupt is pending).
* @rmtoll SR SBIF LL_TIM_IsActiveFlag_SYSBRK
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_SYSBRK(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_SBIF) == (TIM_SR_SBIF)) ? 1UL : 0UL);
}
/**
* @brief Clear the transition error interrupt flag (TERRF).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll SR TERRF LL_TIM_ClearFlag_TERR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_TERR(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_TERRF));
}
/**
* @brief Indicate whether transition error interrupt flag (TERRF) is set (transition error interrupt is pending).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll SR TERRF LL_TIM_IsActiveFlag_TERR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_TERR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_TERRF) == (TIM_SR_TERRF)) ? 1UL : 0UL);
}
/**
* @brief Clear the index error interrupt flag (IERRF).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll SR IERRF LL_TIM_ClearFlag_IERR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_IERR(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_IERRF));
}
/**
* @brief Indicate whether index error interrupt flag (IERRF) is set (index error interrupt is pending).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll SR IERRF LL_TIM_IsActiveFlag_IERR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_IERR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_IERRF) == (TIM_SR_IERRF)) ? 1UL : 0UL);
}
/**
* @brief Clear the direction change interrupt flag (DIRF).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll SR DIRF LL_TIM_ClearFlag_DIR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_DIR(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_DIRF));
}
/**
* @brief Indicate whether direction change interrupt flag (DIRF) is set (direction change interrupt is pending).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll SR DIRF LL_TIM_IsActiveFlag_DIR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_DIR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_DIRF) == (TIM_SR_DIRF)) ? 1UL : 0UL);
}
/**
* @brief Clear the index interrupt flag (IDXF).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll SR IDXF LL_TIM_ClearFlag_IDX
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_ClearFlag_IDX(TIM_TypeDef *TIMx)
{
WRITE_REG(TIMx->SR, ~(TIM_SR_IDXF));
}
/**
* @brief Indicate whether index interrupt flag (IDXF) is set (index interrupt is pending).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll SR IDXF LL_TIM_IsActiveFlag_IDX
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsActiveFlag_IDX(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->SR, TIM_SR_IDXF) == (TIM_SR_IDXF)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_IT_Management IT-Management
* @{
*/
/**
* @brief Enable update interrupt (UIE).
* @rmtoll DIER UIE LL_TIM_EnableIT_UPDATE
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_UPDATE(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_UIE);
}
/**
* @brief Disable update interrupt (UIE).
* @rmtoll DIER UIE LL_TIM_DisableIT_UPDATE
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_UPDATE(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_UIE);
}
/**
* @brief Indicates whether the update interrupt (UIE) is enabled.
* @rmtoll DIER UIE LL_TIM_IsEnabledIT_UPDATE
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_UPDATE(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_UIE) == (TIM_DIER_UIE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 1 interrupt (CC1IE).
* @rmtoll DIER CC1IE LL_TIM_EnableIT_CC1
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_CC1(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC1IE);
}
/**
* @brief Disable capture/compare 1 interrupt (CC1IE).
* @rmtoll DIER CC1IE LL_TIM_DisableIT_CC1
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_CC1(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC1IE);
}
/**
* @brief Indicates whether the capture/compare 1 interrupt (CC1IE) is enabled.
* @rmtoll DIER CC1IE LL_TIM_IsEnabledIT_CC1
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_CC1(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC1IE) == (TIM_DIER_CC1IE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 2 interrupt (CC2IE).
* @rmtoll DIER CC2IE LL_TIM_EnableIT_CC2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_CC2(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC2IE);
}
/**
* @brief Disable capture/compare 2 interrupt (CC2IE).
* @rmtoll DIER CC2IE LL_TIM_DisableIT_CC2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_CC2(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC2IE);
}
/**
* @brief Indicates whether the capture/compare 2 interrupt (CC2IE) is enabled.
* @rmtoll DIER CC2IE LL_TIM_IsEnabledIT_CC2
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_CC2(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC2IE) == (TIM_DIER_CC2IE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 3 interrupt (CC3IE).
* @rmtoll DIER CC3IE LL_TIM_EnableIT_CC3
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_CC3(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC3IE);
}
/**
* @brief Disable capture/compare 3 interrupt (CC3IE).
* @rmtoll DIER CC3IE LL_TIM_DisableIT_CC3
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_CC3(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC3IE);
}
/**
* @brief Indicates whether the capture/compare 3 interrupt (CC3IE) is enabled.
* @rmtoll DIER CC3IE LL_TIM_IsEnabledIT_CC3
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_CC3(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC3IE) == (TIM_DIER_CC3IE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 4 interrupt (CC4IE).
* @rmtoll DIER CC4IE LL_TIM_EnableIT_CC4
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_CC4(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC4IE);
}
/**
* @brief Disable capture/compare 4 interrupt (CC4IE).
* @rmtoll DIER CC4IE LL_TIM_DisableIT_CC4
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_CC4(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC4IE);
}
/**
* @brief Indicates whether the capture/compare 4 interrupt (CC4IE) is enabled.
* @rmtoll DIER CC4IE LL_TIM_IsEnabledIT_CC4
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_CC4(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC4IE) == (TIM_DIER_CC4IE)) ? 1UL : 0UL);
}
/**
* @brief Enable commutation interrupt (COMIE).
* @rmtoll DIER COMIE LL_TIM_EnableIT_COM
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_COM(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_COMIE);
}
/**
* @brief Disable commutation interrupt (COMIE).
* @rmtoll DIER COMIE LL_TIM_DisableIT_COM
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_COM(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_COMIE);
}
/**
* @brief Indicates whether the commutation interrupt (COMIE) is enabled.
* @rmtoll DIER COMIE LL_TIM_IsEnabledIT_COM
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_COM(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_COMIE) == (TIM_DIER_COMIE)) ? 1UL : 0UL);
}
/**
* @brief Enable trigger interrupt (TIE).
* @rmtoll DIER TIE LL_TIM_EnableIT_TRIG
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_TRIG(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_TIE);
}
/**
* @brief Disable trigger interrupt (TIE).
* @rmtoll DIER TIE LL_TIM_DisableIT_TRIG
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_TRIG(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_TIE);
}
/**
* @brief Indicates whether the trigger interrupt (TIE) is enabled.
* @rmtoll DIER TIE LL_TIM_IsEnabledIT_TRIG
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_TRIG(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_TIE) == (TIM_DIER_TIE)) ? 1UL : 0UL);
}
/**
* @brief Enable break interrupt (BIE).
* @rmtoll DIER BIE LL_TIM_EnableIT_BRK
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_BRK(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_BIE);
}
/**
* @brief Disable break interrupt (BIE).
* @rmtoll DIER BIE LL_TIM_DisableIT_BRK
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_BRK(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_BIE);
}
/**
* @brief Indicates whether the break interrupt (BIE) is enabled.
* @rmtoll DIER BIE LL_TIM_IsEnabledIT_BRK
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_BRK(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_BIE) == (TIM_DIER_BIE)) ? 1UL : 0UL);
}
/**
* @brief Enable transition error interrupt (TERRIE).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll DIER TERRIE LL_TIM_EnableIT_TERR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_TERR(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_TERRIE);
}
/**
* @brief Disable transition error interrupt (TERRIE).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll DIER TERRIE LL_TIM_DisableIT_TERR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_TERR(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_TERRIE);
}
/**
* @brief Indicates whether the transition error interrupt (TERRIE) is enabled.
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll DIER TERRIE LL_TIM_IsEnabledIT_TERR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_TERR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_TERRIE) == (TIM_DIER_TERRIE)) ? 1UL : 0UL);
}
/**
* @brief Enable index error interrupt (IERRIE).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll DIER IERRIE LL_TIM_EnableIT_IERR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_IERR(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_IERRIE);
}
/**
* @brief Disable index error interrupt (IERRIE).
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll DIER IERRIE LL_TIM_DisableIT_IERR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_IERR(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_IERRIE);
}
/**
* @brief Indicates whether the index error interrupt (IERRIE) is enabled.
* @note Macro IS_TIM_ENCODER_ERROR_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder error management.
* @rmtoll DIER IERRIE LL_TIM_IsEnabledIT_IERR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_IERR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_IERRIE) == (TIM_DIER_IERRIE)) ? 1UL : 0UL);
}
/**
* @brief Enable direction change interrupt (DIRIE).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll DIER DIRIE LL_TIM_EnableIT_DIR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_DIR(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_DIRIE);
}
/**
* @brief Disable direction change interrupt (DIRIE).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll DIER DIRIE LL_TIM_DisableIT_DIR
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_DIR(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_DIRIE);
}
/**
* @brief Indicates whether the direction change interrupt (DIRIE) is enabled.
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll DIER DIRIE LL_TIM_IsEnabledIT_DIR
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_DIR(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_DIRIE) == (TIM_DIER_DIRIE)) ? 1UL : 0UL);
}
/**
* @brief Enable index interrupt (IDXIE).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll DIER IDXIE LL_TIM_EnableIT_IDX
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableIT_IDX(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_IDXIE);
}
/**
* @brief Disable index interrupt (IDXIE).
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll DIER IDXIE LL_TIM_DisableIT_IDX
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableIT_IDX(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_IDXIE);
}
/**
* @brief Indicates whether the index interrupt (IDXIE) is enabled.
* @note Macro IS_TIM_FUNCTINONAL_ENCODER_INTERRUPT_INSTANCE(TIMx) can be used to check whether or not
* a timer instance provides encoder interrupt management.
* @rmtoll DIER IDXIE LL_TIM_IsEnabledIT_IDX
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledIT_IDX(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_IDXIE) == (TIM_DIER_IDXIE)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_DMA_Management DMA Management
* @{
*/
/**
* @brief Enable update DMA request (UDE).
* @rmtoll DIER UDE LL_TIM_EnableDMAReq_UPDATE
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDMAReq_UPDATE(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_UDE);
}
/**
* @brief Disable update DMA request (UDE).
* @rmtoll DIER UDE LL_TIM_DisableDMAReq_UPDATE
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDMAReq_UPDATE(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_UDE);
}
/**
* @brief Indicates whether the update DMA request (UDE) is enabled.
* @rmtoll DIER UDE LL_TIM_IsEnabledDMAReq_UPDATE
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDMAReq_UPDATE(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_UDE) == (TIM_DIER_UDE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 1 DMA request (CC1DE).
* @rmtoll DIER CC1DE LL_TIM_EnableDMAReq_CC1
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDMAReq_CC1(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC1DE);
}
/**
* @brief Disable capture/compare 1 DMA request (CC1DE).
* @rmtoll DIER CC1DE LL_TIM_DisableDMAReq_CC1
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDMAReq_CC1(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC1DE);
}
/**
* @brief Indicates whether the capture/compare 1 DMA request (CC1DE) is enabled.
* @rmtoll DIER CC1DE LL_TIM_IsEnabledDMAReq_CC1
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDMAReq_CC1(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC1DE) == (TIM_DIER_CC1DE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 2 DMA request (CC2DE).
* @rmtoll DIER CC2DE LL_TIM_EnableDMAReq_CC2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDMAReq_CC2(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC2DE);
}
/**
* @brief Disable capture/compare 2 DMA request (CC2DE).
* @rmtoll DIER CC2DE LL_TIM_DisableDMAReq_CC2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDMAReq_CC2(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC2DE);
}
/**
* @brief Indicates whether the capture/compare 2 DMA request (CC2DE) is enabled.
* @rmtoll DIER CC2DE LL_TIM_IsEnabledDMAReq_CC2
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDMAReq_CC2(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC2DE) == (TIM_DIER_CC2DE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 3 DMA request (CC3DE).
* @rmtoll DIER CC3DE LL_TIM_EnableDMAReq_CC3
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDMAReq_CC3(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC3DE);
}
/**
* @brief Disable capture/compare 3 DMA request (CC3DE).
* @rmtoll DIER CC3DE LL_TIM_DisableDMAReq_CC3
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDMAReq_CC3(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC3DE);
}
/**
* @brief Indicates whether the capture/compare 3 DMA request (CC3DE) is enabled.
* @rmtoll DIER CC3DE LL_TIM_IsEnabledDMAReq_CC3
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDMAReq_CC3(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC3DE) == (TIM_DIER_CC3DE)) ? 1UL : 0UL);
}
/**
* @brief Enable capture/compare 4 DMA request (CC4DE).
* @rmtoll DIER CC4DE LL_TIM_EnableDMAReq_CC4
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDMAReq_CC4(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_CC4DE);
}
/**
* @brief Disable capture/compare 4 DMA request (CC4DE).
* @rmtoll DIER CC4DE LL_TIM_DisableDMAReq_CC4
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDMAReq_CC4(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_CC4DE);
}
/**
* @brief Indicates whether the capture/compare 4 DMA request (CC4DE) is enabled.
* @rmtoll DIER CC4DE LL_TIM_IsEnabledDMAReq_CC4
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDMAReq_CC4(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_CC4DE) == (TIM_DIER_CC4DE)) ? 1UL : 0UL);
}
/**
* @brief Enable commutation DMA request (COMDE).
* @rmtoll DIER COMDE LL_TIM_EnableDMAReq_COM
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDMAReq_COM(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_COMDE);
}
/**
* @brief Disable commutation DMA request (COMDE).
* @rmtoll DIER COMDE LL_TIM_DisableDMAReq_COM
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDMAReq_COM(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_COMDE);
}
/**
* @brief Indicates whether the commutation DMA request (COMDE) is enabled.
* @rmtoll DIER COMDE LL_TIM_IsEnabledDMAReq_COM
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDMAReq_COM(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_COMDE) == (TIM_DIER_COMDE)) ? 1UL : 0UL);
}
/**
* @brief Enable trigger interrupt (TDE).
* @rmtoll DIER TDE LL_TIM_EnableDMAReq_TRIG
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_EnableDMAReq_TRIG(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->DIER, TIM_DIER_TDE);
}
/**
* @brief Disable trigger interrupt (TDE).
* @rmtoll DIER TDE LL_TIM_DisableDMAReq_TRIG
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_DisableDMAReq_TRIG(TIM_TypeDef *TIMx)
{
CLEAR_BIT(TIMx->DIER, TIM_DIER_TDE);
}
/**
* @brief Indicates whether the trigger interrupt (TDE) is enabled.
* @rmtoll DIER TDE LL_TIM_IsEnabledDMAReq_TRIG
* @param TIMx Timer instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_TIM_IsEnabledDMAReq_TRIG(const TIM_TypeDef *TIMx)
{
return ((READ_BIT(TIMx->DIER, TIM_DIER_TDE) == (TIM_DIER_TDE)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup TIM_LL_EF_EVENT_Management EVENT-Management
* @{
*/
/**
* @brief Generate an update event.
* @rmtoll EGR UG LL_TIM_GenerateEvent_UPDATE
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_UPDATE(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_UG);
}
/**
* @brief Generate Capture/Compare 1 event.
* @rmtoll EGR CC1G LL_TIM_GenerateEvent_CC1
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_CC1(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_CC1G);
}
/**
* @brief Generate Capture/Compare 2 event.
* @rmtoll EGR CC2G LL_TIM_GenerateEvent_CC2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_CC2(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_CC2G);
}
/**
* @brief Generate Capture/Compare 3 event.
* @rmtoll EGR CC3G LL_TIM_GenerateEvent_CC3
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_CC3(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_CC3G);
}
/**
* @brief Generate Capture/Compare 4 event.
* @rmtoll EGR CC4G LL_TIM_GenerateEvent_CC4
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_CC4(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_CC4G);
}
/**
* @brief Generate commutation event.
* @rmtoll EGR COMG LL_TIM_GenerateEvent_COM
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_COM(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_COMG);
}
/**
* @brief Generate trigger event.
* @rmtoll EGR TG LL_TIM_GenerateEvent_TRIG
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_TRIG(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_TG);
}
/**
* @brief Generate break event.
* @rmtoll EGR BG LL_TIM_GenerateEvent_BRK
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_BRK(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_BG);
}
/**
* @brief Generate break 2 event.
* @rmtoll EGR B2G LL_TIM_GenerateEvent_BRK2
* @param TIMx Timer instance
* @retval None
*/
__STATIC_INLINE void LL_TIM_GenerateEvent_BRK2(TIM_TypeDef *TIMx)
{
SET_BIT(TIMx->EGR, TIM_EGR_B2G);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup TIM_LL_EF_Init Initialisation and deinitialisation functions
* @{
*/
ErrorStatus LL_TIM_DeInit(const TIM_TypeDef *TIMx);
void LL_TIM_StructInit(LL_TIM_InitTypeDef *TIM_InitStruct);
ErrorStatus LL_TIM_Init(TIM_TypeDef *TIMx, const LL_TIM_InitTypeDef *TIM_InitStruct);
void LL_TIM_OC_StructInit(LL_TIM_OC_InitTypeDef *TIM_OC_InitStruct);
ErrorStatus LL_TIM_OC_Init(TIM_TypeDef *TIMx, uint32_t Channel, const LL_TIM_OC_InitTypeDef *TIM_OC_InitStruct);
void LL_TIM_IC_StructInit(LL_TIM_IC_InitTypeDef *TIM_ICInitStruct);
ErrorStatus LL_TIM_IC_Init(TIM_TypeDef *TIMx, uint32_t Channel, const LL_TIM_IC_InitTypeDef *TIM_IC_InitStruct);
void LL_TIM_ENCODER_StructInit(LL_TIM_ENCODER_InitTypeDef *TIM_EncoderInitStruct);
ErrorStatus LL_TIM_ENCODER_Init(TIM_TypeDef *TIMx, const LL_TIM_ENCODER_InitTypeDef *TIM_EncoderInitStruct);
void LL_TIM_HALLSENSOR_StructInit(LL_TIM_HALLSENSOR_InitTypeDef *TIM_HallSensorInitStruct);
ErrorStatus LL_TIM_HALLSENSOR_Init(TIM_TypeDef *TIMx, const LL_TIM_HALLSENSOR_InitTypeDef *TIM_HallSensorInitStruct);
void LL_TIM_BDTR_StructInit(LL_TIM_BDTR_InitTypeDef *TIM_BDTRInitStruct);
ErrorStatus LL_TIM_BDTR_Init(TIM_TypeDef *TIMx, const LL_TIM_BDTR_InitTypeDef *TIM_BDTRInitStruct);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* TIM1 || TIM2 || TIM3 || TIM4 || TIM5 || TIM6 || TIM7 || TIM8 || TIM15 || TIM16 || TIM17 || TIM20 */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_LL_TIM_H */
| 309,100 | C | 44.962974 | 274 | 0.595846 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_crc.h | /**
******************************************************************************
* @file stm32g4xx_hal_crc.h
* @author MCD Application Team
* @brief Header file of CRC HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_CRC_H
#define STM32G4xx_HAL_CRC_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup CRC
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup CRC_Exported_Types CRC Exported Types
* @{
*/
/**
* @brief CRC HAL State Structure definition
*/
typedef enum
{
HAL_CRC_STATE_RESET = 0x00U, /*!< CRC not yet initialized or disabled */
HAL_CRC_STATE_READY = 0x01U, /*!< CRC initialized and ready for use */
HAL_CRC_STATE_BUSY = 0x02U, /*!< CRC internal process is ongoing */
HAL_CRC_STATE_TIMEOUT = 0x03U, /*!< CRC timeout state */
HAL_CRC_STATE_ERROR = 0x04U /*!< CRC error state */
} HAL_CRC_StateTypeDef;
/**
* @brief CRC Init Structure definition
*/
typedef struct
{
uint8_t DefaultPolynomialUse; /*!< This parameter is a value of @ref CRC_Default_Polynomial and indicates if default polynomial is used.
If set to DEFAULT_POLYNOMIAL_ENABLE, resort to default
X^32 + X^26 + X^23 + X^22 + X^16 + X^12 + X^11 + X^10 +X^8 + X^7 + X^5 +
X^4 + X^2+ X +1.
In that case, there is no need to set GeneratingPolynomial field.
If otherwise set to DEFAULT_POLYNOMIAL_DISABLE, GeneratingPolynomial and
CRCLength fields must be set. */
uint8_t DefaultInitValueUse; /*!< This parameter is a value of @ref CRC_Default_InitValue_Use and indicates if default init value is used.
If set to DEFAULT_INIT_VALUE_ENABLE, resort to default
0xFFFFFFFF value. In that case, there is no need to set InitValue field. If
otherwise set to DEFAULT_INIT_VALUE_DISABLE, InitValue field must be set. */
uint32_t GeneratingPolynomial; /*!< Set CRC generating polynomial as a 7, 8, 16 or 32-bit long value for a polynomial degree
respectively equal to 7, 8, 16 or 32. This field is written in normal,
representation e.g., for a polynomial of degree 7, X^7 + X^6 + X^5 + X^2 + 1
is written 0x65. No need to specify it if DefaultPolynomialUse is set to
DEFAULT_POLYNOMIAL_ENABLE. */
uint32_t CRCLength; /*!< This parameter is a value of @ref CRC_Polynomial_Sizes and indicates CRC length.
Value can be either one of
@arg @ref CRC_POLYLENGTH_32B (32-bit CRC),
@arg @ref CRC_POLYLENGTH_16B (16-bit CRC),
@arg @ref CRC_POLYLENGTH_8B (8-bit CRC),
@arg @ref CRC_POLYLENGTH_7B (7-bit CRC). */
uint32_t InitValue; /*!< Init value to initiate CRC computation. No need to specify it if DefaultInitValueUse
is set to DEFAULT_INIT_VALUE_ENABLE. */
uint32_t InputDataInversionMode; /*!< This parameter is a value of @ref CRCEx_Input_Data_Inversion and specifies input data inversion mode.
Can be either one of the following values
@arg @ref CRC_INPUTDATA_INVERSION_NONE no input data inversion
@arg @ref CRC_INPUTDATA_INVERSION_BYTE byte-wise inversion, 0x1A2B3C4D
becomes 0x58D43CB2
@arg @ref CRC_INPUTDATA_INVERSION_HALFWORD halfword-wise inversion,
0x1A2B3C4D becomes 0xD458B23C
@arg @ref CRC_INPUTDATA_INVERSION_WORD word-wise inversion, 0x1A2B3C4D
becomes 0xB23CD458 */
uint32_t OutputDataInversionMode; /*!< This parameter is a value of @ref CRCEx_Output_Data_Inversion and specifies output data (i.e. CRC) inversion mode.
Can be either
@arg @ref CRC_OUTPUTDATA_INVERSION_DISABLE no CRC inversion,
@arg @ref CRC_OUTPUTDATA_INVERSION_ENABLE CRC 0x11223344 is converted
into 0x22CC4488 */
} CRC_InitTypeDef;
/**
* @brief CRC Handle Structure definition
*/
typedef struct
{
CRC_TypeDef *Instance; /*!< Register base address */
CRC_InitTypeDef Init; /*!< CRC configuration parameters */
HAL_LockTypeDef Lock; /*!< CRC Locking object */
__IO HAL_CRC_StateTypeDef State; /*!< CRC communication state */
uint32_t InputDataFormat; /*!< This parameter is a value of @ref CRC_Input_Buffer_Format and specifies input data format.
Can be either
@arg @ref CRC_INPUTDATA_FORMAT_BYTES input data is a stream of bytes
(8-bit data)
@arg @ref CRC_INPUTDATA_FORMAT_HALFWORDS input data is a stream of
half-words (16-bit data)
@arg @ref CRC_INPUTDATA_FORMAT_WORDS input data is a stream of words
(32-bit data)
Note that constant CRC_INPUT_FORMAT_UNDEFINED is defined but an initialization
error must occur if InputBufferFormat is not one of the three values listed
above */
} CRC_HandleTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup CRC_Exported_Constants CRC Exported Constants
* @{
*/
/** @defgroup CRC_Default_Polynomial_Value Default CRC generating polynomial
* @{
*/
#define DEFAULT_CRC32_POLY 0x04C11DB7U /*!< X^32 + X^26 + X^23 + X^22 + X^16 + X^12 + X^11 + X^10 +X^8 + X^7 + X^5 + X^4 + X^2+ X +1 */
/**
* @}
*/
/** @defgroup CRC_Default_InitValue Default CRC computation initialization value
* @{
*/
#define DEFAULT_CRC_INITVALUE 0xFFFFFFFFU /*!< Initial CRC default value */
/**
* @}
*/
/** @defgroup CRC_Default_Polynomial Indicates whether or not default polynomial is used
* @{
*/
#define DEFAULT_POLYNOMIAL_ENABLE ((uint8_t)0x00U) /*!< Enable default generating polynomial 0x04C11DB7 */
#define DEFAULT_POLYNOMIAL_DISABLE ((uint8_t)0x01U) /*!< Disable default generating polynomial 0x04C11DB7 */
/**
* @}
*/
/** @defgroup CRC_Default_InitValue_Use Indicates whether or not default init value is used
* @{
*/
#define DEFAULT_INIT_VALUE_ENABLE ((uint8_t)0x00U) /*!< Enable initial CRC default value */
#define DEFAULT_INIT_VALUE_DISABLE ((uint8_t)0x01U) /*!< Disable initial CRC default value */
/**
* @}
*/
/** @defgroup CRC_Polynomial_Sizes Polynomial sizes to configure the peripheral
* @{
*/
#define CRC_POLYLENGTH_32B 0x00000000U /*!< Resort to a 32-bit long generating polynomial */
#define CRC_POLYLENGTH_16B CRC_CR_POLYSIZE_0 /*!< Resort to a 16-bit long generating polynomial */
#define CRC_POLYLENGTH_8B CRC_CR_POLYSIZE_1 /*!< Resort to a 8-bit long generating polynomial */
#define CRC_POLYLENGTH_7B CRC_CR_POLYSIZE /*!< Resort to a 7-bit long generating polynomial */
/**
* @}
*/
/** @defgroup CRC_Polynomial_Size_Definitions CRC polynomial possible sizes actual definitions
* @{
*/
#define HAL_CRC_LENGTH_32B 32U /*!< 32-bit long CRC */
#define HAL_CRC_LENGTH_16B 16U /*!< 16-bit long CRC */
#define HAL_CRC_LENGTH_8B 8U /*!< 8-bit long CRC */
#define HAL_CRC_LENGTH_7B 7U /*!< 7-bit long CRC */
/**
* @}
*/
/** @defgroup CRC_Input_Buffer_Format Input Buffer Format
* @{
*/
/* WARNING: CRC_INPUT_FORMAT_UNDEFINED is created for reference purposes but
* an error is triggered in HAL_CRC_Init() if InputDataFormat field is set
* to CRC_INPUT_FORMAT_UNDEFINED: the format MUST be defined by the user for
* the CRC APIs to provide a correct result */
#define CRC_INPUTDATA_FORMAT_UNDEFINED 0x00000000U /*!< Undefined input data format */
#define CRC_INPUTDATA_FORMAT_BYTES 0x00000001U /*!< Input data in byte format */
#define CRC_INPUTDATA_FORMAT_HALFWORDS 0x00000002U /*!< Input data in half-word format */
#define CRC_INPUTDATA_FORMAT_WORDS 0x00000003U /*!< Input data in word format */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup CRC_Exported_Macros CRC Exported Macros
* @{
*/
/** @brief Reset CRC handle state.
* @param __HANDLE__ CRC handle.
* @retval None
*/
#define __HAL_CRC_RESET_HANDLE_STATE(__HANDLE__) ((__HANDLE__)->State = HAL_CRC_STATE_RESET)
/**
* @brief Reset CRC Data Register.
* @param __HANDLE__ CRC handle
* @retval None
*/
#define __HAL_CRC_DR_RESET(__HANDLE__) ((__HANDLE__)->Instance->CR |= CRC_CR_RESET)
/**
* @brief Set CRC INIT non-default value
* @param __HANDLE__ CRC handle
* @param __INIT__ 32-bit initial value
* @retval None
*/
#define __HAL_CRC_INITIALCRCVALUE_CONFIG(__HANDLE__, __INIT__) ((__HANDLE__)->Instance->INIT = (__INIT__))
/**
* @brief Store data in the Independent Data (ID) register.
* @param __HANDLE__ CRC handle
* @param __VALUE__ Value to be stored in the ID register
* @note Refer to the Reference Manual to get the authorized __VALUE__ length in bits
* @retval None
*/
#define __HAL_CRC_SET_IDR(__HANDLE__, __VALUE__) (WRITE_REG((__HANDLE__)->Instance->IDR, (__VALUE__)))
/**
* @brief Return the data stored in the Independent Data (ID) register.
* @param __HANDLE__ CRC handle
* @note Refer to the Reference Manual to get the authorized __VALUE__ length in bits
* @retval Value of the ID register
*/
#define __HAL_CRC_GET_IDR(__HANDLE__) (((__HANDLE__)->Instance->IDR) & CRC_IDR_IDR)
/**
* @}
*/
/* Private macros --------------------------------------------------------*/
/** @defgroup CRC_Private_Macros CRC Private Macros
* @{
*/
#define IS_DEFAULT_POLYNOMIAL(DEFAULT) (((DEFAULT) == DEFAULT_POLYNOMIAL_ENABLE) || \
((DEFAULT) == DEFAULT_POLYNOMIAL_DISABLE))
#define IS_DEFAULT_INIT_VALUE(VALUE) (((VALUE) == DEFAULT_INIT_VALUE_ENABLE) || \
((VALUE) == DEFAULT_INIT_VALUE_DISABLE))
#define IS_CRC_POL_LENGTH(LENGTH) (((LENGTH) == CRC_POLYLENGTH_32B) || \
((LENGTH) == CRC_POLYLENGTH_16B) || \
((LENGTH) == CRC_POLYLENGTH_8B) || \
((LENGTH) == CRC_POLYLENGTH_7B))
#define IS_CRC_INPUTDATA_FORMAT(FORMAT) (((FORMAT) == CRC_INPUTDATA_FORMAT_BYTES) || \
((FORMAT) == CRC_INPUTDATA_FORMAT_HALFWORDS) || \
((FORMAT) == CRC_INPUTDATA_FORMAT_WORDS))
/**
* @}
*/
/* Include CRC HAL Extended module */
#include "stm32g4xx_hal_crc_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @defgroup CRC_Exported_Functions CRC Exported Functions
* @{
*/
/* Initialization and de-initialization functions ****************************/
/** @defgroup CRC_Exported_Functions_Group1 Initialization and de-initialization functions
* @{
*/
HAL_StatusTypeDef HAL_CRC_Init(CRC_HandleTypeDef *hcrc);
HAL_StatusTypeDef HAL_CRC_DeInit(CRC_HandleTypeDef *hcrc);
void HAL_CRC_MspInit(CRC_HandleTypeDef *hcrc);
void HAL_CRC_MspDeInit(CRC_HandleTypeDef *hcrc);
/**
* @}
*/
/* Peripheral Control functions ***********************************************/
/** @defgroup CRC_Exported_Functions_Group2 Peripheral Control functions
* @{
*/
uint32_t HAL_CRC_Accumulate(CRC_HandleTypeDef *hcrc, uint32_t pBuffer[], uint32_t BufferLength);
uint32_t HAL_CRC_Calculate(CRC_HandleTypeDef *hcrc, uint32_t pBuffer[], uint32_t BufferLength);
/**
* @}
*/
/* Peripheral State and Error functions ***************************************/
/** @defgroup CRC_Exported_Functions_Group3 Peripheral State functions
* @{
*/
HAL_CRC_StateTypeDef HAL_CRC_GetState(const CRC_HandleTypeDef *hcrc);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_CRC_H */
| 14,208 | C | 40.425656 | 157 | 0.523719 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_tim.h | /**
******************************************************************************
* @file stm32g4xx_hal_tim.h
* @author MCD Application Team
* @brief Header file of TIM HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_TIM_H
#define STM32G4xx_HAL_TIM_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup TIM
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup TIM_Exported_Types TIM Exported Types
* @{
*/
/**
* @brief TIM Time base Configuration Structure definition
*/
typedef struct
{
uint32_t Prescaler; /*!< Specifies the prescaler value used to divide the TIM clock.
This parameter can be a number between Min_Data = 0x0000 and Max_Data = 0xFFFF
Macro __HAL_TIM_CALC_PSC() can be used to calculate prescaler value */
uint32_t CounterMode; /*!< Specifies the counter mode.
This parameter can be a value of @ref TIM_Counter_Mode */
uint32_t Period; /*!< Specifies the period value to be loaded into the active
Auto-Reload Register at the next update event.
This parameter can be a number between Min_Data = 0x0000 and Max_Data = 0xFFFF
(or 0xFFEF if dithering is activated)Macros __HAL_TIM_CALC_PERIOD(),
__HAL_TIM_CALC_PERIOD_DITHER(),__HAL_TIM_CALC_PERIOD_BY_DELAY(),
__HAL_TIM_CALC_PERIOD_DITHER_BY_DELAY()can be used to calculate Period value */
uint32_t ClockDivision; /*!< Specifies the clock division.
This parameter can be a value of @ref TIM_ClockDivision */
uint32_t RepetitionCounter; /*!< Specifies the repetition counter value. Each time the RCR downcounter
reaches zero, an update event is generated and counting restarts
from the RCR value (N).
This means in PWM mode that (N+1) corresponds to:
- the number of PWM periods in edge-aligned mode
- the number of half PWM period in center-aligned mode
GP timers: this parameter must be a number between Min_Data = 0x00 and
Max_Data = 0xFF.
Advanced timers: this parameter must be a number between Min_Data = 0x0000 and
Max_Data = 0xFFFF. */
uint32_t AutoReloadPreload; /*!< Specifies the auto-reload preload.
This parameter can be a value of @ref TIM_AutoReloadPreload */
} TIM_Base_InitTypeDef;
/**
* @brief TIM Output Compare Configuration Structure definition
*/
typedef struct
{
uint32_t OCMode; /*!< Specifies the TIM mode.
This parameter can be a value of @ref TIM_Output_Compare_and_PWM_modes */
uint32_t Pulse; /*!< Specifies the pulse value to be loaded into the Capture Compare Register.
This parameter can be a number between Min_Data = 0x0000 and Max_Data = 0xFFFF
(or 0xFFEF if dithering is activated)
Macros __HAL_TIM_CALC_PULSE(), __HAL_TIM_CALC_PULSE_DITHER() can be used to calculate
Pulse value */
uint32_t OCPolarity; /*!< Specifies the output polarity.
This parameter can be a value of @ref TIM_Output_Compare_Polarity */
uint32_t OCNPolarity; /*!< Specifies the complementary output polarity.
This parameter can be a value of @ref TIM_Output_Compare_N_Polarity
@note This parameter is valid only for timer instances supporting break feature. */
uint32_t OCFastMode; /*!< Specifies the Fast mode state.
This parameter can be a value of @ref TIM_Output_Fast_State
@note This parameter is valid only in PWM1 and PWM2 mode. */
uint32_t OCIdleState; /*!< Specifies the TIM Output Compare pin state during Idle state.
This parameter can be a value of @ref TIM_Output_Compare_Idle_State
@note This parameter is valid only for timer instances supporting break feature. */
uint32_t OCNIdleState; /*!< Specifies the TIM Output Compare pin state during Idle state.
This parameter can be a value of @ref TIM_Output_Compare_N_Idle_State
@note This parameter is valid only for timer instances supporting break feature. */
} TIM_OC_InitTypeDef;
/**
* @brief TIM One Pulse Mode Configuration Structure definition
*/
typedef struct
{
uint32_t OCMode; /*!< Specifies the TIM mode.
This parameter can be a value of @ref TIM_Output_Compare_and_PWM_modes */
uint32_t Pulse; /*!< Specifies the pulse value to be loaded into the Capture Compare Register.
This parameter can be a number between Min_Data = 0x0000 and Max_Data = 0xFFFF
(or 0xFFEF if dithering is activated)
Macros __HAL_TIM_CALC_PULSE(), __HAL_TIM_CALC_PULSE_DITHER() can be used to calculate
Pulse value */
uint32_t OCPolarity; /*!< Specifies the output polarity.
This parameter can be a value of @ref TIM_Output_Compare_Polarity */
uint32_t OCNPolarity; /*!< Specifies the complementary output polarity.
This parameter can be a value of @ref TIM_Output_Compare_N_Polarity
@note This parameter is valid only for timer instances supporting break feature. */
uint32_t OCIdleState; /*!< Specifies the TIM Output Compare pin state during Idle state.
This parameter can be a value of @ref TIM_Output_Compare_Idle_State
@note This parameter is valid only for timer instances supporting break feature. */
uint32_t OCNIdleState; /*!< Specifies the TIM Output Compare pin state during Idle state.
This parameter can be a value of @ref TIM_Output_Compare_N_Idle_State
@note This parameter is valid only for timer instances supporting break feature. */
uint32_t ICPolarity; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_Input_Capture_Polarity */
uint32_t ICSelection; /*!< Specifies the input.
This parameter can be a value of @ref TIM_Input_Capture_Selection */
uint32_t ICFilter; /*!< Specifies the input capture filter.
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
} TIM_OnePulse_InitTypeDef;
/**
* @brief TIM Input Capture Configuration Structure definition
*/
typedef struct
{
uint32_t ICPolarity; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_Input_Capture_Polarity */
uint32_t ICSelection; /*!< Specifies the input.
This parameter can be a value of @ref TIM_Input_Capture_Selection */
uint32_t ICPrescaler; /*!< Specifies the Input Capture Prescaler.
This parameter can be a value of @ref TIM_Input_Capture_Prescaler */
uint32_t ICFilter; /*!< Specifies the input capture filter.
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
} TIM_IC_InitTypeDef;
/**
* @brief TIM Encoder Configuration Structure definition
*/
typedef struct
{
uint32_t EncoderMode; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_Encoder_Mode */
uint32_t IC1Polarity; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_Encoder_Input_Polarity */
uint32_t IC1Selection; /*!< Specifies the input.
This parameter can be a value of @ref TIM_Input_Capture_Selection */
uint32_t IC1Prescaler; /*!< Specifies the Input Capture Prescaler.
This parameter can be a value of @ref TIM_Input_Capture_Prescaler */
uint32_t IC1Filter; /*!< Specifies the input capture filter.
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
uint32_t IC2Polarity; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_Encoder_Input_Polarity */
uint32_t IC2Selection; /*!< Specifies the input.
This parameter can be a value of @ref TIM_Input_Capture_Selection */
uint32_t IC2Prescaler; /*!< Specifies the Input Capture Prescaler.
This parameter can be a value of @ref TIM_Input_Capture_Prescaler */
uint32_t IC2Filter; /*!< Specifies the input capture filter.
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
} TIM_Encoder_InitTypeDef;
/**
* @brief Clock Configuration Handle Structure definition
*/
typedef struct
{
uint32_t ClockSource; /*!< TIM clock sources
This parameter can be a value of @ref TIM_Clock_Source */
uint32_t ClockPolarity; /*!< TIM clock polarity
This parameter can be a value of @ref TIM_Clock_Polarity */
uint32_t ClockPrescaler; /*!< TIM clock prescaler
This parameter can be a value of @ref TIM_Clock_Prescaler */
uint32_t ClockFilter; /*!< TIM clock filter
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
} TIM_ClockConfigTypeDef;
/**
* @brief TIM Clear Input Configuration Handle Structure definition
*/
typedef struct
{
uint32_t ClearInputState; /*!< TIM clear Input state
This parameter can be ENABLE or DISABLE */
uint32_t ClearInputSource; /*!< TIM clear Input sources
This parameter can be a value of @ref TIM_ClearInput_Source */
uint32_t ClearInputPolarity; /*!< TIM Clear Input polarity
This parameter can be a value of @ref TIM_ClearInput_Polarity */
uint32_t ClearInputPrescaler; /*!< TIM Clear Input prescaler
This parameter must be 0: When OCRef clear feature is used with ETR source,
ETR prescaler must be off */
uint32_t ClearInputFilter; /*!< TIM Clear Input filter
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
} TIM_ClearInputConfigTypeDef;
/**
* @brief TIM Master configuration Structure definition
* @note Advanced timers provide TRGO2 internal line which is redirected
* to the ADC
*/
typedef struct
{
uint32_t MasterOutputTrigger; /*!< Trigger output (TRGO) selection
This parameter can be a value of @ref TIM_Master_Mode_Selection */
uint32_t MasterOutputTrigger2; /*!< Trigger output2 (TRGO2) selection
This parameter can be a value of @ref TIM_Master_Mode_Selection_2 */
uint32_t MasterSlaveMode; /*!< Master/slave mode selection
This parameter can be a value of @ref TIM_Master_Slave_Mode
@note When the Master/slave mode is enabled, the effect of
an event on the trigger input (TRGI) is delayed to allow a
perfect synchronization between the current timer and its
slaves (through TRGO). It is not mandatory in case of timer
synchronization mode. */
} TIM_MasterConfigTypeDef;
/**
* @brief TIM Slave configuration Structure definition
*/
typedef struct
{
uint32_t SlaveMode; /*!< Slave mode selection
This parameter can be a value of @ref TIM_Slave_Mode */
uint32_t InputTrigger; /*!< Input Trigger source
This parameter can be a value of @ref TIM_Trigger_Selection */
uint32_t TriggerPolarity; /*!< Input Trigger polarity
This parameter can be a value of @ref TIM_Trigger_Polarity */
uint32_t TriggerPrescaler; /*!< Input trigger prescaler
This parameter can be a value of @ref TIM_Trigger_Prescaler */
uint32_t TriggerFilter; /*!< Input trigger filter
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
} TIM_SlaveConfigTypeDef;
/**
* @brief TIM Break input(s) and Dead time configuration Structure definition
* @note 2 break inputs can be configured (BKIN and BKIN2) with configurable
* filter and polarity.
*/
typedef struct
{
uint32_t OffStateRunMode; /*!< TIM off state in run mode, This parameter can be a value of @ref TIM_OSSR_Off_State_Selection_for_Run_mode_state */
uint32_t OffStateIDLEMode; /*!< TIM off state in IDLE mode, This parameter can be a value of @ref TIM_OSSI_Off_State_Selection_for_Idle_mode_state */
uint32_t LockLevel; /*!< TIM Lock level, This parameter can be a value of @ref TIM_Lock_level */
uint32_t DeadTime; /*!< TIM dead Time, This parameter can be a number between Min_Data = 0x00 and Max_Data = 0xFF */
uint32_t BreakState; /*!< TIM Break State, This parameter can be a value of @ref TIM_Break_Input_enable_disable */
uint32_t BreakPolarity; /*!< TIM Break input polarity, This parameter can be a value of @ref TIM_Break_Polarity */
uint32_t BreakFilter; /*!< Specifies the break input filter.This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
uint32_t BreakAFMode; /*!< Specifies the alternate function mode of the break input.This parameter can be a value of @ref TIM_Break_Input_AF_Mode */
uint32_t Break2State; /*!< TIM Break2 State, This parameter can be a value of @ref TIM_Break2_Input_enable_disable */
uint32_t Break2Polarity; /*!< TIM Break2 input polarity, This parameter can be a value of @ref TIM_Break2_Polarity */
uint32_t Break2Filter; /*!< TIM break2 input filter.This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
uint32_t Break2AFMode; /*!< Specifies the alternate function mode of the break2 input.This parameter can be a value of @ref TIM_Break2_Input_AF_Mode */
uint32_t AutomaticOutput; /*!< TIM Automatic Output Enable state, This parameter can be a value of @ref TIM_AOE_Bit_Set_Reset */
} TIM_BreakDeadTimeConfigTypeDef;
/**
* @brief HAL State structures definition
*/
typedef enum
{
HAL_TIM_STATE_RESET = 0x00U, /*!< Peripheral not yet initialized or disabled */
HAL_TIM_STATE_READY = 0x01U, /*!< Peripheral Initialized and ready for use */
HAL_TIM_STATE_BUSY = 0x02U, /*!< An internal process is ongoing */
HAL_TIM_STATE_TIMEOUT = 0x03U, /*!< Timeout state */
HAL_TIM_STATE_ERROR = 0x04U /*!< Reception process is ongoing */
} HAL_TIM_StateTypeDef;
/**
* @brief TIM Channel States definition
*/
typedef enum
{
HAL_TIM_CHANNEL_STATE_RESET = 0x00U, /*!< TIM Channel initial state */
HAL_TIM_CHANNEL_STATE_READY = 0x01U, /*!< TIM Channel ready for use */
HAL_TIM_CHANNEL_STATE_BUSY = 0x02U, /*!< An internal process is ongoing on the TIM channel */
} HAL_TIM_ChannelStateTypeDef;
/**
* @brief DMA Burst States definition
*/
typedef enum
{
HAL_DMA_BURST_STATE_RESET = 0x00U, /*!< DMA Burst initial state */
HAL_DMA_BURST_STATE_READY = 0x01U, /*!< DMA Burst ready for use */
HAL_DMA_BURST_STATE_BUSY = 0x02U, /*!< Ongoing DMA Burst */
} HAL_TIM_DMABurstStateTypeDef;
/**
* @brief HAL Active channel structures definition
*/
typedef enum
{
HAL_TIM_ACTIVE_CHANNEL_1 = 0x01U, /*!< The active channel is 1 */
HAL_TIM_ACTIVE_CHANNEL_2 = 0x02U, /*!< The active channel is 2 */
HAL_TIM_ACTIVE_CHANNEL_3 = 0x04U, /*!< The active channel is 3 */
HAL_TIM_ACTIVE_CHANNEL_4 = 0x08U, /*!< The active channel is 4 */
HAL_TIM_ACTIVE_CHANNEL_5 = 0x10U, /*!< The active channel is 5 */
HAL_TIM_ACTIVE_CHANNEL_6 = 0x20U, /*!< The active channel is 6 */
HAL_TIM_ACTIVE_CHANNEL_CLEARED = 0x00U /*!< All active channels cleared */
} HAL_TIM_ActiveChannel;
/**
* @brief TIM Time Base Handle Structure definition
*/
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
typedef struct __TIM_HandleTypeDef
#else
typedef struct
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
{
TIM_TypeDef *Instance; /*!< Register base address */
TIM_Base_InitTypeDef Init; /*!< TIM Time Base required parameters */
HAL_TIM_ActiveChannel Channel; /*!< Active channel */
DMA_HandleTypeDef *hdma[7]; /*!< DMA Handlers array
This array is accessed by a @ref DMA_Handle_index */
HAL_LockTypeDef Lock; /*!< Locking object */
__IO HAL_TIM_StateTypeDef State; /*!< TIM operation state */
__IO HAL_TIM_ChannelStateTypeDef ChannelState[6]; /*!< TIM channel operation state */
__IO HAL_TIM_ChannelStateTypeDef ChannelNState[4]; /*!< TIM complementary channel operation state */
__IO HAL_TIM_DMABurstStateTypeDef DMABurstState; /*!< DMA burst operation state */
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
void (* Base_MspInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Base Msp Init Callback */
void (* Base_MspDeInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Base Msp DeInit Callback */
void (* IC_MspInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM IC Msp Init Callback */
void (* IC_MspDeInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM IC Msp DeInit Callback */
void (* OC_MspInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM OC Msp Init Callback */
void (* OC_MspDeInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM OC Msp DeInit Callback */
void (* PWM_MspInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM PWM Msp Init Callback */
void (* PWM_MspDeInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM PWM Msp DeInit Callback */
void (* OnePulse_MspInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM One Pulse Msp Init Callback */
void (* OnePulse_MspDeInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM One Pulse Msp DeInit Callback */
void (* Encoder_MspInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Encoder Msp Init Callback */
void (* Encoder_MspDeInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Encoder Msp DeInit Callback */
void (* HallSensor_MspInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Hall Sensor Msp Init Callback */
void (* HallSensor_MspDeInitCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Hall Sensor Msp DeInit Callback */
void (* PeriodElapsedCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Period Elapsed Callback */
void (* PeriodElapsedHalfCpltCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Period Elapsed half complete Callback */
void (* TriggerCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Trigger Callback */
void (* TriggerHalfCpltCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Trigger half complete Callback */
void (* IC_CaptureCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Input Capture Callback */
void (* IC_CaptureHalfCpltCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Input Capture half complete Callback */
void (* OC_DelayElapsedCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Output Compare Delay Elapsed Callback */
void (* PWM_PulseFinishedCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM PWM Pulse Finished Callback */
void (* PWM_PulseFinishedHalfCpltCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM PWM Pulse Finished half complete Callback */
void (* ErrorCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Error Callback */
void (* CommutationCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Commutation Callback */
void (* CommutationHalfCpltCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Commutation half complete Callback */
void (* BreakCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Break Callback */
void (* Break2Callback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Break2 Callback */
void (* EncoderIndexCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Encoder Index Callback */
void (* DirectionChangeCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Direction Change Callback */
void (* IndexErrorCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Index Error Callback */
void (* TransitionErrorCallback)(struct __TIM_HandleTypeDef *htim); /*!< TIM Transition Error Callback */
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
} TIM_HandleTypeDef;
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
/**
* @brief HAL TIM Callback ID enumeration definition
*/
typedef enum
{
HAL_TIM_BASE_MSPINIT_CB_ID = 0x00U /*!< TIM Base MspInit Callback ID */
, HAL_TIM_BASE_MSPDEINIT_CB_ID = 0x01U /*!< TIM Base MspDeInit Callback ID */
, HAL_TIM_IC_MSPINIT_CB_ID = 0x02U /*!< TIM IC MspInit Callback ID */
, HAL_TIM_IC_MSPDEINIT_CB_ID = 0x03U /*!< TIM IC MspDeInit Callback ID */
, HAL_TIM_OC_MSPINIT_CB_ID = 0x04U /*!< TIM OC MspInit Callback ID */
, HAL_TIM_OC_MSPDEINIT_CB_ID = 0x05U /*!< TIM OC MspDeInit Callback ID */
, HAL_TIM_PWM_MSPINIT_CB_ID = 0x06U /*!< TIM PWM MspInit Callback ID */
, HAL_TIM_PWM_MSPDEINIT_CB_ID = 0x07U /*!< TIM PWM MspDeInit Callback ID */
, HAL_TIM_ONE_PULSE_MSPINIT_CB_ID = 0x08U /*!< TIM One Pulse MspInit Callback ID */
, HAL_TIM_ONE_PULSE_MSPDEINIT_CB_ID = 0x09U /*!< TIM One Pulse MspDeInit Callback ID */
, HAL_TIM_ENCODER_MSPINIT_CB_ID = 0x0AU /*!< TIM Encoder MspInit Callback ID */
, HAL_TIM_ENCODER_MSPDEINIT_CB_ID = 0x0BU /*!< TIM Encoder MspDeInit Callback ID */
, HAL_TIM_HALL_SENSOR_MSPINIT_CB_ID = 0x0CU /*!< TIM Hall Sensor MspDeInit Callback ID */
, HAL_TIM_HALL_SENSOR_MSPDEINIT_CB_ID = 0x0DU /*!< TIM Hall Sensor MspDeInit Callback ID */
, HAL_TIM_PERIOD_ELAPSED_CB_ID = 0x0EU /*!< TIM Period Elapsed Callback ID */
, HAL_TIM_PERIOD_ELAPSED_HALF_CB_ID = 0x0FU /*!< TIM Period Elapsed half complete Callback ID */
, HAL_TIM_TRIGGER_CB_ID = 0x10U /*!< TIM Trigger Callback ID */
, HAL_TIM_TRIGGER_HALF_CB_ID = 0x11U /*!< TIM Trigger half complete Callback ID */
, HAL_TIM_IC_CAPTURE_CB_ID = 0x12U /*!< TIM Input Capture Callback ID */
, HAL_TIM_IC_CAPTURE_HALF_CB_ID = 0x13U /*!< TIM Input Capture half complete Callback ID */
, HAL_TIM_OC_DELAY_ELAPSED_CB_ID = 0x14U /*!< TIM Output Compare Delay Elapsed Callback ID */
, HAL_TIM_PWM_PULSE_FINISHED_CB_ID = 0x15U /*!< TIM PWM Pulse Finished Callback ID */
, HAL_TIM_PWM_PULSE_FINISHED_HALF_CB_ID = 0x16U /*!< TIM PWM Pulse Finished half complete Callback ID */
, HAL_TIM_ERROR_CB_ID = 0x17U /*!< TIM Error Callback ID */
, HAL_TIM_COMMUTATION_CB_ID = 0x18U /*!< TIM Commutation Callback ID */
, HAL_TIM_COMMUTATION_HALF_CB_ID = 0x19U /*!< TIM Commutation half complete Callback ID */
, HAL_TIM_BREAK_CB_ID = 0x1AU /*!< TIM Break Callback ID */
, HAL_TIM_BREAK2_CB_ID = 0x1BU /*!< TIM Break2 Callback ID */
, HAL_TIM_ENCODER_INDEX_CB_ID = 0x1CU /*!< TIM Encoder Index Callback ID */
, HAL_TIM_DIRECTION_CHANGE_CB_ID = 0x1DU /*!< TIM Direction Change Callback ID */
, HAL_TIM_INDEX_ERROR_CB_ID = 0x1EU /*!< TIM Index Error Callback ID */
, HAL_TIM_TRANSITION_ERROR_CB_ID = 0x1FU /*!< TIM Transition Error Callback ID */
} HAL_TIM_CallbackIDTypeDef;
/**
* @brief HAL TIM Callback pointer definition
*/
typedef void (*pTIM_CallbackTypeDef)(TIM_HandleTypeDef *htim); /*!< pointer to the TIM callback function */
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/**
* @}
*/
/* End of exported types -----------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup TIM_Exported_Constants TIM Exported Constants
* @{
*/
/** @defgroup TIM_ClearInput_Source TIM Clear Input Source
* @{
*/
#define TIM_CLEARINPUTSOURCE_NONE 0xFFFFFFFFU /*!< OCREF_CLR is disabled */
#define TIM_CLEARINPUTSOURCE_ETR 0x00000001U /*!< OCREF_CLR is connected to ETRF input */
#define TIM_CLEARINPUTSOURCE_COMP1 0x00000000U /*!< OCREF_CLR_INT is connected to COMP1 output */
#define TIM_CLEARINPUTSOURCE_COMP2 TIM1_AF2_OCRSEL_0 /*!< OCREF_CLR_INT is connected to COMP2 output */
#define TIM_CLEARINPUTSOURCE_COMP3 TIM1_AF2_OCRSEL_1 /*!< OCREF_CLR_INT is connected to COMP3 output */
#define TIM_CLEARINPUTSOURCE_COMP4 (TIM1_AF2_OCRSEL_1 | TIM1_AF2_OCRSEL_0) /*!< OCREF_CLR_INT is connected to COMP4 output */
#if defined (COMP5)
#define TIM_CLEARINPUTSOURCE_COMP5 TIM1_AF2_OCRSEL_2 /*!< OCREF_CLR_INT is connected to COMP5 output */
#endif /* COMP5 */
#if defined (COMP6)
#define TIM_CLEARINPUTSOURCE_COMP6 (TIM1_AF2_OCRSEL_2 | TIM1_AF2_OCRSEL_0) /*!< OCREF_CLR_INT is connected to COMP6 output */
#endif /* COMP6 */
#if defined (COMP7)
#define TIM_CLEARINPUTSOURCE_COMP7 (TIM1_AF2_OCRSEL_2 | TIM1_AF2_OCRSEL_1) /*!< OCREF_CLR_INT is connected to COMP7 output */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIM_DMA_Base_address TIM DMA Base Address
* @{
*/
#define TIM_DMABASE_CR1 0x00000000U
#define TIM_DMABASE_CR2 0x00000001U
#define TIM_DMABASE_SMCR 0x00000002U
#define TIM_DMABASE_DIER 0x00000003U
#define TIM_DMABASE_SR 0x00000004U
#define TIM_DMABASE_EGR 0x00000005U
#define TIM_DMABASE_CCMR1 0x00000006U
#define TIM_DMABASE_CCMR2 0x00000007U
#define TIM_DMABASE_CCER 0x00000008U
#define TIM_DMABASE_CNT 0x00000009U
#define TIM_DMABASE_PSC 0x0000000AU
#define TIM_DMABASE_ARR 0x0000000BU
#define TIM_DMABASE_RCR 0x0000000CU
#define TIM_DMABASE_CCR1 0x0000000DU
#define TIM_DMABASE_CCR2 0x0000000EU
#define TIM_DMABASE_CCR3 0x0000000FU
#define TIM_DMABASE_CCR4 0x00000010U
#define TIM_DMABASE_BDTR 0x00000011U
#define TIM_DMABASE_CCR5 0x00000012U
#define TIM_DMABASE_CCR6 0x00000013U
#define TIM_DMABASE_CCMR3 0x00000014U
#define TIM_DMABASE_DTR2 0x00000015U
#define TIM_DMABASE_ECR 0x00000016U
#define TIM_DMABASE_TISEL 0x00000017U
#define TIM_DMABASE_AF1 0x00000018U
#define TIM_DMABASE_AF2 0x00000019U
#define TIM_DMABASE_OR 0x0000001AU
/**
* @}
*/
/** @defgroup TIM_Event_Source TIM Event Source
* @{
*/
#define TIM_EVENTSOURCE_UPDATE TIM_EGR_UG /*!< Reinitialize the counter and generates an update of the registers */
#define TIM_EVENTSOURCE_CC1 TIM_EGR_CC1G /*!< A capture/compare event is generated on channel 1 */
#define TIM_EVENTSOURCE_CC2 TIM_EGR_CC2G /*!< A capture/compare event is generated on channel 2 */
#define TIM_EVENTSOURCE_CC3 TIM_EGR_CC3G /*!< A capture/compare event is generated on channel 3 */
#define TIM_EVENTSOURCE_CC4 TIM_EGR_CC4G /*!< A capture/compare event is generated on channel 4 */
#define TIM_EVENTSOURCE_COM TIM_EGR_COMG /*!< A commutation event is generated */
#define TIM_EVENTSOURCE_TRIGGER TIM_EGR_TG /*!< A trigger event is generated */
#define TIM_EVENTSOURCE_BREAK TIM_EGR_BG /*!< A break event is generated */
#define TIM_EVENTSOURCE_BREAK2 TIM_EGR_B2G /*!< A break 2 event is generated */
/**
* @}
*/
/** @defgroup TIM_Input_Channel_Polarity TIM Input Channel polarity
* @{
*/
#define TIM_INPUTCHANNELPOLARITY_RISING 0x00000000U /*!< Polarity for TIx source */
#define TIM_INPUTCHANNELPOLARITY_FALLING TIM_CCER_CC1P /*!< Polarity for TIx source */
#define TIM_INPUTCHANNELPOLARITY_BOTHEDGE (TIM_CCER_CC1P | TIM_CCER_CC1NP) /*!< Polarity for TIx source */
/**
* @}
*/
/** @defgroup TIM_ETR_Polarity TIM ETR Polarity
* @{
*/
#define TIM_ETRPOLARITY_INVERTED TIM_SMCR_ETP /*!< Polarity for ETR source */
#define TIM_ETRPOLARITY_NONINVERTED 0x00000000U /*!< Polarity for ETR source */
/**
* @}
*/
/** @defgroup TIM_ETR_Prescaler TIM ETR Prescaler
* @{
*/
#define TIM_ETRPRESCALER_DIV1 0x00000000U /*!< No prescaler is used */
#define TIM_ETRPRESCALER_DIV2 TIM_SMCR_ETPS_0 /*!< ETR input source is divided by 2 */
#define TIM_ETRPRESCALER_DIV4 TIM_SMCR_ETPS_1 /*!< ETR input source is divided by 4 */
#define TIM_ETRPRESCALER_DIV8 TIM_SMCR_ETPS /*!< ETR input source is divided by 8 */
/**
* @}
*/
/** @defgroup TIM_Counter_Mode TIM Counter Mode
* @{
*/
#define TIM_COUNTERMODE_UP 0x00000000U /*!< Counter used as up-counter */
#define TIM_COUNTERMODE_DOWN TIM_CR1_DIR /*!< Counter used as down-counter */
#define TIM_COUNTERMODE_CENTERALIGNED1 TIM_CR1_CMS_0 /*!< Center-aligned mode 1 */
#define TIM_COUNTERMODE_CENTERALIGNED2 TIM_CR1_CMS_1 /*!< Center-aligned mode 2 */
#define TIM_COUNTERMODE_CENTERALIGNED3 TIM_CR1_CMS /*!< Center-aligned mode 3 */
/**
* @}
*/
/** @defgroup TIM_Update_Interrupt_Flag_Remap TIM Update Interrupt Flag Remap
* @{
*/
#define TIM_UIFREMAP_DISABLE 0x00000000U /*!< Update interrupt flag remap disabled */
#define TIM_UIFREMAP_ENABLE TIM_CR1_UIFREMAP /*!< Update interrupt flag remap enabled */
/**
* @}
*/
/** @defgroup TIM_ClockDivision TIM Clock Division
* @{
*/
#define TIM_CLOCKDIVISION_DIV1 0x00000000U /*!< Clock division: tDTS=tCK_INT */
#define TIM_CLOCKDIVISION_DIV2 TIM_CR1_CKD_0 /*!< Clock division: tDTS=2*tCK_INT */
#define TIM_CLOCKDIVISION_DIV4 TIM_CR1_CKD_1 /*!< Clock division: tDTS=4*tCK_INT */
/**
* @}
*/
/** @defgroup TIM_Output_Compare_State TIM Output Compare State
* @{
*/
#define TIM_OUTPUTSTATE_DISABLE 0x00000000U /*!< Capture/Compare 1 output disabled */
#define TIM_OUTPUTSTATE_ENABLE TIM_CCER_CC1E /*!< Capture/Compare 1 output enabled */
/**
* @}
*/
/** @defgroup TIM_AutoReloadPreload TIM Auto-Reload Preload
* @{
*/
#define TIM_AUTORELOAD_PRELOAD_DISABLE 0x00000000U /*!< TIMx_ARR register is not buffered */
#define TIM_AUTORELOAD_PRELOAD_ENABLE TIM_CR1_ARPE /*!< TIMx_ARR register is buffered */
/**
* @}
*/
/** @defgroup TIM_Output_Fast_State TIM Output Fast State
* @{
*/
#define TIM_OCFAST_DISABLE 0x00000000U /*!< Output Compare fast disable */
#define TIM_OCFAST_ENABLE TIM_CCMR1_OC1FE /*!< Output Compare fast enable */
/**
* @}
*/
/** @defgroup TIM_Output_Compare_N_State TIM Complementary Output Compare State
* @{
*/
#define TIM_OUTPUTNSTATE_DISABLE 0x00000000U /*!< OCxN is disabled */
#define TIM_OUTPUTNSTATE_ENABLE TIM_CCER_CC1NE /*!< OCxN is enabled */
/**
* @}
*/
/** @defgroup TIM_Output_Compare_Polarity TIM Output Compare Polarity
* @{
*/
#define TIM_OCPOLARITY_HIGH 0x00000000U /*!< Capture/Compare output polarity */
#define TIM_OCPOLARITY_LOW TIM_CCER_CC1P /*!< Capture/Compare output polarity */
/**
* @}
*/
/** @defgroup TIM_Output_Compare_N_Polarity TIM Complementary Output Compare Polarity
* @{
*/
#define TIM_OCNPOLARITY_HIGH 0x00000000U /*!< Capture/Compare complementary output polarity */
#define TIM_OCNPOLARITY_LOW TIM_CCER_CC1NP /*!< Capture/Compare complementary output polarity */
/**
* @}
*/
/** @defgroup TIM_Output_Compare_Idle_State TIM Output Compare Idle State
* @{
*/
#define TIM_OCIDLESTATE_SET TIM_CR2_OIS1 /*!< Output Idle state: OCx=1 when MOE=0 */
#define TIM_OCIDLESTATE_RESET 0x00000000U /*!< Output Idle state: OCx=0 when MOE=0 */
/**
* @}
*/
/** @defgroup TIM_Output_Compare_N_Idle_State TIM Complementary Output Compare Idle State
* @{
*/
#define TIM_OCNIDLESTATE_SET TIM_CR2_OIS1N /*!< Complementary output Idle state: OCxN=1 when MOE=0 */
#define TIM_OCNIDLESTATE_RESET 0x00000000U /*!< Complementary output Idle state: OCxN=0 when MOE=0 */
/**
* @}
*/
/** @defgroup TIM_Input_Capture_Polarity TIM Input Capture Polarity
* @{
*/
#define TIM_ICPOLARITY_RISING TIM_INPUTCHANNELPOLARITY_RISING /*!< Capture triggered by rising edge on timer input */
#define TIM_ICPOLARITY_FALLING TIM_INPUTCHANNELPOLARITY_FALLING /*!< Capture triggered by falling edge on timer input */
#define TIM_ICPOLARITY_BOTHEDGE TIM_INPUTCHANNELPOLARITY_BOTHEDGE /*!< Capture triggered by both rising and falling edges on timer input*/
/**
* @}
*/
/** @defgroup TIM_Encoder_Input_Polarity TIM Encoder Input Polarity
* @{
*/
#define TIM_ENCODERINPUTPOLARITY_RISING TIM_INPUTCHANNELPOLARITY_RISING /*!< Encoder input with rising edge polarity */
#define TIM_ENCODERINPUTPOLARITY_FALLING TIM_INPUTCHANNELPOLARITY_FALLING /*!< Encoder input with falling edge polarity */
/**
* @}
*/
/** @defgroup TIM_Input_Capture_Selection TIM Input Capture Selection
* @{
*/
#define TIM_ICSELECTION_DIRECTTI TIM_CCMR1_CC1S_0 /*!< TIM Input 1, 2, 3 or 4 is selected to be connected to IC1, IC2, IC3 or IC4, respectively */
#define TIM_ICSELECTION_INDIRECTTI TIM_CCMR1_CC1S_1 /*!< TIM Input 1, 2, 3 or 4 is selected to be connected to IC2, IC1, IC4 or IC3, respectively */
#define TIM_ICSELECTION_TRC TIM_CCMR1_CC1S /*!< TIM Input 1, 2, 3 or 4 is selected to be connected to TRC */
/**
* @}
*/
/** @defgroup TIM_Input_Capture_Prescaler TIM Input Capture Prescaler
* @{
*/
#define TIM_ICPSC_DIV1 0x00000000U /*!< Capture performed each time an edge is detected on the capture input */
#define TIM_ICPSC_DIV2 TIM_CCMR1_IC1PSC_0 /*!< Capture performed once every 2 events */
#define TIM_ICPSC_DIV4 TIM_CCMR1_IC1PSC_1 /*!< Capture performed once every 4 events */
#define TIM_ICPSC_DIV8 TIM_CCMR1_IC1PSC /*!< Capture performed once every 8 events */
/**
* @}
*/
/** @defgroup TIM_One_Pulse_Mode TIM One Pulse Mode
* @{
*/
#define TIM_OPMODE_SINGLE TIM_CR1_OPM /*!< Counter stops counting at the next update event */
#define TIM_OPMODE_REPETITIVE 0x00000000U /*!< Counter is not stopped at update event */
/**
* @}
*/
/** @defgroup TIM_Encoder_Mode TIM Encoder Mode
* @{
*/
#define TIM_ENCODERMODE_TI1 TIM_SMCR_SMS_0 /*!< Quadrature encoder mode 1, x2 mode, counts up/down on TI1FP1 edge depending on TI2FP2 level */
#define TIM_ENCODERMODE_TI2 TIM_SMCR_SMS_1 /*!< Quadrature encoder mode 2, x2 mode, counts up/down on TI2FP2 edge depending on TI1FP1 level. */
#define TIM_ENCODERMODE_TI12 (TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< Quadrature encoder mode 3, x4 mode, counts up/down on both TI1FP1 and TI2FP2 edges depending on the level of the other input. */
#define TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X2 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_1) /*!< Encoder mode: Clock plus direction, x2 mode */
#define TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X1 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< Encoder mode: Clock plus direction, x1 mode, TI2FP2 edge sensitivity is set by CC2P */
#define TIM_ENCODERMODE_DIRECTIONALCLOCK_X2 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2) /*!< Encoder mode: Directional Clock, x2 mode */
#define TIM_ENCODERMODE_DIRECTIONALCLOCK_X1_TI12 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2 | TIM_SMCR_SMS_0) /*!< Encoder mode: Directional Clock, x1 mode, TI1FP1 and TI2FP2 edge sensitivity is set by CC1P and CC2P */
#define TIM_ENCODERMODE_X1_TI1 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1) /*!< Quadrature encoder mode: x1 mode, counting on TI1FP1 edges only, edge sensitivity is set by CC1P */
#define TIM_ENCODERMODE_X1_TI2 (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< Quadrature encoder mode: x1 mode, counting on TI2FP2 edges only, edge sensitivity is set by CC1P */
/**
* @}
*/
/** @defgroup TIM_Interrupt_definition TIM interrupt Definition
* @{
*/
#define TIM_IT_UPDATE TIM_DIER_UIE /*!< Update interrupt */
#define TIM_IT_CC1 TIM_DIER_CC1IE /*!< Capture/Compare 1 interrupt */
#define TIM_IT_CC2 TIM_DIER_CC2IE /*!< Capture/Compare 2 interrupt */
#define TIM_IT_CC3 TIM_DIER_CC3IE /*!< Capture/Compare 3 interrupt */
#define TIM_IT_CC4 TIM_DIER_CC4IE /*!< Capture/Compare 4 interrupt */
#define TIM_IT_COM TIM_DIER_COMIE /*!< Commutation interrupt */
#define TIM_IT_TRIGGER TIM_DIER_TIE /*!< Trigger interrupt */
#define TIM_IT_BREAK TIM_DIER_BIE /*!< Break interrupt */
#define TIM_IT_IDX TIM_DIER_IDXIE /*!< Index interrupt */
#define TIM_IT_DIR TIM_DIER_DIRIE /*!< Direction change interrupt */
#define TIM_IT_IERR TIM_DIER_IERRIE /*!< Index error interrupt */
#define TIM_IT_TERR TIM_DIER_TERRIE /*!< Transition error interrupt */
/**
* @}
*/
/** @defgroup TIM_Commutation_Source TIM Commutation Source
* @{
*/
#define TIM_COMMUTATION_TRGI TIM_CR2_CCUS /*!< When Capture/compare control bits are preloaded, they are updated by setting the COMG bit or when an rising edge occurs on trigger input */
#define TIM_COMMUTATION_SOFTWARE 0x00000000U /*!< When Capture/compare control bits are preloaded, they are updated by setting the COMG bit */
/**
* @}
*/
/** @defgroup TIM_DMA_sources TIM DMA Sources
* @{
*/
#define TIM_DMA_UPDATE TIM_DIER_UDE /*!< DMA request is triggered by the update event */
#define TIM_DMA_CC1 TIM_DIER_CC1DE /*!< DMA request is triggered by the capture/compare macth 1 event */
#define TIM_DMA_CC2 TIM_DIER_CC2DE /*!< DMA request is triggered by the capture/compare macth 2 event event */
#define TIM_DMA_CC3 TIM_DIER_CC3DE /*!< DMA request is triggered by the capture/compare macth 3 event event */
#define TIM_DMA_CC4 TIM_DIER_CC4DE /*!< DMA request is triggered by the capture/compare macth 4 event event */
#define TIM_DMA_COM TIM_DIER_COMDE /*!< DMA request is triggered by the commutation event */
#define TIM_DMA_TRIGGER TIM_DIER_TDE /*!< DMA request is triggered by the trigger event */
/**
* @}
*/
/** @defgroup TIM_CC_DMA_Request CCx DMA request selection
* @{
*/
#define TIM_CCDMAREQUEST_CC 0x00000000U /*!< CCx DMA request sent when capture or compare match event occurs */
#define TIM_CCDMAREQUEST_UPDATE TIM_CR2_CCDS /*!< CCx DMA requests sent when update event occurs */
/**
* @}
*/
/** @defgroup TIM_Flag_definition TIM Flag Definition
* @{
*/
#define TIM_FLAG_UPDATE TIM_SR_UIF /*!< Update interrupt flag */
#define TIM_FLAG_CC1 TIM_SR_CC1IF /*!< Capture/Compare 1 interrupt flag */
#define TIM_FLAG_CC2 TIM_SR_CC2IF /*!< Capture/Compare 2 interrupt flag */
#define TIM_FLAG_CC3 TIM_SR_CC3IF /*!< Capture/Compare 3 interrupt flag */
#define TIM_FLAG_CC4 TIM_SR_CC4IF /*!< Capture/Compare 4 interrupt flag */
#define TIM_FLAG_CC5 TIM_SR_CC5IF /*!< Capture/Compare 5 interrupt flag */
#define TIM_FLAG_CC6 TIM_SR_CC6IF /*!< Capture/Compare 6 interrupt flag */
#define TIM_FLAG_COM TIM_SR_COMIF /*!< Commutation interrupt flag */
#define TIM_FLAG_TRIGGER TIM_SR_TIF /*!< Trigger interrupt flag */
#define TIM_FLAG_BREAK TIM_SR_BIF /*!< Break interrupt flag */
#define TIM_FLAG_BREAK2 TIM_SR_B2IF /*!< Break 2 interrupt flag */
#define TIM_FLAG_SYSTEM_BREAK TIM_SR_SBIF /*!< System Break interrupt flag */
#define TIM_FLAG_CC1OF TIM_SR_CC1OF /*!< Capture 1 overcapture flag */
#define TIM_FLAG_CC2OF TIM_SR_CC2OF /*!< Capture 2 overcapture flag */
#define TIM_FLAG_CC3OF TIM_SR_CC3OF /*!< Capture 3 overcapture flag */
#define TIM_FLAG_CC4OF TIM_SR_CC4OF /*!< Capture 4 overcapture flag */
#define TIM_FLAG_IDX TIM_SR_IDXF /*!< Encoder index flag */
#define TIM_FLAG_DIR TIM_SR_DIRF /*!< Direction change flag */
#define TIM_FLAG_IERR TIM_SR_IERRF /*!< Index error flag */
#define TIM_FLAG_TERR TIM_SR_TERRF /*!< Transition error flag */
/**
* @}
*/
/** @defgroup TIM_Channel TIM Channel
* @{
*/
#define TIM_CHANNEL_1 0x00000000U /*!< Capture/compare channel 1 identifier */
#define TIM_CHANNEL_2 0x00000004U /*!< Capture/compare channel 2 identifier */
#define TIM_CHANNEL_3 0x00000008U /*!< Capture/compare channel 3 identifier */
#define TIM_CHANNEL_4 0x0000000CU /*!< Capture/compare channel 4 identifier */
#define TIM_CHANNEL_5 0x00000010U /*!< Compare channel 5 identifier */
#define TIM_CHANNEL_6 0x00000014U /*!< Compare channel 6 identifier */
#define TIM_CHANNEL_ALL 0x0000003CU /*!< Global Capture/compare channel identifier */
/**
* @}
*/
/** @defgroup TIM_Clock_Source TIM Clock Source
* @{
*/
#define TIM_CLOCKSOURCE_INTERNAL TIM_SMCR_ETPS_0 /*!< Internal clock source */
#define TIM_CLOCKSOURCE_ETRMODE1 TIM_TS_ETRF /*!< External clock source mode 1 (ETRF) */
#define TIM_CLOCKSOURCE_ETRMODE2 TIM_SMCR_ETPS_1 /*!< External clock source mode 2 */
#define TIM_CLOCKSOURCE_TI1ED TIM_TS_TI1F_ED /*!< External clock source mode 1 (TTI1FP1 + edge detect.) */
#define TIM_CLOCKSOURCE_TI1 TIM_TS_TI1FP1 /*!< External clock source mode 1 (TTI1FP1) */
#define TIM_CLOCKSOURCE_TI2 TIM_TS_TI2FP2 /*!< External clock source mode 1 (TTI2FP2) */
#define TIM_CLOCKSOURCE_ITR0 TIM_TS_ITR0 /*!< External clock source mode 1 (ITR0) */
#define TIM_CLOCKSOURCE_ITR1 TIM_TS_ITR1 /*!< External clock source mode 1 (ITR1) */
#define TIM_CLOCKSOURCE_ITR2 TIM_TS_ITR2 /*!< External clock source mode 1 (ITR2) */
#define TIM_CLOCKSOURCE_ITR3 TIM_TS_ITR3 /*!< External clock source mode 1 (ITR3) */
#if defined (TIM5)
#define TIM_CLOCKSOURCE_ITR4 TIM_TS_ITR4 /*!< External clock source mode 1 (ITR4) */
#endif /* TIM5 */
#define TIM_CLOCKSOURCE_ITR5 TIM_TS_ITR5 /*!< External clock source mode 1 (ITR5) */
#define TIM_CLOCKSOURCE_ITR6 TIM_TS_ITR6 /*!< External clock source mode 1 (ITR6) */
#define TIM_CLOCKSOURCE_ITR7 TIM_TS_ITR7 /*!< External clock source mode 1 (ITR7) */
#define TIM_CLOCKSOURCE_ITR8 TIM_TS_ITR8 /*!< External clock source mode 1 (ITR8) */
#if defined (TIM20)
#define TIM_CLOCKSOURCE_ITR9 TIM_TS_ITR9 /*!< External clock source mode 1 (ITR9) */
#endif /* TIM20 */
#define TIM_CLOCKSOURCE_ITR10 TIM_TS_ITR10 /*!< External clock source mode 1 (ITR10) */
#define TIM_CLOCKSOURCE_ITR11 TIM_TS_ITR11 /*!< External clock source mode 1 (ITR11) */
/**
* @}
*/
/** @defgroup TIM_Clock_Polarity TIM Clock Polarity
* @{
*/
#define TIM_CLOCKPOLARITY_INVERTED TIM_ETRPOLARITY_INVERTED /*!< Polarity for ETRx clock sources */
#define TIM_CLOCKPOLARITY_NONINVERTED TIM_ETRPOLARITY_NONINVERTED /*!< Polarity for ETRx clock sources */
#define TIM_CLOCKPOLARITY_RISING TIM_INPUTCHANNELPOLARITY_RISING /*!< Polarity for TIx clock sources */
#define TIM_CLOCKPOLARITY_FALLING TIM_INPUTCHANNELPOLARITY_FALLING /*!< Polarity for TIx clock sources */
#define TIM_CLOCKPOLARITY_BOTHEDGE TIM_INPUTCHANNELPOLARITY_BOTHEDGE /*!< Polarity for TIx clock sources */
/**
* @}
*/
/** @defgroup TIM_Clock_Prescaler TIM Clock Prescaler
* @{
*/
#define TIM_CLOCKPRESCALER_DIV1 TIM_ETRPRESCALER_DIV1 /*!< No prescaler is used */
#define TIM_CLOCKPRESCALER_DIV2 TIM_ETRPRESCALER_DIV2 /*!< Prescaler for External ETR Clock: Capture performed once every 2 events. */
#define TIM_CLOCKPRESCALER_DIV4 TIM_ETRPRESCALER_DIV4 /*!< Prescaler for External ETR Clock: Capture performed once every 4 events. */
#define TIM_CLOCKPRESCALER_DIV8 TIM_ETRPRESCALER_DIV8 /*!< Prescaler for External ETR Clock: Capture performed once every 8 events. */
/**
* @}
*/
/** @defgroup TIM_ClearInput_Polarity TIM Clear Input Polarity
* @{
*/
#define TIM_CLEARINPUTPOLARITY_INVERTED TIM_ETRPOLARITY_INVERTED /*!< Polarity for ETRx pin */
#define TIM_CLEARINPUTPOLARITY_NONINVERTED TIM_ETRPOLARITY_NONINVERTED /*!< Polarity for ETRx pin */
/**
* @}
*/
/** @defgroup TIM_ClearInput_Prescaler TIM Clear Input Prescaler
* @{
*/
#define TIM_CLEARINPUTPRESCALER_DIV1 TIM_ETRPRESCALER_DIV1 /*!< No prescaler is used */
#define TIM_CLEARINPUTPRESCALER_DIV2 TIM_ETRPRESCALER_DIV2 /*!< Prescaler for External ETR pin: Capture performed once every 2 events. */
#define TIM_CLEARINPUTPRESCALER_DIV4 TIM_ETRPRESCALER_DIV4 /*!< Prescaler for External ETR pin: Capture performed once every 4 events. */
#define TIM_CLEARINPUTPRESCALER_DIV8 TIM_ETRPRESCALER_DIV8 /*!< Prescaler for External ETR pin: Capture performed once every 8 events. */
/**
* @}
*/
/** @defgroup TIM_OSSR_Off_State_Selection_for_Run_mode_state TIM OSSR OffState Selection for Run mode state
* @{
*/
#define TIM_OSSR_ENABLE TIM_BDTR_OSSR /*!< When inactive, OC/OCN outputs are enabled (still controlled by the timer) */
#define TIM_OSSR_DISABLE 0x00000000U /*!< When inactive, OC/OCN outputs are disabled (not controlled any longer by the timer) */
/**
* @}
*/
/** @defgroup TIM_OSSI_Off_State_Selection_for_Idle_mode_state TIM OSSI OffState Selection for Idle mode state
* @{
*/
#define TIM_OSSI_ENABLE TIM_BDTR_OSSI /*!< When inactive, OC/OCN outputs are enabled (still controlled by the timer) */
#define TIM_OSSI_DISABLE 0x00000000U /*!< When inactive, OC/OCN outputs are disabled (not controlled any longer by the timer) */
/**
* @}
*/
/** @defgroup TIM_Lock_level TIM Lock level
* @{
*/
#define TIM_LOCKLEVEL_OFF 0x00000000U /*!< LOCK OFF */
#define TIM_LOCKLEVEL_1 TIM_BDTR_LOCK_0 /*!< LOCK Level 1 */
#define TIM_LOCKLEVEL_2 TIM_BDTR_LOCK_1 /*!< LOCK Level 2 */
#define TIM_LOCKLEVEL_3 TIM_BDTR_LOCK /*!< LOCK Level 3 */
/**
* @}
*/
/** @defgroup TIM_Break_Input_enable_disable TIM Break Input Enable
* @{
*/
#define TIM_BREAK_ENABLE TIM_BDTR_BKE /*!< Break input BRK is enabled */
#define TIM_BREAK_DISABLE 0x00000000U /*!< Break input BRK is disabled */
/**
* @}
*/
/** @defgroup TIM_Break_Polarity TIM Break Input Polarity
* @{
*/
#define TIM_BREAKPOLARITY_LOW 0x00000000U /*!< Break input BRK is active low */
#define TIM_BREAKPOLARITY_HIGH TIM_BDTR_BKP /*!< Break input BRK is active high */
/**
* @}
*/
/** @defgroup TIM_Break_Input_AF_Mode TIM Break Input Alternate Function Mode
* @{
*/
#define TIM_BREAK_AFMODE_INPUT 0x00000000U /*!< Break input BRK in input mode */
#define TIM_BREAK_AFMODE_BIDIRECTIONAL TIM_BDTR_BKBID /*!< Break input BRK in bidirectional mode */
/**
* @}
*/
/** @defgroup TIM_Break2_Input_enable_disable TIM Break input 2 Enable
* @{
*/
#define TIM_BREAK2_DISABLE 0x00000000U /*!< Break input BRK2 is disabled */
#define TIM_BREAK2_ENABLE TIM_BDTR_BK2E /*!< Break input BRK2 is enabled */
/**
* @}
*/
/** @defgroup TIM_Break2_Polarity TIM Break Input 2 Polarity
* @{
*/
#define TIM_BREAK2POLARITY_LOW 0x00000000U /*!< Break input BRK2 is active low */
#define TIM_BREAK2POLARITY_HIGH TIM_BDTR_BK2P /*!< Break input BRK2 is active high */
/**
* @}
*/
/** @defgroup TIM_Break2_Input_AF_Mode TIM Break2 Input Alternate Function Mode
* @{
*/
#define TIM_BREAK2_AFMODE_INPUT 0x00000000U /*!< Break2 input BRK2 in input mode */
#define TIM_BREAK2_AFMODE_BIDIRECTIONAL TIM_BDTR_BK2BID /*!< Break2 input BRK2 in bidirectional mode */
/**
* @}
*/
/** @defgroup TIM_AOE_Bit_Set_Reset TIM Automatic Output Enable
* @{
*/
#define TIM_AUTOMATICOUTPUT_DISABLE 0x00000000U /*!< MOE can be set only by software */
#define TIM_AUTOMATICOUTPUT_ENABLE TIM_BDTR_AOE /*!< MOE can be set by software or automatically at the next update event (if none of the break inputs BRK and BRK2 is active) */
/**
* @}
*/
/** @defgroup TIM_Group_Channel5 TIM Group Channel 5 and Channel 1, 2 or 3
* @{
*/
#define TIM_GROUPCH5_NONE 0x00000000U /*!< No effect of OC5REF on OC1REFC, OC2REFC and OC3REFC */
#define TIM_GROUPCH5_OC1REFC TIM_CCR5_GC5C1 /*!< OC1REFC is the logical AND of OC1REFC and OC5REF */
#define TIM_GROUPCH5_OC2REFC TIM_CCR5_GC5C2 /*!< OC2REFC is the logical AND of OC2REFC and OC5REF */
#define TIM_GROUPCH5_OC3REFC TIM_CCR5_GC5C3 /*!< OC3REFC is the logical AND of OC3REFC and OC5REF */
/**
* @}
*/
/** @defgroup TIM_Master_Mode_Selection TIM Master Mode Selection
* @{
*/
#define TIM_TRGO_RESET 0x00000000U /*!< TIMx_EGR.UG bit is used as trigger output (TRGO) */
#define TIM_TRGO_ENABLE TIM_CR2_MMS_0 /*!< TIMx_CR1.CEN bit is used as trigger output (TRGO) */
#define TIM_TRGO_UPDATE TIM_CR2_MMS_1 /*!< Update event is used as trigger output (TRGO) */
#define TIM_TRGO_OC1 (TIM_CR2_MMS_1 | TIM_CR2_MMS_0) /*!< Capture or a compare match 1 is used as trigger output (TRGO) */
#define TIM_TRGO_OC1REF TIM_CR2_MMS_2 /*!< OC1REF signal is used as trigger output (TRGO) */
#define TIM_TRGO_OC2REF (TIM_CR2_MMS_2 | TIM_CR2_MMS_0) /*!< OC2REF signal is used as trigger output(TRGO) */
#define TIM_TRGO_OC3REF (TIM_CR2_MMS_2 | TIM_CR2_MMS_1) /*!< OC3REF signal is used as trigger output(TRGO) */
#define TIM_TRGO_OC4REF (TIM_CR2_MMS_2 | TIM_CR2_MMS_1 | TIM_CR2_MMS_0) /*!< OC4REF signal is used as trigger output(TRGO) */
#define TIM_TRGO_ENCODER_CLK TIM_CR2_MMS_3 /*!< Encoder clock is used as trigger output(TRGO) */
/**
* @}
*/
/** @defgroup TIM_Master_Mode_Selection_2 TIM Master Mode Selection 2 (TRGO2)
* @{
*/
#define TIM_TRGO2_RESET 0x00000000U /*!< TIMx_EGR.UG bit is used as trigger output (TRGO2) */
#define TIM_TRGO2_ENABLE TIM_CR2_MMS2_0 /*!< TIMx_CR1.CEN bit is used as trigger output (TRGO2) */
#define TIM_TRGO2_UPDATE TIM_CR2_MMS2_1 /*!< Update event is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC1 (TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< Capture or a compare match 1 is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC1REF TIM_CR2_MMS2_2 /*!< OC1REF signal is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC2REF (TIM_CR2_MMS2_2 | TIM_CR2_MMS2_0) /*!< OC2REF signal is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC3REF (TIM_CR2_MMS2_2 | TIM_CR2_MMS2_1) /*!< OC3REF signal is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC4REF (TIM_CR2_MMS2_2 | TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< OC4REF signal is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC5REF TIM_CR2_MMS2_3 /*!< OC5REF signal is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC6REF (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_0) /*!< OC6REF signal is used as trigger output (TRGO2) */
#define TIM_TRGO2_OC4REF_RISINGFALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_1) /*!< OC4REF rising or falling edges generate pulses on TRGO2 */
#define TIM_TRGO2_OC6REF_RISINGFALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< OC6REF rising or falling edges generate pulses on TRGO2 */
#define TIM_TRGO2_OC4REF_RISING_OC6REF_RISING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2) /*!< OC4REF or OC6REF rising edges generate pulses on TRGO2 */
#define TIM_TRGO2_OC4REF_RISING_OC6REF_FALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2 | TIM_CR2_MMS2_0) /*!< OC4REF rising or OC6REF falling edges generate pulses on TRGO2 */
#define TIM_TRGO2_OC5REF_RISING_OC6REF_RISING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2 |TIM_CR2_MMS2_1) /*!< OC5REF or OC6REF rising edges generate pulses on TRGO2 */
#define TIM_TRGO2_OC5REF_RISING_OC6REF_FALLING (TIM_CR2_MMS2_3 | TIM_CR2_MMS2_2 | TIM_CR2_MMS2_1 | TIM_CR2_MMS2_0) /*!< OC5REF or OC6REF rising edges generate pulses on TRGO2 */
/**
* @}
*/
/** @defgroup TIM_Master_Slave_Mode TIM Master/Slave Mode
* @{
*/
#define TIM_MASTERSLAVEMODE_ENABLE TIM_SMCR_MSM /*!< No action */
#define TIM_MASTERSLAVEMODE_DISABLE 0x00000000U /*!< Master/slave mode is selected */
/**
* @}
*/
/** @defgroup TIM_Slave_Mode TIM Slave mode
* @{
*/
#define TIM_SLAVEMODE_DISABLE 0x00000000U /*!< Slave mode disabled */
#define TIM_SLAVEMODE_RESET TIM_SMCR_SMS_2 /*!< Reset Mode */
#define TIM_SLAVEMODE_GATED (TIM_SMCR_SMS_2 | TIM_SMCR_SMS_0) /*!< Gated Mode */
#define TIM_SLAVEMODE_TRIGGER (TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1) /*!< Trigger Mode */
#define TIM_SLAVEMODE_EXTERNAL1 (TIM_SMCR_SMS_2 | TIM_SMCR_SMS_1 | TIM_SMCR_SMS_0) /*!< External Clock Mode 1 */
#define TIM_SLAVEMODE_COMBINED_RESETTRIGGER TIM_SMCR_SMS_3 /*!< Combined reset + trigger mode */
#define TIM_SLAVEMODE_COMBINED_GATEDRESET (TIM_SMCR_SMS_3 | TIM_SMCR_SMS_0) /*!< Combined gated + reset mode */
/**
* @}
*/
/** @defgroup TIM_Output_Compare_and_PWM_modes TIM Output Compare and PWM Modes
* @{
*/
#define TIM_OCMODE_TIMING 0x00000000U /*!< Frozen */
#define TIM_OCMODE_ACTIVE TIM_CCMR1_OC1M_0 /*!< Set channel to active level on match */
#define TIM_OCMODE_INACTIVE TIM_CCMR1_OC1M_1 /*!< Set channel to inactive level on match */
#define TIM_OCMODE_TOGGLE (TIM_CCMR1_OC1M_1 | TIM_CCMR1_OC1M_0) /*!< Toggle */
#define TIM_OCMODE_PWM1 (TIM_CCMR1_OC1M_2 | TIM_CCMR1_OC1M_1) /*!< PWM mode 1 */
#define TIM_OCMODE_PWM2 (TIM_CCMR1_OC1M_2 | TIM_CCMR1_OC1M_1 | TIM_CCMR1_OC1M_0) /*!< PWM mode 2 */
#define TIM_OCMODE_FORCED_ACTIVE (TIM_CCMR1_OC1M_2 | TIM_CCMR1_OC1M_0) /*!< Force active level */
#define TIM_OCMODE_FORCED_INACTIVE TIM_CCMR1_OC1M_2 /*!< Force inactive level */
#define TIM_OCMODE_RETRIGERRABLE_OPM1 TIM_CCMR1_OC1M_3 /*!< Retrigerrable OPM mode 1 */
#define TIM_OCMODE_RETRIGERRABLE_OPM2 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_0) /*!< Retrigerrable OPM mode 2 */
#define TIM_OCMODE_COMBINED_PWM1 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_2) /*!< Combined PWM mode 1 */
#define TIM_OCMODE_COMBINED_PWM2 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_0 | TIM_CCMR1_OC1M_2) /*!< Combined PWM mode 2 */
#define TIM_OCMODE_ASYMMETRIC_PWM1 (TIM_CCMR1_OC1M_3 | TIM_CCMR1_OC1M_1 | TIM_CCMR1_OC1M_2) /*!< Asymmetric PWM mode 1 */
#define TIM_OCMODE_ASYMMETRIC_PWM2 TIM_CCMR1_OC1M /*!< Asymmetric PWM mode 2 */
#define TIM_OCMODE_PULSE_ON_COMPARE (TIM_CCMR2_OC3M_3 | TIM_CCMR2_OC3M_1) /*!< Pulse on compare (CH3&CH4 only) */
#define TIM_OCMODE_DIRECTION_OUTPUT (TIM_CCMR2_OC3M_3 | TIM_CCMR2_OC3M_1 | TIM_CCMR2_OC3M_0) /*!< Direction output (CH3&CH4 only) */
/**
* @}
*/
/** @defgroup TIM_Trigger_Selection TIM Trigger Selection
* @{
*/
#define TIM_TS_ITR0 0x00000000U /*!< Internal Trigger 0 (ITR0) */
#define TIM_TS_ITR1 TIM_SMCR_TS_0 /*!< Internal Trigger 1 (ITR1) */
#define TIM_TS_ITR2 TIM_SMCR_TS_1 /*!< Internal Trigger 2 (ITR2) */
#define TIM_TS_ITR3 (TIM_SMCR_TS_0 | TIM_SMCR_TS_1) /*!< Internal Trigger 3 (ITR3) */
#if defined (TIM5)
#define TIM_TS_ITR4 TIM_SMCR_TS_3 /*!< Internal Trigger 4 (ITR9) */
#endif /* TIM5 */
#define TIM_TS_ITR5 (TIM_SMCR_TS_0 | TIM_SMCR_TS_3) /*!< Internal Trigger 5 (ITR5) */
#define TIM_TS_ITR6 (TIM_SMCR_TS_1 | TIM_SMCR_TS_3) /*!< Internal Trigger 6 (ITR6) */
#define TIM_TS_ITR7 (TIM_SMCR_TS_0 | TIM_SMCR_TS_1 | TIM_SMCR_TS_3) /*!< Internal Trigger 7 (ITR7) */
#define TIM_TS_ITR8 (TIM_SMCR_TS_2 | TIM_SMCR_TS_3) /*!< Internal Trigger 8 (ITR8) */
#if defined (TIM20)
#define TIM_TS_ITR9 (TIM_SMCR_TS_0 | TIM_SMCR_TS_2 | TIM_SMCR_TS_3) /*!< Internal Trigger 9 (ITR9) */
#endif /* TIM20 */
#define TIM_TS_ITR10 (TIM_SMCR_TS_1 | TIM_SMCR_TS_2 | TIM_SMCR_TS_3) /*!< Internal Trigger 10 (ITR10) */
#define TIM_TS_ITR11 (TIM_SMCR_TS_0 | TIM_SMCR_TS_1 | TIM_SMCR_TS_2 | TIM_SMCR_TS_3) /*!< Internal Trigger 11 (ITR11) */
#define TIM_TS_TI1F_ED TIM_SMCR_TS_2 /*!< TI1 Edge Detector (TI1F_ED) */
#define TIM_TS_TI1FP1 (TIM_SMCR_TS_0 | TIM_SMCR_TS_2) /*!< Filtered Timer Input 1 (TI1FP1) */
#define TIM_TS_TI2FP2 (TIM_SMCR_TS_1 | TIM_SMCR_TS_2) /*!< Filtered Timer Input 2 (TI2FP2) */
#define TIM_TS_ETRF (TIM_SMCR_TS_0 | TIM_SMCR_TS_1 | TIM_SMCR_TS_2) /*!< Filtered External Trigger input (ETRF) */
#define TIM_TS_NONE 0x0000FFFFU /*!< No trigger selected */
/**
* @}
*/
/** @defgroup TIM_Trigger_Polarity TIM Trigger Polarity
* @{
*/
#define TIM_TRIGGERPOLARITY_INVERTED TIM_ETRPOLARITY_INVERTED /*!< Polarity for ETRx trigger sources */
#define TIM_TRIGGERPOLARITY_NONINVERTED TIM_ETRPOLARITY_NONINVERTED /*!< Polarity for ETRx trigger sources */
#define TIM_TRIGGERPOLARITY_RISING TIM_INPUTCHANNELPOLARITY_RISING /*!< Polarity for TIxFPx or TI1_ED trigger sources */
#define TIM_TRIGGERPOLARITY_FALLING TIM_INPUTCHANNELPOLARITY_FALLING /*!< Polarity for TIxFPx or TI1_ED trigger sources */
#define TIM_TRIGGERPOLARITY_BOTHEDGE TIM_INPUTCHANNELPOLARITY_BOTHEDGE /*!< Polarity for TIxFPx or TI1_ED trigger sources */
/**
* @}
*/
/** @defgroup TIM_Trigger_Prescaler TIM Trigger Prescaler
* @{
*/
#define TIM_TRIGGERPRESCALER_DIV1 TIM_ETRPRESCALER_DIV1 /*!< No prescaler is used */
#define TIM_TRIGGERPRESCALER_DIV2 TIM_ETRPRESCALER_DIV2 /*!< Prescaler for External ETR Trigger: Capture performed once every 2 events. */
#define TIM_TRIGGERPRESCALER_DIV4 TIM_ETRPRESCALER_DIV4 /*!< Prescaler for External ETR Trigger: Capture performed once every 4 events. */
#define TIM_TRIGGERPRESCALER_DIV8 TIM_ETRPRESCALER_DIV8 /*!< Prescaler for External ETR Trigger: Capture performed once every 8 events. */
/**
* @}
*/
/** @defgroup TIM_TI1_Selection TIM TI1 Input Selection
* @{
*/
#define TIM_TI1SELECTION_CH1 0x00000000U /*!< The TIMx_CH1 pin is connected to TI1 input */
#define TIM_TI1SELECTION_XORCOMBINATION TIM_CR2_TI1S /*!< The TIMx_CH1, CH2 and CH3 pins are connected to the TI1 input (XOR combination) */
/**
* @}
*/
/** @defgroup TIM_DMA_Burst_Length TIM DMA Burst Length
* @{
*/
#define TIM_DMABURSTLENGTH_1TRANSFER 0x00000000U /*!< The transfer is done to 1 register starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_2TRANSFERS 0x00000100U /*!< The transfer is done to 2 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_3TRANSFERS 0x00000200U /*!< The transfer is done to 3 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_4TRANSFERS 0x00000300U /*!< The transfer is done to 4 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_5TRANSFERS 0x00000400U /*!< The transfer is done to 5 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_6TRANSFERS 0x00000500U /*!< The transfer is done to 6 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_7TRANSFERS 0x00000600U /*!< The transfer is done to 7 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_8TRANSFERS 0x00000700U /*!< The transfer is done to 8 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_9TRANSFERS 0x00000800U /*!< The transfer is done to 9 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_10TRANSFERS 0x00000900U /*!< The transfer is done to 10 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_11TRANSFERS 0x00000A00U /*!< The transfer is done to 11 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_12TRANSFERS 0x00000B00U /*!< The transfer is done to 12 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_13TRANSFERS 0x00000C00U /*!< The transfer is done to 13 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_14TRANSFERS 0x00000D00U /*!< The transfer is done to 14 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_15TRANSFERS 0x00000E00U /*!< The transfer is done to 15 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_16TRANSFERS 0x00000F00U /*!< The transfer is done to 16 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_17TRANSFERS 0x00001000U /*!< The transfer is done to 17 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_18TRANSFERS 0x00001100U /*!< The transfer is done to 18 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_19TRANSFERS 0x00001200U /*!< The transfer is done to 19 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_20TRANSFERS 0x00001300U /*!< The transfer is done to 20 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_21TRANSFERS 0x00001400U /*!< The transfer is done to 21 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_22TRANSFERS 0x00001500U /*!< The transfer is done to 22 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_23TRANSFERS 0x00001600U /*!< The transfer is done to 23 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_24TRANSFERS 0x00001700U /*!< The transfer is done to 24 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_25TRANSFERS 0x00001800U /*!< The transfer is done to 25 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
#define TIM_DMABURSTLENGTH_26TRANSFERS 0x00001900U /*!< The transfer is done to 26 registers starting from TIMx_CR1 + TIMx_DCR.DBA */
/**
* @}
*/
/** @defgroup DMA_Handle_index TIM DMA Handle Index
* @{
*/
#define TIM_DMA_ID_UPDATE ((uint16_t) 0x0000) /*!< Index of the DMA handle used for Update DMA requests */
#define TIM_DMA_ID_CC1 ((uint16_t) 0x0001) /*!< Index of the DMA handle used for Capture/Compare 1 DMA requests */
#define TIM_DMA_ID_CC2 ((uint16_t) 0x0002) /*!< Index of the DMA handle used for Capture/Compare 2 DMA requests */
#define TIM_DMA_ID_CC3 ((uint16_t) 0x0003) /*!< Index of the DMA handle used for Capture/Compare 3 DMA requests */
#define TIM_DMA_ID_CC4 ((uint16_t) 0x0004) /*!< Index of the DMA handle used for Capture/Compare 4 DMA requests */
#define TIM_DMA_ID_COMMUTATION ((uint16_t) 0x0005) /*!< Index of the DMA handle used for Commutation DMA requests */
#define TIM_DMA_ID_TRIGGER ((uint16_t) 0x0006) /*!< Index of the DMA handle used for Trigger DMA requests */
/**
* @}
*/
/** @defgroup Channel_CC_State TIM Capture/Compare Channel State
* @{
*/
#define TIM_CCx_ENABLE 0x00000001U /*!< Input or output channel is enabled */
#define TIM_CCx_DISABLE 0x00000000U /*!< Input or output channel is disabled */
#define TIM_CCxN_ENABLE 0x00000004U /*!< Complementary output channel is enabled */
#define TIM_CCxN_DISABLE 0x00000000U /*!< Complementary output channel is enabled */
/**
* @}
*/
/** @defgroup TIM_Break_System TIM Break System
* @{
*/
#define TIM_BREAK_SYSTEM_ECC SYSCFG_CFGR2_ECCL /*!< Enables and locks the ECC error signal with Break Input of TIM1/8/15/16/17/20 */
#define TIM_BREAK_SYSTEM_PVD SYSCFG_CFGR2_PVDL /*!< Enables and locks the PVD connection with TIM1/8/15/16/17/20 Break Input and also the PVDE and PLS bits of the Power Control Interface */
#define TIM_BREAK_SYSTEM_SRAM_PARITY_ERROR SYSCFG_CFGR2_SPL /*!< Enables and locks the SRAM_PARITY error signal with Break Input of TIM1/8/15/16/17/20 */
#define TIM_BREAK_SYSTEM_LOCKUP SYSCFG_CFGR2_CLL /*!< Enables and locks the LOCKUP output of CortexM4 with Break Input of TIM1/8/15/16/17/20 */
/**
* @}
*/
/**
* @}
*/
/* End of exported constants -------------------------------------------------*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup TIM_Exported_Macros TIM Exported Macros
* @{
*/
/** @brief Reset TIM handle state.
* @param __HANDLE__ TIM handle.
* @retval None
*/
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
#define __HAL_TIM_RESET_HANDLE_STATE(__HANDLE__) do { \
(__HANDLE__)->State = HAL_TIM_STATE_RESET; \
(__HANDLE__)->ChannelState[0] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[1] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[2] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[3] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[4] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[5] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[0] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[1] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[2] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[3] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->DMABurstState = HAL_DMA_BURST_STATE_RESET; \
(__HANDLE__)->Base_MspInitCallback = NULL; \
(__HANDLE__)->Base_MspDeInitCallback = NULL; \
(__HANDLE__)->IC_MspInitCallback = NULL; \
(__HANDLE__)->IC_MspDeInitCallback = NULL; \
(__HANDLE__)->OC_MspInitCallback = NULL; \
(__HANDLE__)->OC_MspDeInitCallback = NULL; \
(__HANDLE__)->PWM_MspInitCallback = NULL; \
(__HANDLE__)->PWM_MspDeInitCallback = NULL; \
(__HANDLE__)->OnePulse_MspInitCallback = NULL; \
(__HANDLE__)->OnePulse_MspDeInitCallback = NULL; \
(__HANDLE__)->Encoder_MspInitCallback = NULL; \
(__HANDLE__)->Encoder_MspDeInitCallback = NULL; \
(__HANDLE__)->HallSensor_MspInitCallback = NULL; \
(__HANDLE__)->HallSensor_MspDeInitCallback = NULL; \
} while(0)
#else
#define __HAL_TIM_RESET_HANDLE_STATE(__HANDLE__) do { \
(__HANDLE__)->State = HAL_TIM_STATE_RESET; \
(__HANDLE__)->ChannelState[0] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[1] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[2] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[3] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[4] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelState[5] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[0] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[1] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[2] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->ChannelNState[3] = HAL_TIM_CHANNEL_STATE_RESET; \
(__HANDLE__)->DMABurstState = HAL_DMA_BURST_STATE_RESET; \
} while(0)
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/**
* @brief Enable the TIM peripheral.
* @param __HANDLE__ TIM handle
* @retval None
*/
#define __HAL_TIM_ENABLE(__HANDLE__) ((__HANDLE__)->Instance->CR1|=(TIM_CR1_CEN))
/**
* @brief Enable the TIM main Output.
* @param __HANDLE__ TIM handle
* @retval None
*/
#define __HAL_TIM_MOE_ENABLE(__HANDLE__) ((__HANDLE__)->Instance->BDTR|=(TIM_BDTR_MOE))
/**
* @brief Disable the TIM peripheral.
* @param __HANDLE__ TIM handle
* @retval None
*/
#define __HAL_TIM_DISABLE(__HANDLE__) \
do { \
if (((__HANDLE__)->Instance->CCER & TIM_CCER_CCxE_MASK) == 0UL) \
{ \
if(((__HANDLE__)->Instance->CCER & TIM_CCER_CCxNE_MASK) == 0UL) \
{ \
(__HANDLE__)->Instance->CR1 &= ~(TIM_CR1_CEN); \
} \
} \
} while(0)
/**
* @brief Disable the TIM main Output.
* @param __HANDLE__ TIM handle
* @retval None
* @note The Main Output Enable of a timer instance is disabled only if all the CCx and CCxN channels have been
* disabled
*/
#define __HAL_TIM_MOE_DISABLE(__HANDLE__) \
do { \
if (((__HANDLE__)->Instance->CCER & TIM_CCER_CCxE_MASK) == 0UL) \
{ \
if(((__HANDLE__)->Instance->CCER & TIM_CCER_CCxNE_MASK) == 0UL) \
{ \
(__HANDLE__)->Instance->BDTR &= ~(TIM_BDTR_MOE); \
} \
} \
} while(0)
/**
* @brief Disable the TIM main Output.
* @param __HANDLE__ TIM handle
* @retval None
* @note The Main Output Enable of a timer instance is disabled unconditionally
*/
#define __HAL_TIM_MOE_DISABLE_UNCONDITIONALLY(__HANDLE__) (__HANDLE__)->Instance->BDTR &= ~(TIM_BDTR_MOE)
/** @brief Enable the specified TIM interrupt.
* @param __HANDLE__ specifies the TIM Handle.
* @param __INTERRUPT__ specifies the TIM interrupt source to enable.
* This parameter can be one of the following values:
* @arg TIM_IT_UPDATE: Update interrupt
* @arg TIM_IT_CC1: Capture/Compare 1 interrupt
* @arg TIM_IT_CC2: Capture/Compare 2 interrupt
* @arg TIM_IT_CC3: Capture/Compare 3 interrupt
* @arg TIM_IT_CC4: Capture/Compare 4 interrupt
* @arg TIM_IT_COM: Commutation interrupt
* @arg TIM_IT_TRIGGER: Trigger interrupt
* @arg TIM_IT_BREAK: Break interrupt
* @arg TIM_IT_IDX: Index interrupt
* @arg TIM_IT_DIR: Direction change interrupt
* @arg TIM_IT_IERR: Index error interrupt
* @arg TIM_IT_TERR: Transition error interrupt
* @retval None
*/
#define __HAL_TIM_ENABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->DIER |= (__INTERRUPT__))
/** @brief Disable the specified TIM interrupt.
* @param __HANDLE__ specifies the TIM Handle.
* @param __INTERRUPT__ specifies the TIM interrupt source to disable.
* This parameter can be one of the following values:
* @arg TIM_IT_UPDATE: Update interrupt
* @arg TIM_IT_CC1: Capture/Compare 1 interrupt
* @arg TIM_IT_CC2: Capture/Compare 2 interrupt
* @arg TIM_IT_CC3: Capture/Compare 3 interrupt
* @arg TIM_IT_CC4: Capture/Compare 4 interrupt
* @arg TIM_IT_COM: Commutation interrupt
* @arg TIM_IT_TRIGGER: Trigger interrupt
* @arg TIM_IT_BREAK: Break interrupt
* @arg TIM_IT_IDX: Index interrupt
* @arg TIM_IT_DIR: Direction change interrupt
* @arg TIM_IT_IERR: Index error interrupt
* @arg TIM_IT_TERR: Transition error interrupt
* @retval None
*/
#define __HAL_TIM_DISABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->DIER &= ~(__INTERRUPT__))
/** @brief Enable the specified DMA request.
* @param __HANDLE__ specifies the TIM Handle.
* @param __DMA__ specifies the TIM DMA request to enable.
* This parameter can be one of the following values:
* @arg TIM_DMA_UPDATE: Update DMA request
* @arg TIM_DMA_CC1: Capture/Compare 1 DMA request
* @arg TIM_DMA_CC2: Capture/Compare 2 DMA request
* @arg TIM_DMA_CC3: Capture/Compare 3 DMA request
* @arg TIM_DMA_CC4: Capture/Compare 4 DMA request
* @arg TIM_DMA_COM: Commutation DMA request
* @arg TIM_DMA_TRIGGER: Trigger DMA request
* @retval None
*/
#define __HAL_TIM_ENABLE_DMA(__HANDLE__, __DMA__) ((__HANDLE__)->Instance->DIER |= (__DMA__))
/** @brief Disable the specified DMA request.
* @param __HANDLE__ specifies the TIM Handle.
* @param __DMA__ specifies the TIM DMA request to disable.
* This parameter can be one of the following values:
* @arg TIM_DMA_UPDATE: Update DMA request
* @arg TIM_DMA_CC1: Capture/Compare 1 DMA request
* @arg TIM_DMA_CC2: Capture/Compare 2 DMA request
* @arg TIM_DMA_CC3: Capture/Compare 3 DMA request
* @arg TIM_DMA_CC4: Capture/Compare 4 DMA request
* @arg TIM_DMA_COM: Commutation DMA request
* @arg TIM_DMA_TRIGGER: Trigger DMA request
* @retval None
*/
#define __HAL_TIM_DISABLE_DMA(__HANDLE__, __DMA__) ((__HANDLE__)->Instance->DIER &= ~(__DMA__))
/** @brief Check whether the specified TIM interrupt flag is set or not.
* @param __HANDLE__ specifies the TIM Handle.
* @param __FLAG__ specifies the TIM interrupt flag to check.
* This parameter can be one of the following values:
* @arg TIM_FLAG_UPDATE: Update interrupt flag
* @arg TIM_FLAG_CC1: Capture/Compare 1 interrupt flag
* @arg TIM_FLAG_CC2: Capture/Compare 2 interrupt flag
* @arg TIM_FLAG_CC3: Capture/Compare 3 interrupt flag
* @arg TIM_FLAG_CC4: Capture/Compare 4 interrupt flag
* @arg TIM_FLAG_CC5: Compare 5 interrupt flag
* @arg TIM_FLAG_CC6: Compare 6 interrupt flag
* @arg TIM_FLAG_COM: Commutation interrupt flag
* @arg TIM_FLAG_TRIGGER: Trigger interrupt flag
* @arg TIM_FLAG_BREAK: Break interrupt flag
* @arg TIM_FLAG_BREAK2: Break 2 interrupt flag
* @arg TIM_FLAG_SYSTEM_BREAK: System Break interrupt flag
* @arg TIM_FLAG_CC1OF: Capture/Compare 1 overcapture flag
* @arg TIM_FLAG_CC2OF: Capture/Compare 2 overcapture flag
* @arg TIM_FLAG_CC3OF: Capture/Compare 3 overcapture flag
* @arg TIM_FLAG_CC4OF: Capture/Compare 4 overcapture flag
* @arg TIM_FLAG_IDX: Index interrupt flag
* @arg TIM_FLAG_DIR: Direction change interrupt flag
* @arg TIM_FLAG_IERR: Index error interrupt flag
* @arg TIM_FLAG_TERR: Transition error interrupt flag
* @retval The new state of __FLAG__ (TRUE or FALSE).
*/
#define __HAL_TIM_GET_FLAG(__HANDLE__, __FLAG__) (((__HANDLE__)->Instance->SR &(__FLAG__)) == (__FLAG__))
/** @brief Clear the specified TIM interrupt flag.
* @param __HANDLE__ specifies the TIM Handle.
* @param __FLAG__ specifies the TIM interrupt flag to clear.
* This parameter can be one of the following values:
* @arg TIM_FLAG_UPDATE: Update interrupt flag
* @arg TIM_FLAG_CC1: Capture/Compare 1 interrupt flag
* @arg TIM_FLAG_CC2: Capture/Compare 2 interrupt flag
* @arg TIM_FLAG_CC3: Capture/Compare 3 interrupt flag
* @arg TIM_FLAG_CC4: Capture/Compare 4 interrupt flag
* @arg TIM_FLAG_CC5: Compare 5 interrupt flag
* @arg TIM_FLAG_CC6: Compare 6 interrupt flag
* @arg TIM_FLAG_COM: Commutation interrupt flag
* @arg TIM_FLAG_TRIGGER: Trigger interrupt flag
* @arg TIM_FLAG_BREAK: Break interrupt flag
* @arg TIM_FLAG_BREAK2: Break 2 interrupt flag
* @arg TIM_FLAG_SYSTEM_BREAK: System Break interrupt flag
* @arg TIM_FLAG_CC1OF: Capture/Compare 1 overcapture flag
* @arg TIM_FLAG_CC2OF: Capture/Compare 2 overcapture flag
* @arg TIM_FLAG_CC3OF: Capture/Compare 3 overcapture flag
* @arg TIM_FLAG_CC4OF: Capture/Compare 4 overcapture flag
* @arg TIM_FLAG_IDX: Index interrupt flag
* @arg TIM_FLAG_DIR: Direction change interrupt flag
* @arg TIM_FLAG_IERR: Index error interrupt flag
* @arg TIM_FLAG_TERR: Transition error interrupt flag
* @retval The new state of __FLAG__ (TRUE or FALSE).
*/
#define __HAL_TIM_CLEAR_FLAG(__HANDLE__, __FLAG__) ((__HANDLE__)->Instance->SR = ~(__FLAG__))
/**
* @brief Check whether the specified TIM interrupt source is enabled or not.
* @param __HANDLE__ TIM handle
* @param __INTERRUPT__ specifies the TIM interrupt source to check.
* This parameter can be one of the following values:
* @arg TIM_IT_UPDATE: Update interrupt
* @arg TIM_IT_CC1: Capture/Compare 1 interrupt
* @arg TIM_IT_CC2: Capture/Compare 2 interrupt
* @arg TIM_IT_CC3: Capture/Compare 3 interrupt
* @arg TIM_IT_CC4: Capture/Compare 4 interrupt
* @arg TIM_IT_COM: Commutation interrupt
* @arg TIM_IT_TRIGGER: Trigger interrupt
* @arg TIM_IT_BREAK: Break interrupt
* @arg TIM_IT_IDX: Index interrupt
* @arg TIM_IT_DIR: Direction change interrupt
* @arg TIM_IT_IERR: Index error interrupt
* @arg TIM_IT_TERR: Transition error interrupt
* @retval The state of TIM_IT (SET or RESET).
*/
#define __HAL_TIM_GET_IT_SOURCE(__HANDLE__, __INTERRUPT__) ((((__HANDLE__)->Instance->DIER & (__INTERRUPT__)) \
== (__INTERRUPT__)) ? SET : RESET)
/** @brief Clear the TIM interrupt pending bits.
* @param __HANDLE__ TIM handle
* @param __INTERRUPT__ specifies the interrupt pending bit to clear.
* This parameter can be one of the following values:
* @arg TIM_IT_UPDATE: Update interrupt
* @arg TIM_IT_CC1: Capture/Compare 1 interrupt
* @arg TIM_IT_CC2: Capture/Compare 2 interrupt
* @arg TIM_IT_CC3: Capture/Compare 3 interrupt
* @arg TIM_IT_CC4: Capture/Compare 4 interrupt
* @arg TIM_IT_COM: Commutation interrupt
* @arg TIM_IT_TRIGGER: Trigger interrupt
* @arg TIM_IT_BREAK: Break interrupt
* @arg TIM_IT_IDX: Index interrupt
* @arg TIM_IT_DIR: Direction change interrupt
* @arg TIM_IT_IERR: Index error interrupt
* @arg TIM_IT_TERR: Transition error interrupt
* @retval None
*/
#define __HAL_TIM_CLEAR_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->SR = ~(__INTERRUPT__))
/**
* @brief Force a continuous copy of the update interrupt flag (UIF) into the timer counter register (bit 31).
* @note This allows both the counter value and a potential roll-over condition signalled by the UIFCPY flag to be read
* in an atomic way.
* @param __HANDLE__ TIM handle.
* @retval None
mode.
*/
#define __HAL_TIM_UIFREMAP_ENABLE(__HANDLE__) (((__HANDLE__)->Instance->CR1 |= TIM_CR1_UIFREMAP))
/**
* @brief Disable update interrupt flag (UIF) remapping.
* @param __HANDLE__ TIM handle.
* @retval None
mode.
*/
#define __HAL_TIM_UIFREMAP_DISABLE(__HANDLE__) (((__HANDLE__)->Instance->CR1 &= ~TIM_CR1_UIFREMAP))
/**
* @brief Get update interrupt flag (UIF) copy status.
* @param __COUNTER__ Counter value.
* @retval The state of UIFCPY (TRUE or FALSE).
mode.
*/
#define __HAL_TIM_GET_UIFCPY(__COUNTER__) (((__COUNTER__) & (TIM_CNT_UIFCPY)) == (TIM_CNT_UIFCPY))
/**
* @brief Indicates whether or not the TIM Counter is used as downcounter.
* @param __HANDLE__ TIM handle.
* @retval False (Counter used as upcounter) or True (Counter used as downcounter)
* @note This macro is particularly useful to get the counting mode when the timer operates in Center-aligned mode
* or Encoder mode.
*/
#define __HAL_TIM_IS_TIM_COUNTING_DOWN(__HANDLE__) (((__HANDLE__)->Instance->CR1 &(TIM_CR1_DIR)) == (TIM_CR1_DIR))
/**
* @brief Set the TIM Prescaler on runtime.
* @param __HANDLE__ TIM handle.
* @param __PRESC__ specifies the Prescaler new value.
* @retval None
*/
#define __HAL_TIM_SET_PRESCALER(__HANDLE__, __PRESC__) ((__HANDLE__)->Instance->PSC = (__PRESC__))
/**
* @brief Set the TIM Counter Register value on runtime.
* Note Please check if the bit 31 of CNT register is used as UIF copy or not, this may affect the counter range in
* case of 32 bits counter TIM instance.
* Bit 31 of CNT can be enabled/disabled using __HAL_TIM_UIFREMAP_ENABLE()/__HAL_TIM_UIFREMAP_DISABLE() macros.
* @param __HANDLE__ TIM handle.
* @param __COUNTER__ specifies the Counter register new value.
* @retval None
*/
#define __HAL_TIM_SET_COUNTER(__HANDLE__, __COUNTER__) ((__HANDLE__)->Instance->CNT = (__COUNTER__))
/**
* @brief Get the TIM Counter Register value on runtime.
* @param __HANDLE__ TIM handle.
* @retval 16-bit or 32-bit value of the timer counter register (TIMx_CNT)
*/
#define __HAL_TIM_GET_COUNTER(__HANDLE__) ((__HANDLE__)->Instance->CNT)
/**
* @brief Set the TIM Autoreload Register value on runtime without calling another time any Init function.
* @param __HANDLE__ TIM handle.
* @param __AUTORELOAD__ specifies the Counter register new value.
* @retval None
*/
#define __HAL_TIM_SET_AUTORELOAD(__HANDLE__, __AUTORELOAD__) \
do{ \
(__HANDLE__)->Instance->ARR = (__AUTORELOAD__); \
(__HANDLE__)->Init.Period = (__AUTORELOAD__); \
} while(0)
/**
* @brief Get the TIM Autoreload Register value on runtime.
* @param __HANDLE__ TIM handle.
* @retval 16-bit or 32-bit value of the timer auto-reload register(TIMx_ARR)
*/
#define __HAL_TIM_GET_AUTORELOAD(__HANDLE__) ((__HANDLE__)->Instance->ARR)
/**
* @brief Set the TIM Clock Division value on runtime without calling another time any Init function.
* @param __HANDLE__ TIM handle.
* @param __CKD__ specifies the clock division value.
* This parameter can be one of the following value:
* @arg TIM_CLOCKDIVISION_DIV1: tDTS=tCK_INT
* @arg TIM_CLOCKDIVISION_DIV2: tDTS=2*tCK_INT
* @arg TIM_CLOCKDIVISION_DIV4: tDTS=4*tCK_INT
* @retval None
*/
#define __HAL_TIM_SET_CLOCKDIVISION(__HANDLE__, __CKD__) \
do{ \
(__HANDLE__)->Instance->CR1 &= (~TIM_CR1_CKD); \
(__HANDLE__)->Instance->CR1 |= (__CKD__); \
(__HANDLE__)->Init.ClockDivision = (__CKD__); \
} while(0)
/**
* @brief Get the TIM Clock Division value on runtime.
* @param __HANDLE__ TIM handle.
* @retval The clock division can be one of the following values:
* @arg TIM_CLOCKDIVISION_DIV1: tDTS=tCK_INT
* @arg TIM_CLOCKDIVISION_DIV2: tDTS=2*tCK_INT
* @arg TIM_CLOCKDIVISION_DIV4: tDTS=4*tCK_INT
*/
#define __HAL_TIM_GET_CLOCKDIVISION(__HANDLE__) ((__HANDLE__)->Instance->CR1 & TIM_CR1_CKD)
/**
* @brief Set the TIM Input Capture prescaler on runtime without calling another time HAL_TIM_IC_ConfigChannel()
* function.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @param __ICPSC__ specifies the Input Capture4 prescaler new value.
* This parameter can be one of the following values:
* @arg TIM_ICPSC_DIV1: no prescaler
* @arg TIM_ICPSC_DIV2: capture is done once every 2 events
* @arg TIM_ICPSC_DIV4: capture is done once every 4 events
* @arg TIM_ICPSC_DIV8: capture is done once every 8 events
* @retval None
*/
#define __HAL_TIM_SET_ICPRESCALER(__HANDLE__, __CHANNEL__, __ICPSC__) \
do{ \
TIM_RESET_ICPRESCALERVALUE((__HANDLE__), (__CHANNEL__)); \
TIM_SET_ICPRESCALERVALUE((__HANDLE__), (__CHANNEL__), (__ICPSC__)); \
} while(0)
/**
* @brief Get the TIM Input Capture prescaler on runtime.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: get input capture 1 prescaler value
* @arg TIM_CHANNEL_2: get input capture 2 prescaler value
* @arg TIM_CHANNEL_3: get input capture 3 prescaler value
* @arg TIM_CHANNEL_4: get input capture 4 prescaler value
* @retval The input capture prescaler can be one of the following values:
* @arg TIM_ICPSC_DIV1: no prescaler
* @arg TIM_ICPSC_DIV2: capture is done once every 2 events
* @arg TIM_ICPSC_DIV4: capture is done once every 4 events
* @arg TIM_ICPSC_DIV8: capture is done once every 8 events
*/
#define __HAL_TIM_GET_ICPRESCALER(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCMR1 & TIM_CCMR1_IC1PSC) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? (((__HANDLE__)->Instance->CCMR1 & TIM_CCMR1_IC2PSC) >> 8U) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCMR2 & TIM_CCMR2_IC3PSC) :\
(((__HANDLE__)->Instance->CCMR2 & TIM_CCMR2_IC4PSC)) >> 8U)
/**
* @brief Set the TIM Capture Compare Register value on runtime without calling another time ConfigChannel function.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @param __COMPARE__ specifies the Capture Compare register new value.
* @retval None
*/
#define __HAL_TIM_SET_COMPARE(__HANDLE__, __CHANNEL__, __COMPARE__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCR1 = (__COMPARE__)) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCR2 = (__COMPARE__)) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCR3 = (__COMPARE__)) :\
((__CHANNEL__) == TIM_CHANNEL_4) ? ((__HANDLE__)->Instance->CCR4 = (__COMPARE__)) :\
((__CHANNEL__) == TIM_CHANNEL_5) ? ((__HANDLE__)->Instance->CCR5 = (__COMPARE__)) :\
((__HANDLE__)->Instance->CCR6 = (__COMPARE__)))
/**
* @brief Get the TIM Capture Compare Register value on runtime.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channel associated with the capture compare register
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: get capture/compare 1 register value
* @arg TIM_CHANNEL_2: get capture/compare 2 register value
* @arg TIM_CHANNEL_3: get capture/compare 3 register value
* @arg TIM_CHANNEL_4: get capture/compare 4 register value
* @arg TIM_CHANNEL_5: get capture/compare 5 register value
* @arg TIM_CHANNEL_6: get capture/compare 6 register value
* @retval 16-bit or 32-bit value of the capture/compare register (TIMx_CCRy)
*/
#define __HAL_TIM_GET_COMPARE(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCR1) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCR2) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCR3) :\
((__CHANNEL__) == TIM_CHANNEL_4) ? ((__HANDLE__)->Instance->CCR4) :\
((__CHANNEL__) == TIM_CHANNEL_5) ? ((__HANDLE__)->Instance->CCR5) :\
((__HANDLE__)->Instance->CCR6))
/**
* @brief Set the TIM Output compare preload.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval None
*/
#define __HAL_TIM_ENABLE_OCxPRELOAD(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCMR1 |= TIM_CCMR1_OC1PE) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCMR1 |= TIM_CCMR1_OC2PE) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCMR2 |= TIM_CCMR2_OC3PE) :\
((__CHANNEL__) == TIM_CHANNEL_4) ? ((__HANDLE__)->Instance->CCMR2 |= TIM_CCMR2_OC4PE) :\
((__CHANNEL__) == TIM_CHANNEL_5) ? ((__HANDLE__)->Instance->CCMR3 |= TIM_CCMR3_OC5PE) :\
((__HANDLE__)->Instance->CCMR3 |= TIM_CCMR3_OC6PE))
/**
* @brief Reset the TIM Output compare preload.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @retval None
*/
#define __HAL_TIM_DISABLE_OCxPRELOAD(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCMR1 &= ~TIM_CCMR1_OC1PE) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCMR1 &= ~TIM_CCMR1_OC2PE) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCMR2 &= ~TIM_CCMR2_OC3PE) :\
((__CHANNEL__) == TIM_CHANNEL_4) ? ((__HANDLE__)->Instance->CCMR2 &= ~TIM_CCMR2_OC4PE) :\
((__CHANNEL__) == TIM_CHANNEL_5) ? ((__HANDLE__)->Instance->CCMR3 &= ~TIM_CCMR3_OC5PE) :\
((__HANDLE__)->Instance->CCMR3 &= ~TIM_CCMR3_OC6PE))
/**
* @brief Enable fast mode for a given channel.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @note When fast mode is enabled an active edge on the trigger input acts
* like a compare match on CCx output. Delay to sample the trigger
* input and to activate CCx output is reduced to 3 clock cycles.
* @note Fast mode acts only if the channel is configured in PWM1 or PWM2 mode.
* @retval None
*/
#define __HAL_TIM_ENABLE_OCxFAST(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCMR1 |= TIM_CCMR1_OC1FE) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCMR1 |= TIM_CCMR1_OC2FE) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCMR2 |= TIM_CCMR2_OC3FE) :\
((__CHANNEL__) == TIM_CHANNEL_4) ? ((__HANDLE__)->Instance->CCMR2 |= TIM_CCMR2_OC4FE) :\
((__CHANNEL__) == TIM_CHANNEL_5) ? ((__HANDLE__)->Instance->CCMR3 |= TIM_CCMR3_OC5FE) :\
((__HANDLE__)->Instance->CCMR3 |= TIM_CCMR3_OC6FE))
/**
* @brief Disable fast mode for a given channel.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @arg TIM_CHANNEL_5: TIM Channel 5 selected
* @arg TIM_CHANNEL_6: TIM Channel 6 selected
* @note When fast mode is disabled CCx output behaves normally depending
* on counter and CCRx values even when the trigger is ON. The minimum
* delay to activate CCx output when an active edge occurs on the
* trigger input is 5 clock cycles.
* @retval None
*/
#define __HAL_TIM_DISABLE_OCxFAST(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCMR1 &= ~TIM_CCMR1_OC1FE) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCMR1 &= ~TIM_CCMR1_OC2FE) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCMR2 &= ~TIM_CCMR2_OC3FE) :\
((__CHANNEL__) == TIM_CHANNEL_4) ? ((__HANDLE__)->Instance->CCMR2 &= ~TIM_CCMR2_OC4FE) :\
((__CHANNEL__) == TIM_CHANNEL_5) ? ((__HANDLE__)->Instance->CCMR3 &= ~TIM_CCMR3_OC5FE) :\
((__HANDLE__)->Instance->CCMR3 &= ~TIM_CCMR3_OC6FE))
/**
* @brief Set the Update Request Source (URS) bit of the TIMx_CR1 register.
* @param __HANDLE__ TIM handle.
* @note When the URS bit of the TIMx_CR1 register is set, only counter
* overflow/underflow generates an update interrupt or DMA request (if
* enabled)
* @retval None
*/
#define __HAL_TIM_URS_ENABLE(__HANDLE__) ((__HANDLE__)->Instance->CR1|= TIM_CR1_URS)
/**
* @brief Reset the Update Request Source (URS) bit of the TIMx_CR1 register.
* @param __HANDLE__ TIM handle.
* @note When the URS bit of the TIMx_CR1 register is reset, any of the
* following events generate an update interrupt or DMA request (if
* enabled):
* _ Counter overflow underflow
* _ Setting the UG bit
* _ Update generation through the slave mode controller
* @retval None
*/
#define __HAL_TIM_URS_DISABLE(__HANDLE__) ((__HANDLE__)->Instance->CR1&=~TIM_CR1_URS)
/**
* @brief Set the TIM Capture x input polarity on runtime.
* @param __HANDLE__ TIM handle.
* @param __CHANNEL__ TIM Channels to be configured.
* This parameter can be one of the following values:
* @arg TIM_CHANNEL_1: TIM Channel 1 selected
* @arg TIM_CHANNEL_2: TIM Channel 2 selected
* @arg TIM_CHANNEL_3: TIM Channel 3 selected
* @arg TIM_CHANNEL_4: TIM Channel 4 selected
* @param __POLARITY__ Polarity for TIx source
* @arg TIM_INPUTCHANNELPOLARITY_RISING: Rising Edge
* @arg TIM_INPUTCHANNELPOLARITY_FALLING: Falling Edge
* @arg TIM_INPUTCHANNELPOLARITY_BOTHEDGE: Rising and Falling Edge
* @retval None
*/
#define __HAL_TIM_SET_CAPTUREPOLARITY(__HANDLE__, __CHANNEL__, __POLARITY__) \
do{ \
TIM_RESET_CAPTUREPOLARITY((__HANDLE__), (__CHANNEL__)); \
TIM_SET_CAPTUREPOLARITY((__HANDLE__), (__CHANNEL__), (__POLARITY__)); \
}while(0)
/** @brief Select the Capture/compare DMA request source.
* @param __HANDLE__ specifies the TIM Handle.
* @param __CCDMA__ specifies Capture/compare DMA request source
* This parameter can be one of the following values:
* @arg TIM_CCDMAREQUEST_CC: CCx DMA request generated on Capture/Compare event
* @arg TIM_CCDMAREQUEST_UPDATE: CCx DMA request generated on Update event
* @retval None
*/
#define __HAL_TIM_SELECT_CCDMAREQUEST(__HANDLE__, __CCDMA__) \
MODIFY_REG((__HANDLE__)->Instance->CR2, TIM_CR2_CCDS, (__CCDMA__))
/**
* @}
*/
/* End of exported macros ----------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup TIM_Private_Constants TIM Private Constants
* @{
*/
/* The counter of a timer instance is disabled only if all the CCx and CCxN
channels have been disabled */
#define TIM_CCER_CCxE_MASK ((uint32_t)(TIM_CCER_CC1E | TIM_CCER_CC2E | TIM_CCER_CC3E | TIM_CCER_CC4E))
#define TIM_CCER_CCxNE_MASK ((uint32_t)(TIM_CCER_CC1NE | TIM_CCER_CC2NE | TIM_CCER_CC3NE | TIM_CCER_CC4NE))
/**
* @}
*/
/* End of private constants --------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup TIM_Private_Macros TIM Private Macros
* @{
*/
#if defined(COMP5) && defined(COMP6) && defined(COMP7)
#define IS_TIM_CLEARINPUT_SOURCE(__MODE__) (((__MODE__) == TIM_CLEARINPUTSOURCE_ETR) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP1) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP2) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP3) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP4) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP5) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP6) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP7) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_NONE))
#else /* COMP5 && COMP6 && COMP7 */
#define IS_TIM_CLEARINPUT_SOURCE(__MODE__) (((__MODE__) == TIM_CLEARINPUTSOURCE_ETR) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP1) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP2) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP3) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_COMP4) || \
((__MODE__) == TIM_CLEARINPUTSOURCE_NONE))
#endif /* COMP5 && COMP6 && COMP7 */
#define IS_TIM_DMA_BASE(__BASE__) (((__BASE__) == TIM_DMABASE_CR1) || \
((__BASE__) == TIM_DMABASE_CR2) || \
((__BASE__) == TIM_DMABASE_SMCR) || \
((__BASE__) == TIM_DMABASE_DIER) || \
((__BASE__) == TIM_DMABASE_SR) || \
((__BASE__) == TIM_DMABASE_EGR) || \
((__BASE__) == TIM_DMABASE_CCMR1) || \
((__BASE__) == TIM_DMABASE_CCMR2) || \
((__BASE__) == TIM_DMABASE_CCER) || \
((__BASE__) == TIM_DMABASE_CNT) || \
((__BASE__) == TIM_DMABASE_PSC) || \
((__BASE__) == TIM_DMABASE_ARR) || \
((__BASE__) == TIM_DMABASE_RCR) || \
((__BASE__) == TIM_DMABASE_CCR1) || \
((__BASE__) == TIM_DMABASE_CCR2) || \
((__BASE__) == TIM_DMABASE_CCR3) || \
((__BASE__) == TIM_DMABASE_CCR4) || \
((__BASE__) == TIM_DMABASE_BDTR) || \
((__BASE__) == TIM_DMABASE_CCMR3) || \
((__BASE__) == TIM_DMABASE_CCR5) || \
((__BASE__) == TIM_DMABASE_CCR6) || \
((__BASE__) == TIM_DMABASE_AF1) || \
((__BASE__) == TIM_DMABASE_AF2) || \
((__BASE__) == TIM_DMABASE_TISEL) || \
((__BASE__) == TIM_DMABASE_DTR2) || \
((__BASE__) == TIM_DMABASE_ECR) || \
((__BASE__) == TIM_DMABASE_OR))
#define IS_TIM_EVENT_SOURCE(__SOURCE__) ((((__SOURCE__) & 0xFFFFFE00U) == 0x00000000U) && ((__SOURCE__) != 0x00000000U))
#define IS_TIM_COUNTER_MODE(__MODE__) (((__MODE__) == TIM_COUNTERMODE_UP) || \
((__MODE__) == TIM_COUNTERMODE_DOWN) || \
((__MODE__) == TIM_COUNTERMODE_CENTERALIGNED1) || \
((__MODE__) == TIM_COUNTERMODE_CENTERALIGNED2) || \
((__MODE__) == TIM_COUNTERMODE_CENTERALIGNED3))
#define IS_TIM_UIFREMAP_MODE(__MODE__) (((__MODE__) == TIM_UIFREMAP_DISABLE) || \
((__MODE__) == TIM_UIFREMAP_ENABLE))
#define IS_TIM_CLOCKDIVISION_DIV(__DIV__) (((__DIV__) == TIM_CLOCKDIVISION_DIV1) || \
((__DIV__) == TIM_CLOCKDIVISION_DIV2) || \
((__DIV__) == TIM_CLOCKDIVISION_DIV4))
#define IS_TIM_AUTORELOAD_PRELOAD(PRELOAD) (((PRELOAD) == TIM_AUTORELOAD_PRELOAD_DISABLE) || \
((PRELOAD) == TIM_AUTORELOAD_PRELOAD_ENABLE))
#define IS_TIM_FAST_STATE(__STATE__) (((__STATE__) == TIM_OCFAST_DISABLE) || \
((__STATE__) == TIM_OCFAST_ENABLE))
#define IS_TIM_OC_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_OCPOLARITY_HIGH) || \
((__POLARITY__) == TIM_OCPOLARITY_LOW))
#define IS_TIM_OCN_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_OCNPOLARITY_HIGH) || \
((__POLARITY__) == TIM_OCNPOLARITY_LOW))
#define IS_TIM_OCIDLE_STATE(__STATE__) (((__STATE__) == TIM_OCIDLESTATE_SET) || \
((__STATE__) == TIM_OCIDLESTATE_RESET))
#define IS_TIM_OCNIDLE_STATE(__STATE__) (((__STATE__) == TIM_OCNIDLESTATE_SET) || \
((__STATE__) == TIM_OCNIDLESTATE_RESET))
#define IS_TIM_ENCODERINPUT_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_ENCODERINPUTPOLARITY_RISING) || \
((__POLARITY__) == TIM_ENCODERINPUTPOLARITY_FALLING))
#define IS_TIM_IC_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_ICPOLARITY_RISING) || \
((__POLARITY__) == TIM_ICPOLARITY_FALLING) || \
((__POLARITY__) == TIM_ICPOLARITY_BOTHEDGE))
#define IS_TIM_IC_SELECTION(__SELECTION__) (((__SELECTION__) == TIM_ICSELECTION_DIRECTTI) || \
((__SELECTION__) == TIM_ICSELECTION_INDIRECTTI) || \
((__SELECTION__) == TIM_ICSELECTION_TRC))
#define IS_TIM_IC_PRESCALER(__PRESCALER__) (((__PRESCALER__) == TIM_ICPSC_DIV1) || \
((__PRESCALER__) == TIM_ICPSC_DIV2) || \
((__PRESCALER__) == TIM_ICPSC_DIV4) || \
((__PRESCALER__) == TIM_ICPSC_DIV8))
#define IS_TIM_CCX_CHANNEL(__INSTANCE__, __CHANNEL__) (IS_TIM_CCX_INSTANCE(__INSTANCE__, __CHANNEL__) && \
((__CHANNEL__) != (TIM_CHANNEL_5)) && \
((__CHANNEL__) != (TIM_CHANNEL_6)))
#define IS_TIM_OPM_MODE(__MODE__) (((__MODE__) == TIM_OPMODE_SINGLE) || \
((__MODE__) == TIM_OPMODE_REPETITIVE))
#define IS_TIM_ENCODER_MODE(__MODE__) (((__MODE__) == TIM_ENCODERMODE_TI1) || \
((__MODE__) == TIM_ENCODERMODE_TI2) || \
((__MODE__) == TIM_ENCODERMODE_TI12) || \
((__MODE__) == TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X2) || \
((__MODE__) == TIM_ENCODERMODE_CLOCKPLUSDIRECTION_X1) || \
((__MODE__) == TIM_ENCODERMODE_DIRECTIONALCLOCK_X2) || \
((__MODE__) == TIM_ENCODERMODE_DIRECTIONALCLOCK_X1_TI12) || \
((__MODE__) == TIM_ENCODERMODE_X1_TI1) || \
((__MODE__) == TIM_ENCODERMODE_X1_TI2))
#define IS_TIM_DMA_SOURCE(__SOURCE__) ((((__SOURCE__) & 0xFFFF80FFU) == 0x00000000U) && ((__SOURCE__) != 0x00000000U))
#define IS_TIM_CHANNELS(__CHANNEL__) (((__CHANNEL__) == TIM_CHANNEL_1) || \
((__CHANNEL__) == TIM_CHANNEL_2) || \
((__CHANNEL__) == TIM_CHANNEL_3) || \
((__CHANNEL__) == TIM_CHANNEL_4) || \
((__CHANNEL__) == TIM_CHANNEL_5) || \
((__CHANNEL__) == TIM_CHANNEL_6) || \
((__CHANNEL__) == TIM_CHANNEL_ALL))
#define IS_TIM_OPM_CHANNELS(__CHANNEL__) (((__CHANNEL__) == TIM_CHANNEL_1) || \
((__CHANNEL__) == TIM_CHANNEL_2))
#define IS_TIM_PERIOD(__HANDLE__, __PERIOD__) ((IS_TIM_32B_COUNTER_INSTANCE(((__HANDLE__)->Instance)) == 0U) ? \
(((__PERIOD__) > 0U) && ((__PERIOD__) <= 0x0000FFFFU)) : \
((__PERIOD__) > 0U))
#define IS_TIM_COMPLEMENTARY_CHANNELS(__CHANNEL__) (((__CHANNEL__) == TIM_CHANNEL_1) || \
((__CHANNEL__) == TIM_CHANNEL_2) || \
((__CHANNEL__) == TIM_CHANNEL_3) || \
((__CHANNEL__) == TIM_CHANNEL_4))
#if defined(TIM5) && defined(TIM20)
#define IS_TIM_CLOCKSOURCE(__CLOCK__) (((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))
#elif defined(TIM5)
#define IS_TIM_CLOCKSOURCE(__CLOCK__) (((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))
#elif defined(TIM20)
#define IS_TIM_CLOCKSOURCE(__CLOCK__) (((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))
#else
#define IS_TIM_CLOCKSOURCE(__CLOCK__) (((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))
#endif /* TIM5 && TIM20 */
#define IS_TIM_CLOCKPOLARITY(__POLARITY__) (((__POLARITY__) == TIM_CLOCKPOLARITY_INVERTED) || \
((__POLARITY__) == TIM_CLOCKPOLARITY_NONINVERTED) || \
((__POLARITY__) == TIM_CLOCKPOLARITY_RISING) || \
((__POLARITY__) == TIM_CLOCKPOLARITY_FALLING) || \
((__POLARITY__) == TIM_CLOCKPOLARITY_BOTHEDGE))
#define IS_TIM_CLOCKPRESCALER(__PRESCALER__) (((__PRESCALER__) == TIM_CLOCKPRESCALER_DIV1) || \
((__PRESCALER__) == TIM_CLOCKPRESCALER_DIV2) || \
((__PRESCALER__) == TIM_CLOCKPRESCALER_DIV4) || \
((__PRESCALER__) == TIM_CLOCKPRESCALER_DIV8))
#define IS_TIM_CLOCKFILTER(__ICFILTER__) ((__ICFILTER__) <= 0xFU)
#define IS_TIM_CLEARINPUT_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_CLEARINPUTPOLARITY_INVERTED) || \
((__POLARITY__) == TIM_CLEARINPUTPOLARITY_NONINVERTED))
#define IS_TIM_CLEARINPUT_PRESCALER(__PRESCALER__) (((__PRESCALER__) == TIM_CLEARINPUTPRESCALER_DIV1) || \
((__PRESCALER__) == TIM_CLEARINPUTPRESCALER_DIV2) || \
((__PRESCALER__) == TIM_CLEARINPUTPRESCALER_DIV4) || \
((__PRESCALER__) == TIM_CLEARINPUTPRESCALER_DIV8))
#define IS_TIM_CLEARINPUT_FILTER(__ICFILTER__) ((__ICFILTER__) <= 0xFU)
#define IS_TIM_OSSR_STATE(__STATE__) (((__STATE__) == TIM_OSSR_ENABLE) || \
((__STATE__) == TIM_OSSR_DISABLE))
#define IS_TIM_OSSI_STATE(__STATE__) (((__STATE__) == TIM_OSSI_ENABLE) || \
((__STATE__) == TIM_OSSI_DISABLE))
#define IS_TIM_LOCK_LEVEL(__LEVEL__) (((__LEVEL__) == TIM_LOCKLEVEL_OFF) || \
((__LEVEL__) == TIM_LOCKLEVEL_1) || \
((__LEVEL__) == TIM_LOCKLEVEL_2) || \
((__LEVEL__) == TIM_LOCKLEVEL_3))
#define IS_TIM_BREAK_FILTER(__BRKFILTER__) ((__BRKFILTER__) <= 0xFUL)
#define IS_TIM_BREAK_STATE(__STATE__) (((__STATE__) == TIM_BREAK_ENABLE) || \
((__STATE__) == TIM_BREAK_DISABLE))
#define IS_TIM_BREAK_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_BREAKPOLARITY_LOW) || \
((__POLARITY__) == TIM_BREAKPOLARITY_HIGH))
#define IS_TIM_BREAK_AFMODE(__AFMODE__) (((__AFMODE__) == TIM_BREAK_AFMODE_INPUT) || \
((__AFMODE__) == TIM_BREAK_AFMODE_BIDIRECTIONAL))
#define IS_TIM_BREAK2_STATE(__STATE__) (((__STATE__) == TIM_BREAK2_ENABLE) || \
((__STATE__) == TIM_BREAK2_DISABLE))
#define IS_TIM_BREAK2_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_BREAK2POLARITY_LOW) || \
((__POLARITY__) == TIM_BREAK2POLARITY_HIGH))
#define IS_TIM_BREAK2_AFMODE(__AFMODE__) (((__AFMODE__) == TIM_BREAK2_AFMODE_INPUT) || \
((__AFMODE__) == TIM_BREAK2_AFMODE_BIDIRECTIONAL))
#define IS_TIM_AUTOMATIC_OUTPUT_STATE(__STATE__) (((__STATE__) == TIM_AUTOMATICOUTPUT_ENABLE) || \
((__STATE__) == TIM_AUTOMATICOUTPUT_DISABLE))
#define IS_TIM_GROUPCH5(__OCREF__) ((((__OCREF__) & 0x1FFFFFFFU) == 0x00000000U))
#define IS_TIM_TRGO_SOURCE(__SOURCE__) (((__SOURCE__) == TIM_TRGO_RESET) || \
((__SOURCE__) == TIM_TRGO_ENABLE) || \
((__SOURCE__) == TIM_TRGO_UPDATE) || \
((__SOURCE__) == TIM_TRGO_OC1) || \
((__SOURCE__) == TIM_TRGO_OC1REF) || \
((__SOURCE__) == TIM_TRGO_OC2REF) || \
((__SOURCE__) == TIM_TRGO_OC3REF) || \
((__SOURCE__) == TIM_TRGO_OC4REF) || \
((__SOURCE__) == TIM_TRGO_ENCODER_CLK))
#define IS_TIM_TRGO2_SOURCE(__SOURCE__) (((__SOURCE__) == TIM_TRGO2_RESET) || \
((__SOURCE__) == TIM_TRGO2_ENABLE) || \
((__SOURCE__) == TIM_TRGO2_UPDATE) || \
((__SOURCE__) == TIM_TRGO2_OC1) || \
((__SOURCE__) == TIM_TRGO2_OC1REF) || \
((__SOURCE__) == TIM_TRGO2_OC2REF) || \
((__SOURCE__) == TIM_TRGO2_OC3REF) || \
((__SOURCE__) == TIM_TRGO2_OC3REF) || \
((__SOURCE__) == TIM_TRGO2_OC4REF) || \
((__SOURCE__) == TIM_TRGO2_OC5REF) || \
((__SOURCE__) == TIM_TRGO2_OC6REF) || \
((__SOURCE__) == TIM_TRGO2_OC4REF_RISINGFALLING) || \
((__SOURCE__) == TIM_TRGO2_OC6REF_RISINGFALLING) || \
((__SOURCE__) == TIM_TRGO2_OC4REF_RISING_OC6REF_RISING) || \
((__SOURCE__) == TIM_TRGO2_OC4REF_RISING_OC6REF_FALLING) || \
((__SOURCE__) == TIM_TRGO2_OC5REF_RISING_OC6REF_RISING) || \
((__SOURCE__) == TIM_TRGO2_OC5REF_RISING_OC6REF_FALLING))
#define IS_TIM_MSM_STATE(__STATE__) (((__STATE__) == TIM_MASTERSLAVEMODE_ENABLE) || \
((__STATE__) == TIM_MASTERSLAVEMODE_DISABLE))
#define IS_TIM_SLAVE_MODE(__MODE__) (((__MODE__) == TIM_SLAVEMODE_DISABLE) || \
((__MODE__) == TIM_SLAVEMODE_RESET) || \
((__MODE__) == TIM_SLAVEMODE_GATED) || \
((__MODE__) == TIM_SLAVEMODE_TRIGGER) || \
((__MODE__) == TIM_SLAVEMODE_EXTERNAL1) || \
((__MODE__) == TIM_SLAVEMODE_COMBINED_RESETTRIGGER) || \
((__MODE__) == TIM_SLAVEMODE_COMBINED_GATEDRESET))
#define IS_TIM_PWM_MODE(__MODE__) (((__MODE__) == TIM_OCMODE_PWM1) || \
((__MODE__) == TIM_OCMODE_PWM2) || \
((__MODE__) == TIM_OCMODE_COMBINED_PWM1) || \
((__MODE__) == TIM_OCMODE_COMBINED_PWM2) || \
((__MODE__) == TIM_OCMODE_ASYMMETRIC_PWM1) || \
((__MODE__) == TIM_OCMODE_ASYMMETRIC_PWM2))
#define IS_TIM_OC_MODE(__MODE__) (((__MODE__) == TIM_OCMODE_TIMING) || \
((__MODE__) == TIM_OCMODE_ACTIVE) || \
((__MODE__) == TIM_OCMODE_INACTIVE) || \
((__MODE__) == TIM_OCMODE_TOGGLE) || \
((__MODE__) == TIM_OCMODE_FORCED_ACTIVE) || \
((__MODE__) == TIM_OCMODE_FORCED_INACTIVE) || \
((__MODE__) == TIM_OCMODE_RETRIGERRABLE_OPM1) || \
((__MODE__) == TIM_OCMODE_RETRIGERRABLE_OPM2) || \
((__MODE__) == TIM_OCMODE_DIRECTION_OUTPUT) || \
((__MODE__) == TIM_OCMODE_PULSE_ON_COMPARE))
#define IS_TIM_TRIGGERPOLARITY(__POLARITY__) (((__POLARITY__) == TIM_TRIGGERPOLARITY_INVERTED ) || \
((__POLARITY__) == TIM_TRIGGERPOLARITY_NONINVERTED) || \
((__POLARITY__) == TIM_TRIGGERPOLARITY_RISING ) || \
((__POLARITY__) == TIM_TRIGGERPOLARITY_FALLING ) || \
((__POLARITY__) == TIM_TRIGGERPOLARITY_BOTHEDGE ))
#define IS_TIM_TRIGGERPRESCALER(__PRESCALER__) (((__PRESCALER__) == TIM_TRIGGERPRESCALER_DIV1) || \
((__PRESCALER__) == TIM_TRIGGERPRESCALER_DIV2) || \
((__PRESCALER__) == TIM_TRIGGERPRESCALER_DIV4) || \
((__PRESCALER__) == TIM_TRIGGERPRESCALER_DIV8))
#define IS_TIM_TRIGGERFILTER(__ICFILTER__) ((__ICFILTER__) <= 0xFU)
#define IS_TIM_TI1SELECTION(__TI1SELECTION__) (((__TI1SELECTION__) == TIM_TI1SELECTION_CH1) || \
((__TI1SELECTION__) == TIM_TI1SELECTION_XORCOMBINATION))
#define IS_TIM_DMA_LENGTH(__LENGTH__) (((__LENGTH__) == TIM_DMABURSTLENGTH_1TRANSFER) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_2TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_3TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_4TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_5TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_6TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_7TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_8TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_9TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_10TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_11TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_12TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_13TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_14TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_15TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_16TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_17TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_18TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_19TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_20TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_21TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_22TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_23TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_24TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_25TRANSFERS) || \
((__LENGTH__) == TIM_DMABURSTLENGTH_26TRANSFERS))
#define IS_TIM_DMA_DATA_LENGTH(LENGTH) (((LENGTH) >= 0x1U) && ((LENGTH) < 0x10000U))
#define IS_TIM_IC_FILTER(__ICFILTER__) ((__ICFILTER__) <= 0xFU)
#define IS_TIM_DEADTIME(__DEADTIME__) ((__DEADTIME__) <= 0xFFU)
#define IS_TIM_BREAK_SYSTEM(__CONFIG__) (((__CONFIG__) == TIM_BREAK_SYSTEM_ECC) || \
((__CONFIG__) == TIM_BREAK_SYSTEM_PVD) || \
((__CONFIG__) == TIM_BREAK_SYSTEM_SRAM_PARITY_ERROR) || \
((__CONFIG__) == TIM_BREAK_SYSTEM_LOCKUP))
#define IS_TIM_SLAVEMODE_TRIGGER_ENABLED(__TRIGGER__) (((__TRIGGER__) == TIM_SLAVEMODE_TRIGGER) || \
((__TRIGGER__) == TIM_SLAVEMODE_COMBINED_RESETTRIGGER))
#define TIM_SET_ICPRESCALERVALUE(__HANDLE__, __CHANNEL__, __ICPSC__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCMR1 |= (__ICPSC__)) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCMR1 |= ((__ICPSC__) << 8U)) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCMR2 |= (__ICPSC__)) :\
((__HANDLE__)->Instance->CCMR2 |= ((__ICPSC__) << 8U)))
#define TIM_RESET_ICPRESCALERVALUE(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCMR1 &= ~TIM_CCMR1_IC1PSC) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCMR1 &= ~TIM_CCMR1_IC2PSC) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCMR2 &= ~TIM_CCMR2_IC3PSC) :\
((__HANDLE__)->Instance->CCMR2 &= ~TIM_CCMR2_IC4PSC))
#define TIM_SET_CAPTUREPOLARITY(__HANDLE__, __CHANNEL__, __POLARITY__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCER |= (__POLARITY__)) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCER |= ((__POLARITY__) << 4U)) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCER |= ((__POLARITY__) << 8U)) :\
((__HANDLE__)->Instance->CCER |= (((__POLARITY__) << 12U))))
#define TIM_RESET_CAPTUREPOLARITY(__HANDLE__, __CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->Instance->CCER &= ~(TIM_CCER_CC1P | TIM_CCER_CC1NP)) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->Instance->CCER &= ~(TIM_CCER_CC2P | TIM_CCER_CC2NP)) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->Instance->CCER &= ~(TIM_CCER_CC3P | TIM_CCER_CC3NP)) :\
((__HANDLE__)->Instance->CCER &= ~(TIM_CCER_CC4P | TIM_CCER_CC4NP)))
#define TIM_CHANNEL_STATE_GET(__HANDLE__, __CHANNEL__)\
(((__CHANNEL__) == TIM_CHANNEL_1) ? (__HANDLE__)->ChannelState[0] :\
((__CHANNEL__) == TIM_CHANNEL_2) ? (__HANDLE__)->ChannelState[1] :\
((__CHANNEL__) == TIM_CHANNEL_3) ? (__HANDLE__)->ChannelState[2] :\
((__CHANNEL__) == TIM_CHANNEL_4) ? (__HANDLE__)->ChannelState[3] :\
((__CHANNEL__) == TIM_CHANNEL_5) ? (__HANDLE__)->ChannelState[4] :\
(__HANDLE__)->ChannelState[5])
#define TIM_CHANNEL_STATE_SET(__HANDLE__, __CHANNEL__, __CHANNEL_STATE__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->ChannelState[0] = (__CHANNEL_STATE__)) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->ChannelState[1] = (__CHANNEL_STATE__)) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->ChannelState[2] = (__CHANNEL_STATE__)) :\
((__CHANNEL__) == TIM_CHANNEL_4) ? ((__HANDLE__)->ChannelState[3] = (__CHANNEL_STATE__)) :\
((__CHANNEL__) == TIM_CHANNEL_5) ? ((__HANDLE__)->ChannelState[4] = (__CHANNEL_STATE__)) :\
((__HANDLE__)->ChannelState[5] = (__CHANNEL_STATE__)))
#define TIM_CHANNEL_STATE_SET_ALL(__HANDLE__, __CHANNEL_STATE__) do { \
(__HANDLE__)->ChannelState[0] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelState[1] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelState[2] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelState[3] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelState[4] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelState[5] = \
(__CHANNEL_STATE__); \
} while(0)
#define TIM_CHANNEL_N_STATE_GET(__HANDLE__, __CHANNEL__)\
(((__CHANNEL__) == TIM_CHANNEL_1) ? (__HANDLE__)->ChannelNState[0] :\
((__CHANNEL__) == TIM_CHANNEL_2) ? (__HANDLE__)->ChannelNState[1] :\
((__CHANNEL__) == TIM_CHANNEL_3) ? (__HANDLE__)->ChannelNState[2] :\
(__HANDLE__)->ChannelNState[3])
#define TIM_CHANNEL_N_STATE_SET(__HANDLE__, __CHANNEL__, __CHANNEL_STATE__) \
(((__CHANNEL__) == TIM_CHANNEL_1) ? ((__HANDLE__)->ChannelNState[0] = (__CHANNEL_STATE__)) :\
((__CHANNEL__) == TIM_CHANNEL_2) ? ((__HANDLE__)->ChannelNState[1] = (__CHANNEL_STATE__)) :\
((__CHANNEL__) == TIM_CHANNEL_3) ? ((__HANDLE__)->ChannelNState[2] = (__CHANNEL_STATE__)) :\
((__HANDLE__)->ChannelNState[3] = (__CHANNEL_STATE__)))
#define TIM_CHANNEL_N_STATE_SET_ALL(__HANDLE__, __CHANNEL_STATE__) do { \
(__HANDLE__)->ChannelNState[0] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelNState[1] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelNState[2] = \
(__CHANNEL_STATE__); \
(__HANDLE__)->ChannelNState[3] = \
(__CHANNEL_STATE__); \
} while(0)
/**
* @}
*/
/* End of private macros -----------------------------------------------------*/
/* Include TIM HAL Extended module */
#include "stm32g4xx_hal_tim_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup TIM_Exported_Functions TIM Exported Functions
* @{
*/
/** @addtogroup TIM_Exported_Functions_Group1 TIM Time Base functions
* @brief Time Base functions
* @{
*/
/* Time Base functions ********************************************************/
HAL_StatusTypeDef HAL_TIM_Base_Init(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIM_Base_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIM_Base_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIM_Base_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIM_Base_Start(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIM_Base_Stop(TIM_HandleTypeDef *htim);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIM_Base_Start_IT(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIM_Base_Stop_IT(TIM_HandleTypeDef *htim);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIM_Base_Start_DMA(TIM_HandleTypeDef *htim, const uint32_t *pData, uint16_t Length);
HAL_StatusTypeDef HAL_TIM_Base_Stop_DMA(TIM_HandleTypeDef *htim);
/**
* @}
*/
/** @addtogroup TIM_Exported_Functions_Group2 TIM Output Compare functions
* @brief TIM Output Compare functions
* @{
*/
/* Timer Output Compare functions *********************************************/
HAL_StatusTypeDef HAL_TIM_OC_Init(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIM_OC_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIM_OC_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIM_OC_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIM_OC_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_OC_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIM_OC_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_OC_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIM_OC_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length);
HAL_StatusTypeDef HAL_TIM_OC_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIM_Exported_Functions_Group3 TIM PWM functions
* @brief TIM PWM functions
* @{
*/
/* Timer PWM functions ********************************************************/
HAL_StatusTypeDef HAL_TIM_PWM_Init(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIM_PWM_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIM_PWM_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIM_PWM_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIM_PWM_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_PWM_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIM_PWM_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_PWM_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIM_PWM_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length);
HAL_StatusTypeDef HAL_TIM_PWM_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIM_Exported_Functions_Group4 TIM Input Capture functions
* @brief TIM Input Capture functions
* @{
*/
/* Timer Input Capture functions **********************************************/
HAL_StatusTypeDef HAL_TIM_IC_Init(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIM_IC_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIM_IC_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIM_IC_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIM_IC_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_IC_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIM_IC_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_IC_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIM_IC_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, uint32_t *pData, uint16_t Length);
HAL_StatusTypeDef HAL_TIM_IC_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIM_Exported_Functions_Group5 TIM One Pulse functions
* @brief TIM One Pulse functions
* @{
*/
/* Timer One Pulse functions **************************************************/
HAL_StatusTypeDef HAL_TIM_OnePulse_Init(TIM_HandleTypeDef *htim, uint32_t OnePulseMode);
HAL_StatusTypeDef HAL_TIM_OnePulse_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIM_OnePulse_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIM_OnePulse_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIM_OnePulse_Start(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
HAL_StatusTypeDef HAL_TIM_OnePulse_Stop(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIM_OnePulse_Start_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
HAL_StatusTypeDef HAL_TIM_OnePulse_Stop_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
/**
* @}
*/
/** @addtogroup TIM_Exported_Functions_Group6 TIM Encoder functions
* @brief TIM Encoder functions
* @{
*/
/* Timer Encoder functions ****************************************************/
HAL_StatusTypeDef HAL_TIM_Encoder_Init(TIM_HandleTypeDef *htim, const TIM_Encoder_InitTypeDef *sConfig);
HAL_StatusTypeDef HAL_TIM_Encoder_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIM_Encoder_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIM_Encoder_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIM_Encoder_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_Encoder_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIM_Encoder_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_Encoder_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIM_Encoder_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, uint32_t *pData1,
uint32_t *pData2, uint16_t Length);
HAL_StatusTypeDef HAL_TIM_Encoder_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIM_Exported_Functions_Group7 TIM IRQ handler management
* @brief IRQ handler management
* @{
*/
/* Interrupt Handler functions ***********************************************/
void HAL_TIM_IRQHandler(TIM_HandleTypeDef *htim);
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group8 TIM Peripheral Control functions
* @brief Peripheral Control functions
* @{
*/
/* Control functions *********************************************************/
HAL_StatusTypeDef HAL_TIM_OC_ConfigChannel(TIM_HandleTypeDef *htim, const TIM_OC_InitTypeDef *sConfig,
uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_PWM_ConfigChannel(TIM_HandleTypeDef *htim, const TIM_OC_InitTypeDef *sConfig,
uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_IC_ConfigChannel(TIM_HandleTypeDef *htim, const TIM_IC_InitTypeDef *sConfig,
uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_OnePulse_ConfigChannel(TIM_HandleTypeDef *htim, TIM_OnePulse_InitTypeDef *sConfig,
uint32_t OutputChannel, uint32_t InputChannel);
HAL_StatusTypeDef HAL_TIM_ConfigOCrefClear(TIM_HandleTypeDef *htim,
const TIM_ClearInputConfigTypeDef *sClearInputConfig,
uint32_t Channel);
HAL_StatusTypeDef HAL_TIM_ConfigClockSource(TIM_HandleTypeDef *htim, const TIM_ClockConfigTypeDef *sClockSourceConfig);
HAL_StatusTypeDef HAL_TIM_ConfigTI1Input(TIM_HandleTypeDef *htim, uint32_t TI1_Selection);
HAL_StatusTypeDef HAL_TIM_SlaveConfigSynchro(TIM_HandleTypeDef *htim, const TIM_SlaveConfigTypeDef *sSlaveConfig);
HAL_StatusTypeDef HAL_TIM_SlaveConfigSynchro_IT(TIM_HandleTypeDef *htim, const TIM_SlaveConfigTypeDef *sSlaveConfig);
HAL_StatusTypeDef HAL_TIM_DMABurst_WriteStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, const uint32_t *BurstBuffer,
uint32_t BurstLength);
HAL_StatusTypeDef HAL_TIM_DMABurst_MultiWriteStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, const uint32_t *BurstBuffer,
uint32_t BurstLength, uint32_t DataLength);
HAL_StatusTypeDef HAL_TIM_DMABurst_WriteStop(TIM_HandleTypeDef *htim, uint32_t BurstRequestSrc);
HAL_StatusTypeDef HAL_TIM_DMABurst_ReadStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, uint32_t *BurstBuffer, uint32_t BurstLength);
HAL_StatusTypeDef HAL_TIM_DMABurst_MultiReadStart(TIM_HandleTypeDef *htim, uint32_t BurstBaseAddress,
uint32_t BurstRequestSrc, uint32_t *BurstBuffer,
uint32_t BurstLength, uint32_t DataLength);
HAL_StatusTypeDef HAL_TIM_DMABurst_ReadStop(TIM_HandleTypeDef *htim, uint32_t BurstRequestSrc);
HAL_StatusTypeDef HAL_TIM_GenerateEvent(TIM_HandleTypeDef *htim, uint32_t EventSource);
uint32_t HAL_TIM_ReadCapturedValue(const TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group9 TIM Callbacks functions
* @brief TIM Callbacks functions
* @{
*/
/* Callback in non blocking modes (Interrupt and DMA) *************************/
void HAL_TIM_PeriodElapsedCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_PeriodElapsedHalfCpltCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_OC_DelayElapsedCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_IC_CaptureCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_IC_CaptureHalfCpltCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_PWM_PulseFinishedCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_PWM_PulseFinishedHalfCpltCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_TriggerCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_TriggerHalfCpltCallback(TIM_HandleTypeDef *htim);
void HAL_TIM_ErrorCallback(TIM_HandleTypeDef *htim);
/* Callbacks Register/UnRegister functions ***********************************/
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
HAL_StatusTypeDef HAL_TIM_RegisterCallback(TIM_HandleTypeDef *htim, HAL_TIM_CallbackIDTypeDef CallbackID,
pTIM_CallbackTypeDef pCallback);
HAL_StatusTypeDef HAL_TIM_UnRegisterCallback(TIM_HandleTypeDef *htim, HAL_TIM_CallbackIDTypeDef CallbackID);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/**
* @}
*/
/** @defgroup TIM_Exported_Functions_Group10 TIM Peripheral State functions
* @brief Peripheral State functions
* @{
*/
/* Peripheral State functions ************************************************/
HAL_TIM_StateTypeDef HAL_TIM_Base_GetState(const TIM_HandleTypeDef *htim);
HAL_TIM_StateTypeDef HAL_TIM_OC_GetState(const TIM_HandleTypeDef *htim);
HAL_TIM_StateTypeDef HAL_TIM_PWM_GetState(const TIM_HandleTypeDef *htim);
HAL_TIM_StateTypeDef HAL_TIM_IC_GetState(const TIM_HandleTypeDef *htim);
HAL_TIM_StateTypeDef HAL_TIM_OnePulse_GetState(const TIM_HandleTypeDef *htim);
HAL_TIM_StateTypeDef HAL_TIM_Encoder_GetState(const TIM_HandleTypeDef *htim);
/* Peripheral Channel state functions ************************************************/
HAL_TIM_ActiveChannel HAL_TIM_GetActiveChannel(const TIM_HandleTypeDef *htim);
HAL_TIM_ChannelStateTypeDef HAL_TIM_GetChannelState(const TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_TIM_DMABurstStateTypeDef HAL_TIM_DMABurstState(const TIM_HandleTypeDef *htim);
/**
* @}
*/
/**
* @}
*/
/* End of exported functions -------------------------------------------------*/
/* Private functions----------------------------------------------------------*/
/** @defgroup TIM_Private_Functions TIM Private Functions
* @{
*/
void TIM_Base_SetConfig(TIM_TypeDef *TIMx, const TIM_Base_InitTypeDef *Structure);
void TIM_TI1_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ICPolarity, uint32_t TIM_ICSelection, uint32_t TIM_ICFilter);
void TIM_OC2_SetConfig(TIM_TypeDef *TIMx, const TIM_OC_InitTypeDef *OC_Config);
void TIM_ETR_SetConfig(TIM_TypeDef *TIMx, uint32_t TIM_ExtTRGPrescaler,
uint32_t TIM_ExtTRGPolarity, uint32_t ExtTRGFilter);
void TIM_DMADelayPulseHalfCplt(DMA_HandleTypeDef *hdma);
void TIM_DMAError(DMA_HandleTypeDef *hdma);
void TIM_DMACaptureCplt(DMA_HandleTypeDef *hdma);
void TIM_DMACaptureHalfCplt(DMA_HandleTypeDef *hdma);
void TIM_CCxChannelCmd(TIM_TypeDef *TIMx, uint32_t Channel, uint32_t ChannelState);
#if (USE_HAL_TIM_REGISTER_CALLBACKS == 1)
void TIM_ResetCallback(TIM_HandleTypeDef *htim);
#endif /* USE_HAL_TIM_REGISTER_CALLBACKS */
/**
* @}
*/
/* End of private functions --------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_TIM_H */
| 160,492 | C | 60.444487 | 250 | 0.514487 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_rcc_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_rcc_ex.h
* @author MCD Application Team
* @brief Header file of RCC HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_RCC_EX_H
#define STM32G4xx_HAL_RCC_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup RCCEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup RCCEx_Exported_Types RCCEx Exported Types
* @{
*/
/**
* @brief RCC extended clocks structure definition
*/
typedef struct
{
uint32_t PeriphClockSelection; /*!< The Extended Clock to be configured.
This parameter can be a value of @ref RCCEx_Periph_Clock_Selection */
uint32_t Usart1ClockSelection; /*!< Specifies USART1 clock source.
This parameter can be a value of @ref RCCEx_USART1_Clock_Source */
uint32_t Usart2ClockSelection; /*!< Specifies USART2 clock source.
This parameter can be a value of @ref RCCEx_USART2_Clock_Source */
uint32_t Usart3ClockSelection; /*!< Specifies USART3 clock source.
This parameter can be a value of @ref RCCEx_USART3_Clock_Source */
#if defined(UART4)
uint32_t Uart4ClockSelection; /*!< Specifies UART4 clock source.
This parameter can be a value of @ref RCCEx_UART4_Clock_Source */
#endif /* UART4 */
#if defined(UART5)
uint32_t Uart5ClockSelection; /*!< Specifies UART5 clock source.
This parameter can be a value of @ref RCCEx_UART5_Clock_Source */
#endif /* UART5 */
uint32_t Lpuart1ClockSelection; /*!< Specifies LPUART1 clock source.
This parameter can be a value of @ref RCCEx_LPUART1_Clock_Source */
uint32_t I2c1ClockSelection; /*!< Specifies I2C1 clock source.
This parameter can be a value of @ref RCCEx_I2C1_Clock_Source */
uint32_t I2c2ClockSelection; /*!< Specifies I2C2 clock source.
This parameter can be a value of @ref RCCEx_I2C2_Clock_Source */
uint32_t I2c3ClockSelection; /*!< Specifies I2C3 clock source.
This parameter can be a value of @ref RCCEx_I2C3_Clock_Source */
#if defined(I2C4)
uint32_t I2c4ClockSelection; /*!< Specifies I2C4 clock source.
This parameter can be a value of @ref RCCEx_I2C4_Clock_Source */
#endif /* I2C4 */
uint32_t Lptim1ClockSelection; /*!< Specifies LPTIM1 clock source.
This parameter can be a value of @ref RCCEx_LPTIM1_Clock_Source */
uint32_t Sai1ClockSelection; /*!< Specifies SAI1 clock source.
This parameter can be a value of @ref RCCEx_SAI1_Clock_Source */
uint32_t I2sClockSelection; /*!< Specifies I2S clock source.
This parameter can be a value of @ref RCCEx_I2S_Clock_Source */
#if defined(FDCAN1)
uint32_t FdcanClockSelection; /*!< Specifies FDCAN clock source.
This parameter can be a value of @ref RCCEx_FDCAN_Clock_Source */
#endif /* FDCAN1 */
#if defined(USB)
uint32_t UsbClockSelection; /*!< Specifies USB clock source (warning: same source for RNG).
This parameter can be a value of @ref RCCEx_USB_Clock_Source */
#endif /* USB */
uint32_t RngClockSelection; /*!< Specifies RNG clock source (warning: same source for USB).
This parameter can be a value of @ref RCCEx_RNG_Clock_Source */
uint32_t Adc12ClockSelection; /*!< Specifies ADC12 interface clock source.
This parameter can be a value of @ref RCCEx_ADC12_Clock_Source */
#if defined(ADC345_COMMON)
uint32_t Adc345ClockSelection; /*!< Specifies ADC345 interface clock source.
This parameter can be a value of @ref RCCEx_ADC345_Clock_Source */
#endif /* ADC345_COMMON */
#if defined(QUADSPI)
uint32_t QspiClockSelection; /*!< Specifies QuadSPI clock source.
This parameter can be a value of @ref RCCEx_QSPI_Clock_Source */
#endif
uint32_t RTCClockSelection; /*!< Specifies RTC clock source.
This parameter can be a value of @ref RCC_RTC_Clock_Source */
}RCC_PeriphCLKInitTypeDef;
/**
* @brief RCC_CRS Init structure definition
*/
typedef struct
{
uint32_t Prescaler; /*!< Specifies the division factor of the SYNC signal.
This parameter can be a value of @ref RCCEx_CRS_SynchroDivider */
uint32_t Source; /*!< Specifies the SYNC signal source.
This parameter can be a value of @ref RCCEx_CRS_SynchroSource */
uint32_t Polarity; /*!< Specifies the input polarity for the SYNC signal source.
This parameter can be a value of @ref RCCEx_CRS_SynchroPolarity */
uint32_t ReloadValue; /*!< Specifies the value to be loaded in the frequency error counter with each SYNC event.
It can be calculated in using macro __HAL_RCC_CRS_RELOADVALUE_CALCULATE(__FTARGET__, __FSYNC__)
This parameter must be a number between 0 and 0xFFFF or a value of @ref RCCEx_CRS_ReloadValueDefault .*/
uint32_t ErrorLimitValue; /*!< Specifies the value to be used to evaluate the captured frequency error value.
This parameter must be a number between 0 and 0xFF or a value of @ref RCCEx_CRS_ErrorLimitDefault */
uint32_t HSI48CalibrationValue; /*!< Specifies a user-programmable trimming value to the HSI48 oscillator.
This parameter must be a number between 0 and 0x7F or a value of @ref RCCEx_CRS_HSI48CalibrationDefault */
}RCC_CRSInitTypeDef;
/**
* @brief RCC_CRS Synchronization structure definition
*/
typedef struct
{
uint32_t ReloadValue; /*!< Specifies the value loaded in the Counter reload value.
This parameter must be a number between 0 and 0xFFFF */
uint32_t HSI48CalibrationValue; /*!< Specifies value loaded in HSI48 oscillator smooth trimming.
This parameter must be a number between 0 and 0x7F */
uint32_t FreqErrorCapture; /*!< Specifies the value loaded in the .FECAP, the frequency error counter
value latched in the time of the last SYNC event.
This parameter must be a number between 0 and 0xFFFF */
uint32_t FreqErrorDirection; /*!< Specifies the value loaded in the .FEDIR, the counting direction of the
frequency error counter latched in the time of the last SYNC event.
It shows whether the actual frequency is below or above the target.
This parameter must be a value of @ref RCCEx_CRS_FreqErrorDirection*/
}RCC_CRSSynchroInfoTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup RCCEx_Exported_Constants RCCEx Exported Constants
* @{
*/
/** @defgroup RCCEx_LSCO_Clock_Source Low Speed Clock Source
* @{
*/
#define RCC_LSCOSOURCE_LSI 0x00000000U /*!< LSI selection for low speed clock output */
#define RCC_LSCOSOURCE_LSE RCC_BDCR_LSCOSEL /*!< LSE selection for low speed clock output */
/**
* @}
*/
/** @defgroup RCCEx_Periph_Clock_Selection Periph Clock Selection
* @{
*/
#define RCC_PERIPHCLK_USART1 0x00000001U
#define RCC_PERIPHCLK_USART2 0x00000002U
#define RCC_PERIPHCLK_USART3 0x00000004U
#if defined(UART4)
#define RCC_PERIPHCLK_UART4 0x00000008U
#endif /* UART4 */
#if defined(UART5)
#define RCC_PERIPHCLK_UART5 0x00000010U
#endif /* UART5 */
#define RCC_PERIPHCLK_LPUART1 0x00000020U
#define RCC_PERIPHCLK_I2C1 0x00000040U
#define RCC_PERIPHCLK_I2C2 0x00000080U
#define RCC_PERIPHCLK_I2C3 0x00000100U
#define RCC_PERIPHCLK_LPTIM1 0x00000200U
#define RCC_PERIPHCLK_SAI1 0x00000400U
#define RCC_PERIPHCLK_I2S 0x00000800U
#if defined(FDCAN1)
#define RCC_PERIPHCLK_FDCAN 0x00001000U
#endif /* FDCAN1 */
#define RCC_PERIPHCLK_USB 0x00002000U
#define RCC_PERIPHCLK_RNG 0x00004000U
#define RCC_PERIPHCLK_ADC12 0x00008000U
#if defined(ADC345_COMMON)
#define RCC_PERIPHCLK_ADC345 0x00010000U
#endif /* ADC345_COMMON */
#if defined(I2C4)
#define RCC_PERIPHCLK_I2C4 0x00020000U
#endif /* I2C4 */
#if defined(QUADSPI)
#define RCC_PERIPHCLK_QSPI 0x00040000U
#endif /* QUADSPI */
#define RCC_PERIPHCLK_RTC 0x00080000U
/**
* @}
*/
/** @defgroup RCCEx_USART1_Clock_Source USART1 Clock Source
* @{
*/
#define RCC_USART1CLKSOURCE_PCLK2 0x00000000U
#define RCC_USART1CLKSOURCE_SYSCLK RCC_CCIPR_USART1SEL_0
#define RCC_USART1CLKSOURCE_HSI RCC_CCIPR_USART1SEL_1
#define RCC_USART1CLKSOURCE_LSE (RCC_CCIPR_USART1SEL_0 | RCC_CCIPR_USART1SEL_1)
/**
* @}
*/
/** @defgroup RCCEx_USART2_Clock_Source USART2 Clock Source
* @{
*/
#define RCC_USART2CLKSOURCE_PCLK1 0x00000000U
#define RCC_USART2CLKSOURCE_SYSCLK RCC_CCIPR_USART2SEL_0
#define RCC_USART2CLKSOURCE_HSI RCC_CCIPR_USART2SEL_1
#define RCC_USART2CLKSOURCE_LSE (RCC_CCIPR_USART2SEL_0 | RCC_CCIPR_USART2SEL_1)
/**
* @}
*/
/** @defgroup RCCEx_USART3_Clock_Source USART3 Clock Source
* @{
*/
#define RCC_USART3CLKSOURCE_PCLK1 0x00000000U
#define RCC_USART3CLKSOURCE_SYSCLK RCC_CCIPR_USART3SEL_0
#define RCC_USART3CLKSOURCE_HSI RCC_CCIPR_USART3SEL_1
#define RCC_USART3CLKSOURCE_LSE (RCC_CCIPR_USART3SEL_0 | RCC_CCIPR_USART3SEL_1)
/**
* @}
*/
#if defined(UART4)
/** @defgroup RCCEx_UART4_Clock_Source UART4 Clock Source
* @{
*/
#define RCC_UART4CLKSOURCE_PCLK1 0x00000000U
#define RCC_UART4CLKSOURCE_SYSCLK RCC_CCIPR_UART4SEL_0
#define RCC_UART4CLKSOURCE_HSI RCC_CCIPR_UART4SEL_1
#define RCC_UART4CLKSOURCE_LSE (RCC_CCIPR_UART4SEL_0 | RCC_CCIPR_UART4SEL_1)
/**
* @}
*/
#endif /* UART4 */
#if defined(UART5)
/** @defgroup RCCEx_UART5_Clock_Source UART5 Clock Source
* @{
*/
#define RCC_UART5CLKSOURCE_PCLK1 0x00000000U
#define RCC_UART5CLKSOURCE_SYSCLK RCC_CCIPR_UART5SEL_0
#define RCC_UART5CLKSOURCE_HSI RCC_CCIPR_UART5SEL_1
#define RCC_UART5CLKSOURCE_LSE (RCC_CCIPR_UART5SEL_0 | RCC_CCIPR_UART5SEL_1)
/**
* @}
*/
#endif /* UART5 */
/** @defgroup RCCEx_LPUART1_Clock_Source LPUART1 Clock Source
* @{
*/
#define RCC_LPUART1CLKSOURCE_PCLK1 0x00000000U
#define RCC_LPUART1CLKSOURCE_SYSCLK RCC_CCIPR_LPUART1SEL_0
#define RCC_LPUART1CLKSOURCE_HSI RCC_CCIPR_LPUART1SEL_1
#define RCC_LPUART1CLKSOURCE_LSE (RCC_CCIPR_LPUART1SEL_0 | RCC_CCIPR_LPUART1SEL_1)
/**
* @}
*/
/** @defgroup RCCEx_I2C1_Clock_Source I2C1 Clock Source
* @{
*/
#define RCC_I2C1CLKSOURCE_PCLK1 0x00000000U
#define RCC_I2C1CLKSOURCE_SYSCLK RCC_CCIPR_I2C1SEL_0
#define RCC_I2C1CLKSOURCE_HSI RCC_CCIPR_I2C1SEL_1
/**
* @}
*/
/** @defgroup RCCEx_I2C2_Clock_Source I2C2 Clock Source
* @{
*/
#define RCC_I2C2CLKSOURCE_PCLK1 0x00000000U
#define RCC_I2C2CLKSOURCE_SYSCLK RCC_CCIPR_I2C2SEL_0
#define RCC_I2C2CLKSOURCE_HSI RCC_CCIPR_I2C2SEL_1
/**
* @}
*/
/** @defgroup RCCEx_I2C3_Clock_Source I2C3 Clock Source
* @{
*/
#define RCC_I2C3CLKSOURCE_PCLK1 0x00000000U
#define RCC_I2C3CLKSOURCE_SYSCLK RCC_CCIPR_I2C3SEL_0
#define RCC_I2C3CLKSOURCE_HSI RCC_CCIPR_I2C3SEL_1
/**
* @}
*/
/** @defgroup RCCEx_LPTIM1_Clock_Source LPTIM1 Clock Source
* @{
*/
#define RCC_LPTIM1CLKSOURCE_PCLK1 0x00000000U
#define RCC_LPTIM1CLKSOURCE_LSI RCC_CCIPR_LPTIM1SEL_0
#define RCC_LPTIM1CLKSOURCE_HSI RCC_CCIPR_LPTIM1SEL_1
#define RCC_LPTIM1CLKSOURCE_LSE RCC_CCIPR_LPTIM1SEL
/**
* @}
*/
/** @defgroup RCCEx_SAI1_Clock_Source SAI1 Clock Source
* @{
*/
#define RCC_SAI1CLKSOURCE_SYSCLK 0x00000000U
#define RCC_SAI1CLKSOURCE_PLL RCC_CCIPR_SAI1SEL_0
#define RCC_SAI1CLKSOURCE_EXT RCC_CCIPR_SAI1SEL_1
#define RCC_SAI1CLKSOURCE_HSI (RCC_CCIPR_SAI1SEL_1 | RCC_CCIPR_SAI1SEL_0)
/**
* @}
*/
/** @defgroup RCCEx_I2S_Clock_Source I2S Clock Source
* @{
*/
#define RCC_I2SCLKSOURCE_SYSCLK 0x00000000U
#define RCC_I2SCLKSOURCE_PLL RCC_CCIPR_I2S23SEL_0
#define RCC_I2SCLKSOURCE_EXT RCC_CCIPR_I2S23SEL_1
#define RCC_I2SCLKSOURCE_HSI (RCC_CCIPR_I2S23SEL_1 | RCC_CCIPR_I2S23SEL_0)
/**
* @}
*/
#if defined(FDCAN1)
/** @defgroup RCCEx_FDCAN_Clock_Source FDCAN Clock Source
* @{
*/
#define RCC_FDCANCLKSOURCE_HSE 0x00000000U
#define RCC_FDCANCLKSOURCE_PLL RCC_CCIPR_FDCANSEL_0
#define RCC_FDCANCLKSOURCE_PCLK1 RCC_CCIPR_FDCANSEL_1
/**
* @}
*/
#endif /* FDCAN1 */
/** @defgroup RCCEx_RNG_Clock_Source RNG Clock Source
* @{
*/
#define RCC_RNGCLKSOURCE_HSI48 0x00000000U
#define RCC_RNGCLKSOURCE_PLL RCC_CCIPR_CLK48SEL_1
/**
* @}
*/
/** @defgroup RCCEx_USB_Clock_Source USB Clock Source
* @{
*/
#define RCC_USBCLKSOURCE_HSI48 0x00000000U
#define RCC_USBCLKSOURCE_PLL RCC_CCIPR_CLK48SEL_1
/**
* @}
*/
/** @defgroup RCCEx_ADC12_Clock_Source ADC12 Clock Source
* @{
*/
#define RCC_ADC12CLKSOURCE_NONE 0x00000000U
#define RCC_ADC12CLKSOURCE_PLL RCC_CCIPR_ADC12SEL_0
#define RCC_ADC12CLKSOURCE_SYSCLK RCC_CCIPR_ADC12SEL_1
/**
* @}
*/
#if defined(ADC345_COMMON)
/** @defgroup RCCEx_ADC345_Clock_Source ADC345 Clock Source
* @{
*/
#define RCC_ADC345CLKSOURCE_NONE 0x00000000U
#define RCC_ADC345CLKSOURCE_PLL RCC_CCIPR_ADC345SEL_0
#define RCC_ADC345CLKSOURCE_SYSCLK RCC_CCIPR_ADC345SEL_1
/**
* @}
*/
#endif /* ADC345_COMMON */
#if defined(I2C4)
/** @defgroup RCCEx_I2C4_Clock_Source I2C4 Clock Source
* @{
*/
#define RCC_I2C4CLKSOURCE_PCLK1 0x00000000U
#define RCC_I2C4CLKSOURCE_SYSCLK RCC_CCIPR2_I2C4SEL_0
#define RCC_I2C4CLKSOURCE_HSI RCC_CCIPR2_I2C4SEL_1
/**
* @}
*/
#endif /* I2C4 */
#if defined(QUADSPI)
/** @defgroup RCCEx_QSPI_Clock_Source QuadSPI Clock Source
* @{
*/
#define RCC_QSPICLKSOURCE_SYSCLK 0x00000000U
#define RCC_QSPICLKSOURCE_HSI RCC_CCIPR2_QSPISEL_0
#define RCC_QSPICLKSOURCE_PLL RCC_CCIPR2_QSPISEL_1
/**
* @}
*/
#endif /* QUADSPI */
/** @defgroup RCCEx_EXTI_LINE_LSECSS RCC LSE CSS external interrupt line
* @{
*/
#define RCC_EXTI_LINE_LSECSS EXTI_IMR1_IM19 /*!< External interrupt line 19 connected to the LSE CSS EXTI Line */
/**
* @}
*/
/** @defgroup RCCEx_CRS_Status RCCEx CRS Status
* @{
*/
#define RCC_CRS_NONE 0x00000000U
#define RCC_CRS_TIMEOUT 0x00000001U
#define RCC_CRS_SYNCOK 0x00000002U
#define RCC_CRS_SYNCWARN 0x00000004U
#define RCC_CRS_SYNCERR 0x00000008U
#define RCC_CRS_SYNCMISS 0x00000010U
#define RCC_CRS_TRIMOVF 0x00000020U
/**
* @}
*/
/** @defgroup RCCEx_CRS_SynchroSource RCCEx CRS SynchroSource
* @{
*/
#define RCC_CRS_SYNC_SOURCE_GPIO 0x00000000U /*!< Synchro Signal source GPIO */
#define RCC_CRS_SYNC_SOURCE_LSE CRS_CFGR_SYNCSRC_0 /*!< Synchro Signal source LSE */
#define RCC_CRS_SYNC_SOURCE_USB CRS_CFGR_SYNCSRC_1 /*!< Synchro Signal source USB SOF (default)*/
/**
* @}
*/
/** @defgroup RCCEx_CRS_SynchroDivider RCCEx CRS SynchroDivider
* @{
*/
#define RCC_CRS_SYNC_DIV1 0x00000000U /*!< Synchro Signal not divided (default) */
#define RCC_CRS_SYNC_DIV2 CRS_CFGR_SYNCDIV_0 /*!< Synchro Signal divided by 2 */
#define RCC_CRS_SYNC_DIV4 CRS_CFGR_SYNCDIV_1 /*!< Synchro Signal divided by 4 */
#define RCC_CRS_SYNC_DIV8 (CRS_CFGR_SYNCDIV_1 | CRS_CFGR_SYNCDIV_0) /*!< Synchro Signal divided by 8 */
#define RCC_CRS_SYNC_DIV16 CRS_CFGR_SYNCDIV_2 /*!< Synchro Signal divided by 16 */
#define RCC_CRS_SYNC_DIV32 (CRS_CFGR_SYNCDIV_2 | CRS_CFGR_SYNCDIV_0) /*!< Synchro Signal divided by 32 */
#define RCC_CRS_SYNC_DIV64 (CRS_CFGR_SYNCDIV_2 | CRS_CFGR_SYNCDIV_1) /*!< Synchro Signal divided by 64 */
#define RCC_CRS_SYNC_DIV128 CRS_CFGR_SYNCDIV /*!< Synchro Signal divided by 128 */
/**
* @}
*/
/** @defgroup RCCEx_CRS_SynchroPolarity RCCEx CRS SynchroPolarity
* @{
*/
#define RCC_CRS_SYNC_POLARITY_RISING 0x00000000U /*!< Synchro Active on rising edge (default) */
#define RCC_CRS_SYNC_POLARITY_FALLING CRS_CFGR_SYNCPOL /*!< Synchro Active on falling edge */
/**
* @}
*/
/** @defgroup RCCEx_CRS_ReloadValueDefault RCCEx CRS ReloadValueDefault
* @{
*/
#define RCC_CRS_RELOADVALUE_DEFAULT 0x0000BB7FU /*!< The reset value of the RELOAD field corresponds
to a target frequency of 48 MHz and a synchronization signal frequency of 1 kHz (SOF signal from USB). */
/**
* @}
*/
/** @defgroup RCCEx_CRS_ErrorLimitDefault RCCEx CRS ErrorLimitDefault
* @{
*/
#define RCC_CRS_ERRORLIMIT_DEFAULT 0x00000022U /*!< Default Frequency error limit */
/**
* @}
*/
/** @defgroup RCCEx_CRS_HSI48CalibrationDefault RCCEx CRS HSI48CalibrationDefault
* @{
*/
#define RCC_CRS_HSI48CALIBRATION_DEFAULT 0x00000040U /*!< The default value is 64, which corresponds to the middle of the trimming interval.
The trimming step is around 67 kHz between two consecutive TRIM steps. A higher TRIM value
corresponds to a higher output frequency */
/**
* @}
*/
/** @defgroup RCCEx_CRS_FreqErrorDirection RCCEx CRS FreqErrorDirection
* @{
*/
#define RCC_CRS_FREQERRORDIR_UP 0x00000000U /*!< Upcounting direction, the actual frequency is above the target */
#define RCC_CRS_FREQERRORDIR_DOWN CRS_ISR_FEDIR /*!< Downcounting direction, the actual frequency is below the target */
/**
* @}
*/
/** @defgroup RCCEx_CRS_Interrupt_Sources RCCEx CRS Interrupt Sources
* @{
*/
#define RCC_CRS_IT_SYNCOK CRS_CR_SYNCOKIE /*!< SYNC event OK */
#define RCC_CRS_IT_SYNCWARN CRS_CR_SYNCWARNIE /*!< SYNC warning */
#define RCC_CRS_IT_ERR CRS_CR_ERRIE /*!< Error */
#define RCC_CRS_IT_ESYNC CRS_CR_ESYNCIE /*!< Expected SYNC */
#define RCC_CRS_IT_SYNCERR CRS_CR_ERRIE /*!< SYNC error */
#define RCC_CRS_IT_SYNCMISS CRS_CR_ERRIE /*!< SYNC missed */
#define RCC_CRS_IT_TRIMOVF CRS_CR_ERRIE /*!< Trimming overflow or underflow */
/**
* @}
*/
/** @defgroup RCCEx_CRS_Flags RCCEx CRS Flags
* @{
*/
#define RCC_CRS_FLAG_SYNCOK CRS_ISR_SYNCOKF /*!< SYNC event OK flag */
#define RCC_CRS_FLAG_SYNCWARN CRS_ISR_SYNCWARNF /*!< SYNC warning flag */
#define RCC_CRS_FLAG_ERR CRS_ISR_ERRF /*!< Error flag */
#define RCC_CRS_FLAG_ESYNC CRS_ISR_ESYNCF /*!< Expected SYNC flag */
#define RCC_CRS_FLAG_SYNCERR CRS_ISR_SYNCERR /*!< SYNC error */
#define RCC_CRS_FLAG_SYNCMISS CRS_ISR_SYNCMISS /*!< SYNC missed*/
#define RCC_CRS_FLAG_TRIMOVF CRS_ISR_TRIMOVF /*!< Trimming overflow or underflow */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup RCCEx_Exported_Macros RCCEx Exported Macros
* @{
*/
/** @brief Macro to configure the USART1 clock (USART1CLK).
*
* @param __USART1_CLKSOURCE__ specifies the USART1 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_USART1CLKSOURCE_PCLK2 PCLK2 selected as USART1 clock
* @arg @ref RCC_USART1CLKSOURCE_HSI HSI selected as USART1 clock
* @arg @ref RCC_USART1CLKSOURCE_SYSCLK System Clock selected as USART1 clock
* @arg @ref RCC_USART1CLKSOURCE_LSE LSE selected as USART1 clock
* @retval None
*/
#define __HAL_RCC_USART1_CONFIG(__USART1_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_USART1SEL, (__USART1_CLKSOURCE__))
/** @brief Macro to get the USART1 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_USART1CLKSOURCE_PCLK2 PCLK2 selected as USART1 clock
* @arg @ref RCC_USART1CLKSOURCE_HSI HSI selected as USART1 clock
* @arg @ref RCC_USART1CLKSOURCE_SYSCLK System Clock selected as USART1 clock
* @arg @ref RCC_USART1CLKSOURCE_LSE LSE selected as USART1 clock
*/
#define __HAL_RCC_GET_USART1_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_USART1SEL))
/** @brief Macro to configure the USART2 clock (USART2CLK).
*
* @param __USART2_CLKSOURCE__ specifies the USART2 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_USART2CLKSOURCE_PCLK1 PCLK1 selected as USART2 clock
* @arg @ref RCC_USART2CLKSOURCE_HSI HSI selected as USART2 clock
* @arg @ref RCC_USART2CLKSOURCE_SYSCLK System Clock selected as USART2 clock
* @arg @ref RCC_USART2CLKSOURCE_LSE LSE selected as USART2 clock
* @retval None
*/
#define __HAL_RCC_USART2_CONFIG(__USART2_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_USART2SEL, (__USART2_CLKSOURCE__))
/** @brief Macro to get the USART2 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_USART2CLKSOURCE_PCLK1 PCLK1 selected as USART2 clock
* @arg @ref RCC_USART2CLKSOURCE_HSI HSI selected as USART2 clock
* @arg @ref RCC_USART2CLKSOURCE_SYSCLK System Clock selected as USART2 clock
* @arg @ref RCC_USART2CLKSOURCE_LSE LSE selected as USART2 clock
*/
#define __HAL_RCC_GET_USART2_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_USART2SEL))
/** @brief Macro to configure the USART3 clock (USART3CLK).
*
* @param __USART3_CLKSOURCE__ specifies the USART3 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_USART3CLKSOURCE_PCLK1 PCLK1 selected as USART3 clock
* @arg @ref RCC_USART3CLKSOURCE_HSI HSI selected as USART3 clock
* @arg @ref RCC_USART3CLKSOURCE_SYSCLK System Clock selected as USART3 clock
* @arg @ref RCC_USART3CLKSOURCE_LSE LSE selected as USART3 clock
* @retval None
*/
#define __HAL_RCC_USART3_CONFIG(__USART3_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_USART3SEL, (__USART3_CLKSOURCE__))
/** @brief Macro to get the USART3 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_USART3CLKSOURCE_PCLK1 PCLK1 selected as USART3 clock
* @arg @ref RCC_USART3CLKSOURCE_HSI HSI selected as USART3 clock
* @arg @ref RCC_USART3CLKSOURCE_SYSCLK System Clock selected as USART3 clock
* @arg @ref RCC_USART3CLKSOURCE_LSE LSE selected as USART3 clock
*/
#define __HAL_RCC_GET_USART3_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_USART3SEL))
#if defined(UART4)
/** @brief Macro to configure the UART4 clock (UART4CLK).
*
* @param __UART4_CLKSOURCE__ specifies the UART4 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_UART4CLKSOURCE_PCLK1 PCLK1 selected as UART4 clock
* @arg @ref RCC_UART4CLKSOURCE_HSI HSI selected as UART4 clock
* @arg @ref RCC_UART4CLKSOURCE_SYSCLK System Clock selected as UART4 clock
* @arg @ref RCC_UART4CLKSOURCE_LSE LSE selected as UART4 clock
* @retval None
*/
#define __HAL_RCC_UART4_CONFIG(__UART4_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_UART4SEL, (__UART4_CLKSOURCE__))
/** @brief Macro to get the UART4 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_UART4CLKSOURCE_PCLK1 PCLK1 selected as UART4 clock
* @arg @ref RCC_UART4CLKSOURCE_HSI HSI selected as UART4 clock
* @arg @ref RCC_UART4CLKSOURCE_SYSCLK System Clock selected as UART4 clock
* @arg @ref RCC_UART4CLKSOURCE_LSE LSE selected as UART4 clock
*/
#define __HAL_RCC_GET_UART4_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_UART4SEL))
#endif /* UART4 */
#if defined(UART5)
/** @brief Macro to configure the UART5 clock (UART5CLK).
*
* @param __UART5_CLKSOURCE__ specifies the UART5 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_UART5CLKSOURCE_PCLK1 PCLK1 selected as UART5 clock
* @arg @ref RCC_UART5CLKSOURCE_HSI HSI selected as UART5 clock
* @arg @ref RCC_UART5CLKSOURCE_SYSCLK System Clock selected as UART5 clock
* @arg @ref RCC_UART5CLKSOURCE_LSE LSE selected as UART5 clock
* @retval None
*/
#define __HAL_RCC_UART5_CONFIG(__UART5_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_UART5SEL, (__UART5_CLKSOURCE__))
/** @brief Macro to get the UART5 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_UART5CLKSOURCE_PCLK1 PCLK1 selected as UART5 clock
* @arg @ref RCC_UART5CLKSOURCE_HSI HSI selected as UART5 clock
* @arg @ref RCC_UART5CLKSOURCE_SYSCLK System Clock selected as UART5 clock
* @arg @ref RCC_UART5CLKSOURCE_LSE LSE selected as UART5 clock
*/
#define __HAL_RCC_GET_UART5_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_UART5SEL))
#endif /* UART5 */
/** @brief Macro to configure the LPUART1 clock (LPUART1CLK).
*
* @param __LPUART1_CLKSOURCE__ specifies the LPUART1 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_LPUART1CLKSOURCE_PCLK1 PCLK1 selected as LPUART1 clock
* @arg @ref RCC_LPUART1CLKSOURCE_HSI HSI selected as LPUART1 clock
* @arg @ref RCC_LPUART1CLKSOURCE_SYSCLK System Clock selected as LPUART1 clock
* @arg @ref RCC_LPUART1CLKSOURCE_LSE LSE selected as LPUART1 clock
* @retval None
*/
#define __HAL_RCC_LPUART1_CONFIG(__LPUART1_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_LPUART1SEL, (__LPUART1_CLKSOURCE__))
/** @brief Macro to get the LPUART1 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_LPUART1CLKSOURCE_PCLK1 PCLK1 selected as LPUART1 clock
* @arg @ref RCC_LPUART1CLKSOURCE_HSI HSI selected as LPUART1 clock
* @arg @ref RCC_LPUART1CLKSOURCE_SYSCLK System Clock selected as LPUART1 clock
* @arg @ref RCC_LPUART1CLKSOURCE_LSE LSE selected as LPUART1 clock
*/
#define __HAL_RCC_GET_LPUART1_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_LPUART1SEL))
/** @brief Macro to configure the I2C1 clock (I2C1CLK).
*
* @param __I2C1_CLKSOURCE__ specifies the I2C1 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_I2C1CLKSOURCE_PCLK1 PCLK1 selected as I2C1 clock
* @arg @ref RCC_I2C1CLKSOURCE_HSI HSI selected as I2C1 clock
* @arg @ref RCC_I2C1CLKSOURCE_SYSCLK System Clock selected as I2C1 clock
* @retval None
*/
#define __HAL_RCC_I2C1_CONFIG(__I2C1_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_I2C1SEL, (__I2C1_CLKSOURCE__))
/** @brief Macro to get the I2C1 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_I2C1CLKSOURCE_PCLK1 PCLK1 selected as I2C1 clock
* @arg @ref RCC_I2C1CLKSOURCE_HSI HSI selected as I2C1 clock
* @arg @ref RCC_I2C1CLKSOURCE_SYSCLK System Clock selected as I2C1 clock
*/
#define __HAL_RCC_GET_I2C1_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_I2C1SEL))
/** @brief Macro to configure the I2C2 clock (I2C2CLK).
*
* @param __I2C2_CLKSOURCE__ specifies the I2C2 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_I2C2CLKSOURCE_PCLK1 PCLK1 selected as I2C2 clock
* @arg @ref RCC_I2C2CLKSOURCE_HSI HSI selected as I2C2 clock
* @arg @ref RCC_I2C2CLKSOURCE_SYSCLK System Clock selected as I2C2 clock
* @retval None
*/
#define __HAL_RCC_I2C2_CONFIG(__I2C2_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_I2C2SEL, (__I2C2_CLKSOURCE__))
/** @brief Macro to get the I2C2 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_I2C2CLKSOURCE_PCLK1 PCLK1 selected as I2C2 clock
* @arg @ref RCC_I2C2CLKSOURCE_HSI HSI selected as I2C2 clock
* @arg @ref RCC_I2C2CLKSOURCE_SYSCLK System Clock selected as I2C2 clock
*/
#define __HAL_RCC_GET_I2C2_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_I2C2SEL))
/** @brief Macro to configure the I2C3 clock (I2C3CLK).
*
* @param __I2C3_CLKSOURCE__ specifies the I2C3 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_I2C3CLKSOURCE_PCLK1 PCLK1 selected as I2C3 clock
* @arg @ref RCC_I2C3CLKSOURCE_HSI HSI selected as I2C3 clock
* @arg @ref RCC_I2C3CLKSOURCE_SYSCLK System Clock selected as I2C3 clock
* @retval None
*/
#define __HAL_RCC_I2C3_CONFIG(__I2C3_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_I2C3SEL, (__I2C3_CLKSOURCE__))
/** @brief Macro to get the I2C3 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_I2C3CLKSOURCE_PCLK1 PCLK1 selected as I2C3 clock
* @arg @ref RCC_I2C3CLKSOURCE_HSI HSI selected as I2C3 clock
* @arg @ref RCC_I2C3CLKSOURCE_SYSCLK System Clock selected as I2C3 clock
*/
#define __HAL_RCC_GET_I2C3_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_I2C3SEL))
#if defined(I2C4)
/** @brief Macro to configure the I2C4 clock (I2C4CLK).
*
* @param __I2C4_CLKSOURCE__ specifies the I2C4 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_I2C4CLKSOURCE_PCLK1 PCLK1 selected as I2C4 clock
* @arg @ref RCC_I2C4CLKSOURCE_HSI HSI selected as I2C4 clock
* @arg @ref RCC_I2C4CLKSOURCE_SYSCLK System Clock selected as I2C4 clock
* @retval None
*/
#define __HAL_RCC_I2C4_CONFIG(__I2C4_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR2, RCC_CCIPR2_I2C4SEL, (__I2C4_CLKSOURCE__))
/** @brief Macro to get the I2C4 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_I2C4CLKSOURCE_PCLK1 PCLK1 selected as I2C4 clock
* @arg @ref RCC_I2C4CLKSOURCE_HSI HSI selected as I2C4 clock
* @arg @ref RCC_I2C4CLKSOURCE_SYSCLK System Clock selected as I2C4 clock
*/
#define __HAL_RCC_GET_I2C4_SOURCE() (READ_BIT(RCC->CCIPR2, RCC_CCIPR2_I2C4SEL))
#endif /* I2C4 */
/** @brief Macro to configure the LPTIM1 clock (LPTIM1CLK).
*
* @param __LPTIM1_CLKSOURCE__ specifies the LPTIM1 clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_LPTIM1CLKSOURCE_PCLK1 PCLK1 selected as LPTIM1 clock
* @arg @ref RCC_LPTIM1CLKSOURCE_LSI HSI selected as LPTIM1 clock
* @arg @ref RCC_LPTIM1CLKSOURCE_HSI LSI selected as LPTIM1 clock
* @arg @ref RCC_LPTIM1CLKSOURCE_LSE LSE selected as LPTIM1 clock
* @retval None
*/
#define __HAL_RCC_LPTIM1_CONFIG(__LPTIM1_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_LPTIM1SEL, (__LPTIM1_CLKSOURCE__))
/** @brief Macro to get the LPTIM1 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_LPTIM1CLKSOURCE_PCLK1 PCLK1 selected as LPUART1 clock
* @arg @ref RCC_LPTIM1CLKSOURCE_LSI HSI selected as LPUART1 clock
* @arg @ref RCC_LPTIM1CLKSOURCE_HSI System Clock selected as LPUART1 clock
* @arg @ref RCC_LPTIM1CLKSOURCE_LSE LSE selected as LPUART1 clock
*/
#define __HAL_RCC_GET_LPTIM1_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_LPTIM1SEL))
/**
* @brief Macro to configure the SAI1 clock source.
* @param __SAI1_CLKSOURCE__ defines the SAI1 clock source. This clock is derived
* from the HSI, system PLL, System Clock or external clock.
* This parameter can be one of the following values:
* @arg @ref RCC_SAI1CLKSOURCE_SYSCLK SAI1 clock = System Clock
* @arg @ref RCC_SAI1CLKSOURCE_PLL SAI1 clock = PLL "Q" clock
* @arg @ref RCC_SAI1CLKSOURCE_EXT SAI1 clock = EXT
* @arg @ref RCC_SAI1CLKSOURCE_HSI SAI1 clock = HSI
*
* @retval None
*/
#define __HAL_RCC_SAI1_CONFIG(__SAI1_CLKSOURCE__)\
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_SAI1SEL, (__SAI1_CLKSOURCE__))
/** @brief Macro to get the SAI1 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_SAI1CLKSOURCE_SYSCLK SAI1 clock = System Clock
* @arg @ref RCC_SAI1CLKSOURCE_PLL SAI1 clock = PLL "Q" clock
* @arg @ref RCC_SAI1CLKSOURCE_EXT SAI1 clock = EXT
* @arg @ref RCC_SAI1CLKSOURCE_HSI SAI1 clock = HSI
*
*/
#define __HAL_RCC_GET_SAI1_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_SAI1SEL))
/**
* @brief Macro to configure the I2S clock source.
* @param __I2S_CLKSOURCE__ defines the I2S clock source. This clock is derived
* from the HSI, system PLL, System Clock or external clock.
* This parameter can be one of the following values:
* @arg @ref RCC_I2SCLKSOURCE_SYSCLK I2S clock = System Clock
* @arg @ref RCC_I2SCLKSOURCE_PLL I2S clock = PLL "Q" clock
* @arg @ref RCC_I2SCLKSOURCE_EXT I2S clock = EXT
* @arg @ref RCC_I2SCLKSOURCE_HSI I2S clock = HSI
*
* @retval None
*/
#define __HAL_RCC_I2S_CONFIG(__I2S_CLKSOURCE__)\
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_I2S23SEL, (__I2S_CLKSOURCE__))
/** @brief Macro to get the I2S clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_I2SCLKSOURCE_SYSCLK I2S clock = System Clock
* @arg @ref RCC_I2SCLKSOURCE_PLL I2S clock = PLL "Q" clock
* @arg @ref RCC_I2SCLKSOURCE_EXT I2S clock = EXT
* @arg @ref RCC_I2SCLKSOURCE_HSI I2S clock = HSI
*
*/
#define __HAL_RCC_GET_I2S_SOURCE() ((uint32_t)(READ_BIT(RCC->CCIPR, RCC_CCIPR_I2S23SEL)))
#if defined(FDCAN1)
/**
* @brief Macro to configure the FDCAN clock source.
* @param __FDCAN_CLKSOURCE__ defines the FDCAN clock source. This clock is derived
* from the HSE, system PLL or PCLK1.
* This parameter can be one of the following values:
* @arg @ref RCC_FDCANCLKSOURCE_HSE FDCAN clock = HSE
* @arg @ref RCC_FDCANCLKSOURCE_PLL FDCAN clock = PLL "Q" clock
* @arg @ref RCC_FDCANCLKSOURCE_PCLK1 FDCAN clock = PCLK1
*
* @retval None
*/
#define __HAL_RCC_FDCAN_CONFIG(__FDCAN_CLKSOURCE__)\
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_FDCANSEL, (uint32_t)(__FDCAN_CLKSOURCE__))
/** @brief Macro to get the FDCAN clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_FDCANCLKSOURCE_HSE FDCAN clock = HSE
* @arg @ref RCC_FDCANCLKSOURCE_PLL FDCAN clock = PLL "Q" clock
* @arg @ref RCC_FDCANCLKSOURCE_PCLK1 FDCAN clock = PCLK1
*
*/
#define __HAL_RCC_GET_FDCAN_SOURCE() ((uint32_t)(READ_BIT(RCC->CCIPR, RCC_CCIPR_FDCANSEL)))
#endif /* FDCAN1 */
/** @brief Macro to configure the RNG clock.
*
* @note USB and RNG peripherals share the same 48MHz clock source.
*
* @param __RNG_CLKSOURCE__ specifies the RNG clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_RNGCLKSOURCE_HSI48 HSI48 selected as RNG clock for devices with HSI48
* @arg @ref RCC_RNGCLKSOURCE_PLL PLL Clock selected as RNG clock
* @retval None
*/
#define __HAL_RCC_RNG_CONFIG(__RNG_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_CLK48SEL, (__RNG_CLKSOURCE__))
/** @brief Macro to get the RNG clock.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_RNGCLKSOURCE_HSI48 HSI48 selected as RNG clock for devices with HSI48
* @arg @ref RCC_RNGCLKSOURCE_PLL PLL "Q" clock selected as RNG clock
*/
#define __HAL_RCC_GET_RNG_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_CLK48SEL))
#if defined(USB)
/** @brief Macro to configure the USB clock (USBCLK).
*
* @note USB, RNG peripherals share the same 48MHz clock source.
*
* @param __USB_CLKSOURCE__ specifies the USB clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_USBCLKSOURCE_HSI48 HSI48 selected as 48MHz clock for devices with HSI48
* @arg @ref RCC_USBCLKSOURCE_PLL PLL "Q" clock (PLL48M1CLK) selected as USB clock
* @retval None
*/
#define __HAL_RCC_USB_CONFIG(__USB_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_CLK48SEL, (__USB_CLKSOURCE__))
/** @brief Macro to get the USB clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_USBCLKSOURCE_HSI48 HSI48 selected as 48MHz clock for devices with HSI48
* @arg @ref RCC_USBCLKSOURCE_PLL PLL "Q" clock (PLL48M1CLK) selected as USB clock
*/
#define __HAL_RCC_GET_USB_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_CLK48SEL))
#endif /* USB */
/** @brief Macro to configure the ADC12 interface clock.
* @param __ADC12_CLKSOURCE__ specifies the ADC12 digital interface clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_ADC12CLKSOURCE_NONE No clock selected as ADC12 clock
* @arg @ref RCC_ADC12CLKSOURCE_PLL PLL Clock selected as ADC12 clock
* @arg @ref RCC_ADC12CLKSOURCE_SYSCLK System Clock selected as ADC12 clock
* @retval None
*/
#define __HAL_RCC_ADC12_CONFIG(__ADC12_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_ADC12SEL, (__ADC12_CLKSOURCE__))
/** @brief Macro to get the ADC12 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_ADC12CLKSOURCE_NONE No clock selected as ADC12 clock
* @arg @ref RCC_ADC12CLKSOURCE_PLL PLL Clock selected as ADC12 clock
* @arg @ref RCC_ADC12CLKSOURCE_SYSCLK System Clock selected as ADC12 clock
*/
#define __HAL_RCC_GET_ADC12_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_ADC12SEL))
#if defined(ADC345_COMMON)
/** @brief Macro to configure the ADC345 interface clock.
* @param __ADC345_CLKSOURCE__ specifies the ADC345 digital interface clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_ADC345CLKSOURCE_NONE No clock selected as ADC345 clock
* @arg @ref RCC_ADC345CLKSOURCE_PLL PLL Clock selected as ADC345 clock
* @arg @ref RCC_ADC345CLKSOURCE_SYSCLK System Clock selected as ADC345 clock
* @retval None
*/
#define __HAL_RCC_ADC345_CONFIG(__ADC345_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_ADC345SEL, __ADC345_CLKSOURCE__)
/** @brief Macro to get the ADC345 clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_ADC345CLKSOURCE_NONE No clock selected as ADC345 clock
* @arg @ref RCC_ADC345CLKSOURCE_PLL PLL Clock selected as ADC345 clock
* @arg @ref RCC_ADC345CLKSOURCE_SYSCLK System Clock selected as ADC345 clock
*/
#define __HAL_RCC_GET_ADC345_SOURCE() (READ_BIT(RCC->CCIPR, RCC_CCIPR_ADC345SEL))
#endif /* ADC345_COMMON */
#if defined(QUADSPI)
/** @brief Macro to configure the QuadSPI clock.
* @param __QSPI_CLKSOURCE__ specifies the QuadSPI clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_QSPICLKSOURCE_SYSCLK System Clock selected as QuadSPI clock
* @arg @ref RCC_QSPICLKSOURCE_HSI HSI clock selected as QuadSPI clock
* @arg @ref RCC_QSPICLKSOURCE_PLL PLL Q divider clock selected as QuadSPI clock
* @retval None
*/
#define __HAL_RCC_QSPI_CONFIG(__QSPI_CLKSOURCE__) \
MODIFY_REG(RCC->CCIPR2, RCC_CCIPR2_QSPISEL, __QSPI_CLKSOURCE__)
/** @brief Macro to get the QuadSPI clock source.
* @retval The clock source can be one of the following values:
* @arg @ref RCC_QSPICLKSOURCE_SYSCLK System Clock selected as QuadSPI clock
* @arg @ref RCC_QSPICLKSOURCE_HSI HSI clock selected as QuadSPI clock
* @arg @ref RCC_QSPICLKSOURCE_PLL PLL Q divider clock selected as QuadSPI clock
*/
#define __HAL_RCC_GET_QSPI_SOURCE() (READ_BIT(RCC->CCIPR2, RCC_CCIPR2_QSPISEL))
#endif /* QUADSPI */
/** @defgroup RCCEx_Flags_Interrupts_Management Flags Interrupts Management
* @brief macros to manage the specified RCC Flags and interrupts.
* @{
*/
/**
* @brief Enable the RCC LSE CSS Extended Interrupt Line.
* @retval None
*/
#define __HAL_RCC_LSECSS_EXTI_ENABLE_IT() SET_BIT(EXTI->IMR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Disable the RCC LSE CSS Extended Interrupt Line.
* @retval None
*/
#define __HAL_RCC_LSECSS_EXTI_DISABLE_IT() CLEAR_BIT(EXTI->IMR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Enable the RCC LSE CSS Event Line.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_ENABLE_EVENT() SET_BIT(EXTI->EMR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Disable the RCC LSE CSS Event Line.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_DISABLE_EVENT() CLEAR_BIT(EXTI->EMR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Enable the RCC LSE CSS Extended Interrupt Falling Trigger.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_ENABLE_FALLING_EDGE() SET_BIT(EXTI->FTSR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Disable the RCC LSE CSS Extended Interrupt Falling Trigger.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_DISABLE_FALLING_EDGE() CLEAR_BIT(EXTI->FTSR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Enable the RCC LSE CSS Extended Interrupt Rising Trigger.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_ENABLE_RISING_EDGE() SET_BIT(EXTI->RTSR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Disable the RCC LSE CSS Extended Interrupt Rising Trigger.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_DISABLE_RISING_EDGE() CLEAR_BIT(EXTI->RTSR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Enable the RCC LSE CSS Extended Interrupt Rising & Falling Trigger.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_ENABLE_RISING_FALLING_EDGE() \
do { \
__HAL_RCC_LSECSS_EXTI_ENABLE_RISING_EDGE(); \
__HAL_RCC_LSECSS_EXTI_ENABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Disable the RCC LSE CSS Extended Interrupt Rising & Falling Trigger.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_DISABLE_RISING_FALLING_EDGE() \
do { \
__HAL_RCC_LSECSS_EXTI_DISABLE_RISING_EDGE(); \
__HAL_RCC_LSECSS_EXTI_DISABLE_FALLING_EDGE(); \
} while(0)
/**
* @brief Check whether the specified RCC LSE CSS EXTI interrupt flag is set or not.
* @retval EXTI RCC LSE CSS Line Status.
*/
#define __HAL_RCC_LSECSS_EXTI_GET_FLAG() (READ_BIT(EXTI->PR1, RCC_EXTI_LINE_LSECSS) == RCC_EXTI_LINE_LSECSS)
/**
* @brief Clear the RCC LSE CSS EXTI flag.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_CLEAR_FLAG() WRITE_REG(EXTI->PR1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Generate a Software interrupt on the RCC LSE CSS EXTI line.
* @retval None.
*/
#define __HAL_RCC_LSECSS_EXTI_GENERATE_SWIT() SET_BIT(EXTI->SWIER1, RCC_EXTI_LINE_LSECSS)
/**
* @brief Enable the specified CRS interrupts.
* @param __INTERRUPT__ specifies the CRS interrupt sources to be enabled.
* This parameter can be any combination of the following values:
* @arg @ref RCC_CRS_IT_SYNCOK SYNC event OK interrupt
* @arg @ref RCC_CRS_IT_SYNCWARN SYNC warning interrupt
* @arg @ref RCC_CRS_IT_ERR Synchronization or trimming error interrupt
* @arg @ref RCC_CRS_IT_ESYNC Expected SYNC interrupt
* @retval None
*/
#define __HAL_RCC_CRS_ENABLE_IT(__INTERRUPT__) SET_BIT(CRS->CR, (__INTERRUPT__))
/**
* @brief Disable the specified CRS interrupts.
* @param __INTERRUPT__ specifies the CRS interrupt sources to be disabled.
* This parameter can be any combination of the following values:
* @arg @ref RCC_CRS_IT_SYNCOK SYNC event OK interrupt
* @arg @ref RCC_CRS_IT_SYNCWARN SYNC warning interrupt
* @arg @ref RCC_CRS_IT_ERR Synchronization or trimming error interrupt
* @arg @ref RCC_CRS_IT_ESYNC Expected SYNC interrupt
* @retval None
*/
#define __HAL_RCC_CRS_DISABLE_IT(__INTERRUPT__) CLEAR_BIT(CRS->CR, (__INTERRUPT__))
/** @brief Check whether the CRS interrupt has occurred or not.
* @param __INTERRUPT__ specifies the CRS interrupt source to check.
* This parameter can be one of the following values:
* @arg @ref RCC_CRS_IT_SYNCOK SYNC event OK interrupt
* @arg @ref RCC_CRS_IT_SYNCWARN SYNC warning interrupt
* @arg @ref RCC_CRS_IT_ERR Synchronization or trimming error interrupt
* @arg @ref RCC_CRS_IT_ESYNC Expected SYNC interrupt
* @retval The new state of __INTERRUPT__ (SET or RESET).
*/
#define __HAL_RCC_CRS_GET_IT_SOURCE(__INTERRUPT__) ((READ_BIT(CRS->CR, (__INTERRUPT__)) != 0U) ? SET : RESET)
/** @brief Clear the CRS interrupt pending bits
* @param __INTERRUPT__ specifies the interrupt pending bit to clear.
* This parameter can be any combination of the following values:
* @arg @ref RCC_CRS_IT_SYNCOK SYNC event OK interrupt
* @arg @ref RCC_CRS_IT_SYNCWARN SYNC warning interrupt
* @arg @ref RCC_CRS_IT_ERR Synchronization or trimming error interrupt
* @arg @ref RCC_CRS_IT_ESYNC Expected SYNC interrupt
* @arg @ref RCC_CRS_IT_TRIMOVF Trimming overflow or underflow interrupt
* @arg @ref RCC_CRS_IT_SYNCERR SYNC error interrupt
* @arg @ref RCC_CRS_IT_SYNCMISS SYNC missed interrupt
*/
/* CRS IT Error Mask */
#define RCC_CRS_IT_ERROR_MASK (RCC_CRS_IT_TRIMOVF | RCC_CRS_IT_SYNCERR | RCC_CRS_IT_SYNCMISS)
#define __HAL_RCC_CRS_CLEAR_IT(__INTERRUPT__) do { \
if(((__INTERRUPT__) & RCC_CRS_IT_ERROR_MASK) != 0U) \
{ \
WRITE_REG(CRS->ICR, CRS_ICR_ERRC | ((__INTERRUPT__) & ~RCC_CRS_IT_ERROR_MASK)); \
} \
else \
{ \
WRITE_REG(CRS->ICR, (__INTERRUPT__)); \
} \
} while(0)
/**
* @brief Check whether the specified CRS flag is set or not.
* @param __FLAG__ specifies the flag to check.
* This parameter can be one of the following values:
* @arg @ref RCC_CRS_FLAG_SYNCOK SYNC event OK
* @arg @ref RCC_CRS_FLAG_SYNCWARN SYNC warning
* @arg @ref RCC_CRS_FLAG_ERR Error
* @arg @ref RCC_CRS_FLAG_ESYNC Expected SYNC
* @arg @ref RCC_CRS_FLAG_TRIMOVF Trimming overflow or underflow
* @arg @ref RCC_CRS_FLAG_SYNCERR SYNC error
* @arg @ref RCC_CRS_FLAG_SYNCMISS SYNC missed
* @retval The new state of _FLAG_ (TRUE or FALSE).
*/
#define __HAL_RCC_CRS_GET_FLAG(__FLAG__) (READ_BIT(CRS->ISR, (__FLAG__)) == (__FLAG__))
/**
* @brief Clear the CRS specified FLAG.
* @param __FLAG__ specifies the flag to clear.
* This parameter can be one of the following values:
* @arg @ref RCC_CRS_FLAG_SYNCOK SYNC event OK
* @arg @ref RCC_CRS_FLAG_SYNCWARN SYNC warning
* @arg @ref RCC_CRS_FLAG_ERR Error
* @arg @ref RCC_CRS_FLAG_ESYNC Expected SYNC
* @arg @ref RCC_CRS_FLAG_TRIMOVF Trimming overflow or underflow
* @arg @ref RCC_CRS_FLAG_SYNCERR SYNC error
* @arg @ref RCC_CRS_FLAG_SYNCMISS SYNC missed
* @note RCC_CRS_FLAG_ERR clears RCC_CRS_FLAG_TRIMOVF, RCC_CRS_FLAG_SYNCERR, RCC_CRS_FLAG_SYNCMISS and consequently RCC_CRS_FLAG_ERR
* @retval None
*/
/* CRS Flag Error Mask */
#define RCC_CRS_FLAG_ERROR_MASK (RCC_CRS_FLAG_TRIMOVF | RCC_CRS_FLAG_SYNCERR | RCC_CRS_FLAG_SYNCMISS)
#define __HAL_RCC_CRS_CLEAR_FLAG(__FLAG__) do { \
if(((__FLAG__) & RCC_CRS_FLAG_ERROR_MASK) != 0U) \
{ \
WRITE_REG(CRS->ICR, CRS_ICR_ERRC | ((__FLAG__) & ~RCC_CRS_FLAG_ERROR_MASK)); \
} \
else \
{ \
WRITE_REG(CRS->ICR, (__FLAG__)); \
} \
} while(0)
/**
* @}
*/
/** @defgroup RCCEx_CRS_Extended_Features RCCEx CRS Extended Features
* @{
*/
/**
* @brief Enable the oscillator clock for frequency error counter.
* @note when the CEN bit is set the CRS_CFGR register becomes write-protected.
* @retval None
*/
#define __HAL_RCC_CRS_FREQ_ERROR_COUNTER_ENABLE() SET_BIT(CRS->CR, CRS_CR_CEN)
/**
* @brief Disable the oscillator clock for frequency error counter.
* @retval None
*/
#define __HAL_RCC_CRS_FREQ_ERROR_COUNTER_DISABLE() CLEAR_BIT(CRS->CR, CRS_CR_CEN)
/**
* @brief Enable the automatic hardware adjustment of TRIM bits.
* @note When the AUTOTRIMEN bit is set the CRS_CFGR register becomes write-protected.
* @retval None
*/
#define __HAL_RCC_CRS_AUTOMATIC_CALIB_ENABLE() SET_BIT(CRS->CR, CRS_CR_AUTOTRIMEN)
/**
* @brief Enable or disable the automatic hardware adjustment of TRIM bits.
* @retval None
*/
#define __HAL_RCC_CRS_AUTOMATIC_CALIB_DISABLE() CLEAR_BIT(CRS->CR, CRS_CR_AUTOTRIMEN)
/**
* @brief Macro to calculate reload value to be set in CRS register according to target and sync frequencies
* @note The RELOAD value should be selected according to the ratio between the target frequency and the frequency
* of the synchronization source after prescaling. It is then decreased by one in order to
* reach the expected synchronization on the zero value. The formula is the following:
* RELOAD = (fTARGET / fSYNC) -1
* @param __FTARGET__ Target frequency (value in Hz)
* @param __FSYNC__ Synchronization signal frequency (value in Hz)
* @retval None
*/
#define __HAL_RCC_CRS_RELOADVALUE_CALCULATE(__FTARGET__, __FSYNC__) (((__FTARGET__) / (__FSYNC__)) - 1U)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup RCCEx_Exported_Functions
* @{
*/
/** @addtogroup RCCEx_Exported_Functions_Group1
* @{
*/
HAL_StatusTypeDef HAL_RCCEx_PeriphCLKConfig(RCC_PeriphCLKInitTypeDef *PeriphClkInit);
void HAL_RCCEx_GetPeriphCLKConfig(RCC_PeriphCLKInitTypeDef *PeriphClkInit);
uint32_t HAL_RCCEx_GetPeriphCLKFreq(uint32_t PeriphClk);
/**
* @}
*/
/** @addtogroup RCCEx_Exported_Functions_Group2
* @{
*/
void HAL_RCCEx_EnableLSECSS(void);
void HAL_RCCEx_DisableLSECSS(void);
void HAL_RCCEx_EnableLSECSS_IT(void);
void HAL_RCCEx_LSECSS_IRQHandler(void);
void HAL_RCCEx_LSECSS_Callback(void);
void HAL_RCCEx_EnableLSCO(uint32_t LSCOSource);
void HAL_RCCEx_DisableLSCO(void);
/**
* @}
*/
/** @addtogroup RCCEx_Exported_Functions_Group3
* @{
*/
void HAL_RCCEx_CRSConfig(RCC_CRSInitTypeDef *pInit);
void HAL_RCCEx_CRSSoftwareSynchronizationGenerate(void);
void HAL_RCCEx_CRSGetSynchronizationInfo(RCC_CRSSynchroInfoTypeDef *pSynchroInfo);
uint32_t HAL_RCCEx_CRSWaitSynchronization(uint32_t Timeout);
void HAL_RCCEx_CRS_IRQHandler(void);
void HAL_RCCEx_CRS_SyncOkCallback(void);
void HAL_RCCEx_CRS_SyncWarnCallback(void);
void HAL_RCCEx_CRS_ExpectedSyncCallback(void);
void HAL_RCCEx_CRS_ErrorCallback(uint32_t Error);
/**
* @}
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @addtogroup RCCEx_Private_Macros
* @{
*/
#define IS_RCC_LSCOSOURCE(__SOURCE__) (((__SOURCE__) == RCC_LSCOSOURCE_LSI) || \
((__SOURCE__) == RCC_LSCOSOURCE_LSE))
#if defined(STM32G474xx) || defined(STM32G484xx)
#define IS_RCC_PERIPHCLOCK(__SELECTION__) \
((((__SELECTION__) & RCC_PERIPHCLK_USART1) == RCC_PERIPHCLK_USART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART2) == RCC_PERIPHCLK_USART2) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART3) == RCC_PERIPHCLK_USART3) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART4) == RCC_PERIPHCLK_UART4) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART5) == RCC_PERIPHCLK_UART5) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPUART1) == RCC_PERIPHCLK_LPUART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C1) == RCC_PERIPHCLK_I2C1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C2) == RCC_PERIPHCLK_I2C2) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C3) == RCC_PERIPHCLK_I2C3) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C4) == RCC_PERIPHCLK_I2C4) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPTIM1) == RCC_PERIPHCLK_LPTIM1) || \
(((__SELECTION__) & RCC_PERIPHCLK_SAI1) == RCC_PERIPHCLK_SAI1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2S) == RCC_PERIPHCLK_I2S) || \
(((__SELECTION__) & RCC_PERIPHCLK_FDCAN) == RCC_PERIPHCLK_FDCAN) || \
(((__SELECTION__) & RCC_PERIPHCLK_USB) == RCC_PERIPHCLK_USB) || \
(((__SELECTION__) & RCC_PERIPHCLK_RNG) == RCC_PERIPHCLK_RNG) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC12) == RCC_PERIPHCLK_ADC12) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC345) == RCC_PERIPHCLK_ADC345) || \
(((__SELECTION__) & RCC_PERIPHCLK_QSPI) == RCC_PERIPHCLK_QSPI) || \
(((__SELECTION__) & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC))
#elif defined(STM32G491xx) || defined(STM32G4A1xx)
#define IS_RCC_PERIPHCLOCK(__SELECTION__) \
((((__SELECTION__) & RCC_PERIPHCLK_USART1) == RCC_PERIPHCLK_USART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART2) == RCC_PERIPHCLK_USART2) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART3) == RCC_PERIPHCLK_USART3) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART4) == RCC_PERIPHCLK_UART4) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART5) == RCC_PERIPHCLK_UART5) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPUART1) == RCC_PERIPHCLK_LPUART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C1) == RCC_PERIPHCLK_I2C1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C2) == RCC_PERIPHCLK_I2C2) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C3) == RCC_PERIPHCLK_I2C3) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPTIM1) == RCC_PERIPHCLK_LPTIM1) || \
(((__SELECTION__) & RCC_PERIPHCLK_SAI1) == RCC_PERIPHCLK_SAI1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2S) == RCC_PERIPHCLK_I2S) || \
(((__SELECTION__) & RCC_PERIPHCLK_FDCAN) == RCC_PERIPHCLK_FDCAN) || \
(((__SELECTION__) & RCC_PERIPHCLK_USB) == RCC_PERIPHCLK_USB) || \
(((__SELECTION__) & RCC_PERIPHCLK_RNG) == RCC_PERIPHCLK_RNG) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC12) == RCC_PERIPHCLK_ADC12) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC345) == RCC_PERIPHCLK_ADC345) || \
(((__SELECTION__) & RCC_PERIPHCLK_QSPI) == RCC_PERIPHCLK_QSPI) || \
(((__SELECTION__) & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC))
#elif defined(STM32G473xx) || defined(STM32G483xx)
#define IS_RCC_PERIPHCLOCK(__SELECTION__) \
((((__SELECTION__) & RCC_PERIPHCLK_USART1) == RCC_PERIPHCLK_USART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART2) == RCC_PERIPHCLK_USART2) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART3) == RCC_PERIPHCLK_USART3) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART4) == RCC_PERIPHCLK_UART4) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART5) == RCC_PERIPHCLK_UART5) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPUART1) == RCC_PERIPHCLK_LPUART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C1) == RCC_PERIPHCLK_I2C1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C2) == RCC_PERIPHCLK_I2C2) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C3) == RCC_PERIPHCLK_I2C3) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C4) == RCC_PERIPHCLK_I2C4) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPTIM1) == RCC_PERIPHCLK_LPTIM1) || \
(((__SELECTION__) & RCC_PERIPHCLK_SAI1) == RCC_PERIPHCLK_SAI1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2S) == RCC_PERIPHCLK_I2S) || \
(((__SELECTION__) & RCC_PERIPHCLK_FDCAN) == RCC_PERIPHCLK_FDCAN) || \
(((__SELECTION__) & RCC_PERIPHCLK_USB) == RCC_PERIPHCLK_USB) || \
(((__SELECTION__) & RCC_PERIPHCLK_RNG) == RCC_PERIPHCLK_RNG) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC12) == RCC_PERIPHCLK_ADC12) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC345) == RCC_PERIPHCLK_ADC345) || \
(((__SELECTION__) & RCC_PERIPHCLK_QSPI) == RCC_PERIPHCLK_QSPI) || \
(((__SELECTION__) & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC))
#elif defined(STM32G471xx)
#define IS_RCC_PERIPHCLOCK(__SELECTION__) \
((((__SELECTION__) & RCC_PERIPHCLK_USART1) == RCC_PERIPHCLK_USART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART2) == RCC_PERIPHCLK_USART2) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART3) == RCC_PERIPHCLK_USART3) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART4) == RCC_PERIPHCLK_UART4) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART5) == RCC_PERIPHCLK_UART5) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPUART1) == RCC_PERIPHCLK_LPUART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C1) == RCC_PERIPHCLK_I2C1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C2) == RCC_PERIPHCLK_I2C2) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C3) == RCC_PERIPHCLK_I2C3) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C4) == RCC_PERIPHCLK_I2C4) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPTIM1) == RCC_PERIPHCLK_LPTIM1) || \
(((__SELECTION__) & RCC_PERIPHCLK_SAI1) == RCC_PERIPHCLK_SAI1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2S) == RCC_PERIPHCLK_I2S) || \
(((__SELECTION__) & RCC_PERIPHCLK_USB) == RCC_PERIPHCLK_USB) || \
(((__SELECTION__) & RCC_PERIPHCLK_RNG) == RCC_PERIPHCLK_RNG) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC12) == RCC_PERIPHCLK_ADC12) || \
(((__SELECTION__) & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC))
#elif defined(STM32G431xx) || defined(STM32G441xx)
#define IS_RCC_PERIPHCLOCK(__SELECTION__) \
((((__SELECTION__) & RCC_PERIPHCLK_USART1) == RCC_PERIPHCLK_USART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART2) == RCC_PERIPHCLK_USART2) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART3) == RCC_PERIPHCLK_USART3) || \
(((__SELECTION__) & RCC_PERIPHCLK_UART4) == RCC_PERIPHCLK_UART4) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPUART1) == RCC_PERIPHCLK_LPUART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C1) == RCC_PERIPHCLK_I2C1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C2) == RCC_PERIPHCLK_I2C2) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C3) == RCC_PERIPHCLK_I2C3) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPTIM1) == RCC_PERIPHCLK_LPTIM1) || \
(((__SELECTION__) & RCC_PERIPHCLK_SAI1) == RCC_PERIPHCLK_SAI1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2S) == RCC_PERIPHCLK_I2S) || \
(((__SELECTION__) & RCC_PERIPHCLK_FDCAN) == RCC_PERIPHCLK_FDCAN) || \
(((__SELECTION__) & RCC_PERIPHCLK_USB) == RCC_PERIPHCLK_USB) || \
(((__SELECTION__) & RCC_PERIPHCLK_RNG) == RCC_PERIPHCLK_RNG) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC12) == RCC_PERIPHCLK_ADC12) || \
(((__SELECTION__) & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC))
#elif defined(STM32GBK1CB)
#define IS_RCC_PERIPHCLOCK(__SELECTION__) \
((((__SELECTION__) & RCC_PERIPHCLK_USART1) == RCC_PERIPHCLK_USART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART2) == RCC_PERIPHCLK_USART2) || \
(((__SELECTION__) & RCC_PERIPHCLK_USART3) == RCC_PERIPHCLK_USART3) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPUART1) == RCC_PERIPHCLK_LPUART1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C1) == RCC_PERIPHCLK_I2C1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C2) == RCC_PERIPHCLK_I2C2) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2C3) == RCC_PERIPHCLK_I2C3) || \
(((__SELECTION__) & RCC_PERIPHCLK_LPTIM1) == RCC_PERIPHCLK_LPTIM1) || \
(((__SELECTION__) & RCC_PERIPHCLK_SAI1) == RCC_PERIPHCLK_SAI1) || \
(((__SELECTION__) & RCC_PERIPHCLK_I2S) == RCC_PERIPHCLK_I2S) || \
(((__SELECTION__) & RCC_PERIPHCLK_FDCAN) == RCC_PERIPHCLK_FDCAN) || \
(((__SELECTION__) & RCC_PERIPHCLK_USB) == RCC_PERIPHCLK_USB) || \
(((__SELECTION__) & RCC_PERIPHCLK_RNG) == RCC_PERIPHCLK_RNG) || \
(((__SELECTION__) & RCC_PERIPHCLK_ADC12) == RCC_PERIPHCLK_ADC12) || \
(((__SELECTION__) & RCC_PERIPHCLK_RTC) == RCC_PERIPHCLK_RTC))
#endif /* STM32G474xx || STM32G484xx */
#define IS_RCC_USART1CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_USART1CLKSOURCE_PCLK2) || \
((__SOURCE__) == RCC_USART1CLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_USART1CLKSOURCE_LSE) || \
((__SOURCE__) == RCC_USART1CLKSOURCE_HSI))
#define IS_RCC_USART2CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_USART2CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_USART2CLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_USART2CLKSOURCE_LSE) || \
((__SOURCE__) == RCC_USART2CLKSOURCE_HSI))
#define IS_RCC_USART3CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_USART3CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_USART3CLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_USART3CLKSOURCE_LSE) || \
((__SOURCE__) == RCC_USART3CLKSOURCE_HSI))
#if defined(UART4)
#define IS_RCC_UART4CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_UART4CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_UART4CLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_UART4CLKSOURCE_LSE) || \
((__SOURCE__) == RCC_UART4CLKSOURCE_HSI))
#endif /* UART4 */
#if defined(UART5)
#define IS_RCC_UART5CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_UART5CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_UART5CLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_UART5CLKSOURCE_LSE) || \
((__SOURCE__) == RCC_UART5CLKSOURCE_HSI))
#endif /* UART5 */
#define IS_RCC_LPUART1CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_LPUART1CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_LPUART1CLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_LPUART1CLKSOURCE_LSE) || \
((__SOURCE__) == RCC_LPUART1CLKSOURCE_HSI))
#define IS_RCC_I2C1CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_I2C1CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_I2C1CLKSOURCE_SYSCLK)|| \
((__SOURCE__) == RCC_I2C1CLKSOURCE_HSI))
#define IS_RCC_I2C2CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_I2C2CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_I2C2CLKSOURCE_SYSCLK)|| \
((__SOURCE__) == RCC_I2C2CLKSOURCE_HSI))
#define IS_RCC_I2C3CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_I2C3CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_I2C3CLKSOURCE_SYSCLK)|| \
((__SOURCE__) == RCC_I2C3CLKSOURCE_HSI))
#if defined(I2C4)
#define IS_RCC_I2C4CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_I2C4CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_I2C4CLKSOURCE_SYSCLK)|| \
((__SOURCE__) == RCC_I2C4CLKSOURCE_HSI))
#endif /* I2C4 */
#define IS_RCC_LPTIM1CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_LPTIM1CLKSOURCE_PCLK1) || \
((__SOURCE__) == RCC_LPTIM1CLKSOURCE_LSI) || \
((__SOURCE__) == RCC_LPTIM1CLKSOURCE_HSI) || \
((__SOURCE__) == RCC_LPTIM1CLKSOURCE_LSE))
#define IS_RCC_SAI1CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_SAI1CLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_SAI1CLKSOURCE_PLL) || \
((__SOURCE__) == RCC_SAI1CLKSOURCE_EXT) || \
((__SOURCE__) == RCC_SAI1CLKSOURCE_HSI))
#define IS_RCC_I2SCLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_I2SCLKSOURCE_SYSCLK) || \
((__SOURCE__) == RCC_I2SCLKSOURCE_PLL) || \
((__SOURCE__) == RCC_I2SCLKSOURCE_EXT) || \
((__SOURCE__) == RCC_I2SCLKSOURCE_HSI))
#if defined(FDCAN1)
#define IS_RCC_FDCANCLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_FDCANCLKSOURCE_HSE) || \
((__SOURCE__) == RCC_FDCANCLKSOURCE_PLL) || \
((__SOURCE__) == RCC_FDCANCLKSOURCE_PCLK1))
#endif /* FDCAN1 */
#define IS_RCC_RNGCLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_RNGCLKSOURCE_HSI48) || \
((__SOURCE__) == RCC_RNGCLKSOURCE_PLL))
#if defined(USB)
#define IS_RCC_USBCLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_USBCLKSOURCE_HSI48) || \
((__SOURCE__) == RCC_USBCLKSOURCE_PLL))
#endif /* USB */
#define IS_RCC_ADC12CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_ADC12CLKSOURCE_NONE) || \
((__SOURCE__) == RCC_ADC12CLKSOURCE_PLL) || \
((__SOURCE__) == RCC_ADC12CLKSOURCE_SYSCLK))
#if defined(ADC345_COMMON)
#define IS_RCC_ADC345CLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_ADC345CLKSOURCE_NONE) || \
((__SOURCE__) == RCC_ADC345CLKSOURCE_PLL) || \
((__SOURCE__) == RCC_ADC345CLKSOURCE_SYSCLK))
#endif /* ADC345_COMMON */
#if defined(QUADSPI)
#define IS_RCC_QSPICLKSOURCE(__SOURCE__) \
(((__SOURCE__) == RCC_QSPICLKSOURCE_HSI) || \
((__SOURCE__) == RCC_QSPICLKSOURCE_SYSCLK)|| \
((__SOURCE__) == RCC_QSPICLKSOURCE_PLL))
#endif /* QUADSPI */
#define IS_RCC_CRS_SYNC_SOURCE(__SOURCE__) (((__SOURCE__) == RCC_CRS_SYNC_SOURCE_GPIO) || \
((__SOURCE__) == RCC_CRS_SYNC_SOURCE_LSE) || \
((__SOURCE__) == RCC_CRS_SYNC_SOURCE_USB))
#define IS_RCC_CRS_SYNC_DIV(__DIV__) (((__DIV__) == RCC_CRS_SYNC_DIV1) || ((__DIV__) == RCC_CRS_SYNC_DIV2) || \
((__DIV__) == RCC_CRS_SYNC_DIV4) || ((__DIV__) == RCC_CRS_SYNC_DIV8) || \
((__DIV__) == RCC_CRS_SYNC_DIV16) || ((__DIV__) == RCC_CRS_SYNC_DIV32) || \
((__DIV__) == RCC_CRS_SYNC_DIV64) || ((__DIV__) == RCC_CRS_SYNC_DIV128))
#define IS_RCC_CRS_SYNC_POLARITY(__POLARITY__) (((__POLARITY__) == RCC_CRS_SYNC_POLARITY_RISING) || \
((__POLARITY__) == RCC_CRS_SYNC_POLARITY_FALLING))
#define IS_RCC_CRS_RELOADVALUE(__VALUE__) (((__VALUE__) <= 0xFFFFU))
#define IS_RCC_CRS_ERRORLIMIT(__VALUE__) (((__VALUE__) <= 0xFFU))
#define IS_RCC_CRS_HSI48CALIBRATION(__VALUE__) (((__VALUE__) <= 0x3FU))
#define IS_RCC_CRS_FREQERRORDIR(__DIR__) (((__DIR__) == RCC_CRS_FREQERRORDIR_UP) || \
((__DIR__) == RCC_CRS_FREQERRORDIR_DOWN))
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_RCC_EX_H */
| 72,600 | C | 44.177971 | 173 | 0.578526 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_lpuart.h | /**
******************************************************************************
* @file stm32g4xx_ll_lpuart.h
* @author MCD Application Team
* @brief Header file of LPUART LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_LPUART_H
#define STM32G4xx_LL_LPUART_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined (LPUART1)
/** @defgroup LPUART_LL LPUART
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup LPUART_LL_Private_Variables LPUART Private Variables
* @{
*/
/* Array used to get the LPUART prescaler division decimal values versus @ref LPUART_LL_EC_PRESCALER values */
static const uint16_t LPUART_PRESCALER_TAB[] =
{
(uint16_t)1,
(uint16_t)2,
(uint16_t)4,
(uint16_t)6,
(uint16_t)8,
(uint16_t)10,
(uint16_t)12,
(uint16_t)16,
(uint16_t)32,
(uint16_t)64,
(uint16_t)128,
(uint16_t)256
};
/**
* @}
*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup LPUART_LL_Private_Constants LPUART Private Constants
* @{
*/
/* Defines used in Baud Rate related macros and corresponding register setting computation */
#define LPUART_LPUARTDIV_FREQ_MUL 256U
#define LPUART_BRR_MASK 0x000FFFFFU
#define LPUART_BRR_MIN_VALUE 0x00000300U
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup LPUART_LL_Private_Macros LPUART Private Macros
* @{
*/
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported types ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup LPUART_LL_ES_INIT LPUART Exported Init structures
* @{
*/
/**
* @brief LL LPUART Init Structure definition
*/
typedef struct
{
uint32_t PrescalerValue; /*!< Specifies the Prescaler to compute the communication baud rate.
This parameter can be a value of @ref LPUART_LL_EC_PRESCALER.
This feature can be modified afterwards using unitary
function @ref LL_LPUART_SetPrescaler().*/
uint32_t BaudRate; /*!< This field defines expected LPUART communication baud rate.
This feature can be modified afterwards using unitary
function @ref LL_LPUART_SetBaudRate().*/
uint32_t DataWidth; /*!< Specifies the number of data bits transmitted or received in a frame.
This parameter can be a value of @ref LPUART_LL_EC_DATAWIDTH.
This feature can be modified afterwards using unitary
function @ref LL_LPUART_SetDataWidth().*/
uint32_t StopBits; /*!< Specifies the number of stop bits transmitted.
This parameter can be a value of @ref LPUART_LL_EC_STOPBITS.
This feature can be modified afterwards using unitary
function @ref LL_LPUART_SetStopBitsLength().*/
uint32_t Parity; /*!< Specifies the parity mode.
This parameter can be a value of @ref LPUART_LL_EC_PARITY.
This feature can be modified afterwards using unitary
function @ref LL_LPUART_SetParity().*/
uint32_t TransferDirection; /*!< Specifies whether the Receive and/or Transmit mode is enabled or disabled.
This parameter can be a value of @ref LPUART_LL_EC_DIRECTION.
This feature can be modified afterwards using unitary
function @ref LL_LPUART_SetTransferDirection().*/
uint32_t HardwareFlowControl; /*!< Specifies whether the hardware flow control mode is enabled or disabled.
This parameter can be a value of @ref LPUART_LL_EC_HWCONTROL.
This feature can be modified afterwards using unitary
function @ref LL_LPUART_SetHWFlowCtrl().*/
} LL_LPUART_InitTypeDef;
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/* Exported constants --------------------------------------------------------*/
/** @defgroup LPUART_LL_Exported_Constants LPUART Exported Constants
* @{
*/
/** @defgroup LPUART_LL_EC_CLEAR_FLAG Clear Flags Defines
* @brief Flags defines which can be used with LL_LPUART_WriteReg function
* @{
*/
#define LL_LPUART_ICR_PECF USART_ICR_PECF /*!< Parity error clear flag */
#define LL_LPUART_ICR_FECF USART_ICR_FECF /*!< Framing error clear flag */
#define LL_LPUART_ICR_NCF USART_ICR_NECF /*!< Noise error detected clear flag */
#define LL_LPUART_ICR_ORECF USART_ICR_ORECF /*!< Overrun error clear flag */
#define LL_LPUART_ICR_IDLECF USART_ICR_IDLECF /*!< Idle line detected clear flag */
#define LL_LPUART_ICR_TCCF USART_ICR_TCCF /*!< Transmission complete clear flag */
#define LL_LPUART_ICR_CTSCF USART_ICR_CTSCF /*!< CTS clear flag */
#define LL_LPUART_ICR_CMCF USART_ICR_CMCF /*!< Character match clear flag */
#define LL_LPUART_ICR_WUCF USART_ICR_WUCF /*!< Wakeup from Stop mode clear flag */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_LPUART_ReadReg function
* @{
*/
#define LL_LPUART_ISR_PE USART_ISR_PE /*!< Parity error flag */
#define LL_LPUART_ISR_FE USART_ISR_FE /*!< Framing error flag */
#define LL_LPUART_ISR_NE USART_ISR_NE /*!< Noise detected flag */
#define LL_LPUART_ISR_ORE USART_ISR_ORE /*!< Overrun error flag */
#define LL_LPUART_ISR_IDLE USART_ISR_IDLE /*!< Idle line detected flag */
#define LL_LPUART_ISR_RXNE_RXFNE USART_ISR_RXNE_RXFNE /*!< Read data register or RX FIFO not empty flag */
#define LL_LPUART_ISR_TC USART_ISR_TC /*!< Transmission complete flag */
#define LL_LPUART_ISR_TXE_TXFNF USART_ISR_TXE_TXFNF /*!< Transmit data register empty or TX FIFO Not Full flag*/
#define LL_LPUART_ISR_CTSIF USART_ISR_CTSIF /*!< CTS interrupt flag */
#define LL_LPUART_ISR_CTS USART_ISR_CTS /*!< CTS flag */
#define LL_LPUART_ISR_BUSY USART_ISR_BUSY /*!< Busy flag */
#define LL_LPUART_ISR_CMF USART_ISR_CMF /*!< Character match flag */
#define LL_LPUART_ISR_SBKF USART_ISR_SBKF /*!< Send break flag */
#define LL_LPUART_ISR_RWU USART_ISR_RWU /*!< Receiver wakeup from Mute mode flag */
#define LL_LPUART_ISR_WUF USART_ISR_WUF /*!< Wakeup from Stop mode flag */
#define LL_LPUART_ISR_TEACK USART_ISR_TEACK /*!< Transmit enable acknowledge flag */
#define LL_LPUART_ISR_REACK USART_ISR_REACK /*!< Receive enable acknowledge flag */
#define LL_LPUART_ISR_TXFE USART_ISR_TXFE /*!< TX FIFO empty flag */
#define LL_LPUART_ISR_RXFF USART_ISR_RXFF /*!< RX FIFO full flag */
#define LL_LPUART_ISR_RXFT USART_ISR_RXFT /*!< RX FIFO threshold flag */
#define LL_LPUART_ISR_TXFT USART_ISR_TXFT /*!< TX FIFO threshold flag */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_IT IT Defines
* @brief IT defines which can be used with LL_LPUART_ReadReg and LL_LPUART_WriteReg functions
* @{
*/
#define LL_LPUART_CR1_IDLEIE USART_CR1_IDLEIE /*!< IDLE interrupt enable */
#define LL_LPUART_CR1_RXNEIE_RXFNEIE USART_CR1_RXNEIE_RXFNEIE /*!< Read data register and RXFIFO not empty
interrupt enable */
#define LL_LPUART_CR1_TCIE USART_CR1_TCIE /*!< Transmission complete interrupt enable */
#define LL_LPUART_CR1_TXEIE_TXFNFIE USART_CR1_TXEIE_TXFNFIE /*!< Transmit data register empty and TX FIFO
not full interrupt enable */
#define LL_LPUART_CR1_PEIE USART_CR1_PEIE /*!< Parity error */
#define LL_LPUART_CR1_CMIE USART_CR1_CMIE /*!< Character match interrupt enable */
#define LL_LPUART_CR1_TXFEIE USART_CR1_TXFEIE /*!< TX FIFO empty interrupt enable */
#define LL_LPUART_CR1_RXFFIE USART_CR1_RXFFIE /*!< RX FIFO full interrupt enable */
#define LL_LPUART_CR3_EIE USART_CR3_EIE /*!< Error interrupt enable */
#define LL_LPUART_CR3_CTSIE USART_CR3_CTSIE /*!< CTS interrupt enable */
#define LL_LPUART_CR3_WUFIE USART_CR3_WUFIE /*!< Wakeup from Stop mode interrupt enable */
#define LL_LPUART_CR3_TXFTIE USART_CR3_TXFTIE /*!< TX FIFO threshold interrupt enable */
#define LL_LPUART_CR3_RXFTIE USART_CR3_RXFTIE /*!< RX FIFO threshold interrupt enable */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_FIFOTHRESHOLD FIFO Threshold
* @{
*/
#define LL_LPUART_FIFOTHRESHOLD_1_8 0x00000000U /*!< FIFO reaches 1/8 of its depth */
#define LL_LPUART_FIFOTHRESHOLD_1_4 0x00000001U /*!< FIFO reaches 1/4 of its depth */
#define LL_LPUART_FIFOTHRESHOLD_1_2 0x00000002U /*!< FIFO reaches 1/2 of its depth */
#define LL_LPUART_FIFOTHRESHOLD_3_4 0x00000003U /*!< FIFO reaches 3/4 of its depth */
#define LL_LPUART_FIFOTHRESHOLD_7_8 0x00000004U /*!< FIFO reaches 7/8 of its depth */
#define LL_LPUART_FIFOTHRESHOLD_8_8 0x00000005U /*!< FIFO becomes empty for TX and full for RX */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_DIRECTION Direction
* @{
*/
#define LL_LPUART_DIRECTION_NONE 0x00000000U /*!< Transmitter and Receiver are disabled */
#define LL_LPUART_DIRECTION_RX USART_CR1_RE /*!< Transmitter is disabled and Receiver is enabled */
#define LL_LPUART_DIRECTION_TX USART_CR1_TE /*!< Transmitter is enabled and Receiver is disabled */
#define LL_LPUART_DIRECTION_TX_RX (USART_CR1_TE |USART_CR1_RE) /*!< Transmitter and Receiver are enabled */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_PARITY Parity Control
* @{
*/
#define LL_LPUART_PARITY_NONE 0x00000000U /*!< Parity control disabled */
#define LL_LPUART_PARITY_EVEN USART_CR1_PCE /*!< Parity control enabled and Even Parity is selected */
#define LL_LPUART_PARITY_ODD (USART_CR1_PCE | USART_CR1_PS) /*!< Parity control enabled and Odd Parity is selected */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_WAKEUP Wakeup
* @{
*/
#define LL_LPUART_WAKEUP_IDLELINE 0x00000000U /*!< LPUART wake up from Mute mode on Idle Line */
#define LL_LPUART_WAKEUP_ADDRESSMARK USART_CR1_WAKE /*!< LPUART wake up from Mute mode on Address Mark */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_DATAWIDTH Datawidth
* @{
*/
#define LL_LPUART_DATAWIDTH_7B USART_CR1_M1 /*!< 7 bits word length : Start bit, 7 data bits, n stop bits */
#define LL_LPUART_DATAWIDTH_8B 0x00000000U /*!< 8 bits word length : Start bit, 8 data bits, n stop bits */
#define LL_LPUART_DATAWIDTH_9B USART_CR1_M0 /*!< 9 bits word length : Start bit, 9 data bits, n stop bits */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_PRESCALER Clock Source Prescaler
* @{
*/
#define LL_LPUART_PRESCALER_DIV1 0x00000000U /*!< Input clock not divided */
#define LL_LPUART_PRESCALER_DIV2 (USART_PRESC_PRESCALER_0) /*!< Input clock divided by 2 */
#define LL_LPUART_PRESCALER_DIV4 (USART_PRESC_PRESCALER_1) /*!< Input clock divided by 4 */
#define LL_LPUART_PRESCALER_DIV6 (USART_PRESC_PRESCALER_1 |\
USART_PRESC_PRESCALER_0) /*!< Input clock divided by 6 */
#define LL_LPUART_PRESCALER_DIV8 (USART_PRESC_PRESCALER_2) /*!< Input clock divided by 8 */
#define LL_LPUART_PRESCALER_DIV10 (USART_PRESC_PRESCALER_2 |\
USART_PRESC_PRESCALER_0) /*!< Input clock divided by 10 */
#define LL_LPUART_PRESCALER_DIV12 (USART_PRESC_PRESCALER_2 |\
USART_PRESC_PRESCALER_1) /*!< Input clock divided by 12 */
#define LL_LPUART_PRESCALER_DIV16 (USART_PRESC_PRESCALER_2 |\
USART_PRESC_PRESCALER_1 |\
USART_PRESC_PRESCALER_0) /*!< Input clock divided by 16 */
#define LL_LPUART_PRESCALER_DIV32 (USART_PRESC_PRESCALER_3) /*!< Input clock divided by 32 */
#define LL_LPUART_PRESCALER_DIV64 (USART_PRESC_PRESCALER_3 |\
USART_PRESC_PRESCALER_0) /*!< Input clock divided by 64 */
#define LL_LPUART_PRESCALER_DIV128 (USART_PRESC_PRESCALER_3 |\
USART_PRESC_PRESCALER_1) /*!< Input clock divided by 128 */
#define LL_LPUART_PRESCALER_DIV256 (USART_PRESC_PRESCALER_3 |\
USART_PRESC_PRESCALER_1 |\
USART_PRESC_PRESCALER_0) /*!< Input clock divided by 256 */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_STOPBITS Stop Bits
* @{
*/
#define LL_LPUART_STOPBITS_1 0x00000000U /*!< 1 stop bit */
#define LL_LPUART_STOPBITS_2 USART_CR2_STOP_1 /*!< 2 stop bits */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_TXRX TX RX Pins Swap
* @{
*/
#define LL_LPUART_TXRX_STANDARD 0x00000000U /*!< TX/RX pins are used as defined in standard pinout */
#define LL_LPUART_TXRX_SWAPPED (USART_CR2_SWAP) /*!< TX and RX pins functions are swapped. */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_RXPIN_LEVEL RX Pin Active Level Inversion
* @{
*/
#define LL_LPUART_RXPIN_LEVEL_STANDARD 0x00000000U /*!< RX pin signal works using the standard logic levels */
#define LL_LPUART_RXPIN_LEVEL_INVERTED (USART_CR2_RXINV) /*!< RX pin signal values are inverted. */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_TXPIN_LEVEL TX Pin Active Level Inversion
* @{
*/
#define LL_LPUART_TXPIN_LEVEL_STANDARD 0x00000000U /*!< TX pin signal works using the standard logic levels */
#define LL_LPUART_TXPIN_LEVEL_INVERTED (USART_CR2_TXINV) /*!< TX pin signal values are inverted. */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_BINARY_LOGIC Binary Data Inversion
* @{
*/
#define LL_LPUART_BINARY_LOGIC_POSITIVE 0x00000000U /*!< Logical data from the data register are send/received
in positive/direct logic. (1=H, 0=L) */
#define LL_LPUART_BINARY_LOGIC_NEGATIVE USART_CR2_DATAINV /*!< Logical data from the data register are send/received
in negative/inverse logic. (1=L, 0=H).
The parity bit is also inverted. */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_BITORDER Bit Order
* @{
*/
#define LL_LPUART_BITORDER_LSBFIRST 0x00000000U /*!< data is transmitted/received with data bit 0 first,
following the start bit */
#define LL_LPUART_BITORDER_MSBFIRST USART_CR2_MSBFIRST /*!< data is transmitted/received with the MSB first,
following the start bit */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_ADDRESS_DETECT Address Length Detection
* @{
*/
#define LL_LPUART_ADDRESS_DETECT_4B 0x00000000U /*!< 4-bit address detection method selected */
#define LL_LPUART_ADDRESS_DETECT_7B USART_CR2_ADDM7 /*!< 7-bit address detection (in 8-bit data mode) method selected */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_HWCONTROL Hardware Control
* @{
*/
#define LL_LPUART_HWCONTROL_NONE 0x00000000U /*!< CTS and RTS hardware flow control disabled */
#define LL_LPUART_HWCONTROL_RTS USART_CR3_RTSE /*!< RTS output enabled, data is only requested
when there is space in the receive buffer */
#define LL_LPUART_HWCONTROL_CTS USART_CR3_CTSE /*!< CTS mode enabled, data is only transmitted
when the nCTS input is asserted (tied to 0)*/
#define LL_LPUART_HWCONTROL_RTS_CTS (USART_CR3_RTSE | USART_CR3_CTSE) /*!< CTS and RTS hardware flow control enabled */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_WAKEUP_ON Wakeup Activation
* @{
*/
#define LL_LPUART_WAKEUP_ON_ADDRESS 0x00000000U /*!< Wake up active on address match */
#define LL_LPUART_WAKEUP_ON_STARTBIT USART_CR3_WUS_1 /*!< Wake up active on Start bit detection */
#define LL_LPUART_WAKEUP_ON_RXNE (USART_CR3_WUS_0 | USART_CR3_WUS_1) /*!< Wake up active on RXNE */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_DE_POLARITY Driver Enable Polarity
* @{
*/
#define LL_LPUART_DE_POLARITY_HIGH 0x00000000U /*!< DE signal is active high */
#define LL_LPUART_DE_POLARITY_LOW USART_CR3_DEP /*!< DE signal is active low */
/**
* @}
*/
/** @defgroup LPUART_LL_EC_DMA_REG_DATA DMA Register Data
* @{
*/
#define LL_LPUART_DMA_REG_DATA_TRANSMIT 0x00000000U /*!< Get address of data register used for transmission */
#define LL_LPUART_DMA_REG_DATA_RECEIVE 0x00000001U /*!< Get address of data register used for reception */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup LPUART_LL_Exported_Macros LPUART Exported Macros
* @{
*/
/** @defgroup LPUART_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in LPUART register
* @param __INSTANCE__ LPUART Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_LPUART_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG(__INSTANCE__->__REG__, (__VALUE__))
/**
* @brief Read a value in LPUART register
* @param __INSTANCE__ LPUART Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_LPUART_ReadReg(__INSTANCE__, __REG__) READ_REG(__INSTANCE__->__REG__)
/**
* @}
*/
/** @defgroup LPUART_LL_EM_Exported_Macros_Helper Helper Macros
* @{
*/
/**
* @brief Compute LPUARTDIV value according to Peripheral Clock and
* expected Baud Rate (20-bit value of LPUARTDIV is returned)
* @param __PERIPHCLK__ Peripheral Clock frequency used for LPUART Instance
* @param __PRESCALER__ This parameter can be one of the following values:
* @arg @ref LL_LPUART_PRESCALER_DIV1
* @arg @ref LL_LPUART_PRESCALER_DIV2
* @arg @ref LL_LPUART_PRESCALER_DIV4
* @arg @ref LL_LPUART_PRESCALER_DIV6
* @arg @ref LL_LPUART_PRESCALER_DIV8
* @arg @ref LL_LPUART_PRESCALER_DIV10
* @arg @ref LL_LPUART_PRESCALER_DIV12
* @arg @ref LL_LPUART_PRESCALER_DIV16
* @arg @ref LL_LPUART_PRESCALER_DIV32
* @arg @ref LL_LPUART_PRESCALER_DIV64
* @arg @ref LL_LPUART_PRESCALER_DIV128
* @arg @ref LL_LPUART_PRESCALER_DIV256
* @param __BAUDRATE__ Baud Rate value to achieve
* @retval LPUARTDIV value to be used for BRR register filling
*/
#define __LL_LPUART_DIV(__PERIPHCLK__, __PRESCALER__, __BAUDRATE__) (uint32_t)\
((((((uint64_t)(__PERIPHCLK__)/(uint64_t)(LPUART_PRESCALER_TAB[(uint16_t)(__PRESCALER__)]))\
* LPUART_LPUARTDIV_FREQ_MUL) + (uint32_t)((__BAUDRATE__)/2U))/(__BAUDRATE__)) & LPUART_BRR_MASK)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup LPUART_LL_Exported_Functions LPUART Exported Functions
* @{
*/
/** @defgroup LPUART_LL_EF_Configuration Configuration functions
* @{
*/
/**
* @brief LPUART Enable
* @rmtoll CR1 UE LL_LPUART_Enable
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_Enable(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR1, USART_CR1_UE);
}
/**
* @brief LPUART Disable
* @note When LPUART is disabled, LPUART prescalers and outputs are stopped immediately,
* and current operations are discarded. The configuration of the LPUART is kept, but all the status
* flags, in the LPUARTx_ISR are set to their default values.
* @note In order to go into low-power mode without generating errors on the line,
* the TE bit must be reset before and the software must wait
* for the TC bit in the LPUART_ISR to be set before resetting the UE bit.
* The DMA requests are also reset when UE = 0 so the DMA channel must
* be disabled before resetting the UE bit.
* @rmtoll CR1 UE LL_LPUART_Disable
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_Disable(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR1, USART_CR1_UE);
}
/**
* @brief Indicate if LPUART is enabled
* @rmtoll CR1 UE LL_LPUART_IsEnabled
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabled(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_UE) == (USART_CR1_UE)) ? 1UL : 0UL);
}
/**
* @brief FIFO Mode Enable
* @rmtoll CR1 FIFOEN LL_LPUART_EnableFIFO
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableFIFO(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR1, USART_CR1_FIFOEN);
}
/**
* @brief FIFO Mode Disable
* @rmtoll CR1 FIFOEN LL_LPUART_DisableFIFO
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableFIFO(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR1, USART_CR1_FIFOEN);
}
/**
* @brief Indicate if FIFO Mode is enabled
* @rmtoll CR1 FIFOEN LL_LPUART_IsEnabledFIFO
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledFIFO(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_FIFOEN) == (USART_CR1_FIFOEN)) ? 1UL : 0UL);
}
/**
* @brief Configure TX FIFO Threshold
* @rmtoll CR3 TXFTCFG LL_LPUART_SetTXFIFOThreshold
* @param LPUARTx LPUART Instance
* @param Threshold This parameter can be one of the following values:
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_2
* @arg @ref LL_LPUART_FIFOTHRESHOLD_3_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_7_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_8_8
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetTXFIFOThreshold(USART_TypeDef *LPUARTx, uint32_t Threshold)
{
ATOMIC_MODIFY_REG(LPUARTx->CR3, USART_CR3_TXFTCFG, Threshold << USART_CR3_TXFTCFG_Pos);
}
/**
* @brief Return TX FIFO Threshold Configuration
* @rmtoll CR3 TXFTCFG LL_LPUART_GetTXFIFOThreshold
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_2
* @arg @ref LL_LPUART_FIFOTHRESHOLD_3_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_7_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_8_8
*/
__STATIC_INLINE uint32_t LL_LPUART_GetTXFIFOThreshold(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR3, USART_CR3_TXFTCFG) >> USART_CR3_TXFTCFG_Pos);
}
/**
* @brief Configure RX FIFO Threshold
* @rmtoll CR3 RXFTCFG LL_LPUART_SetRXFIFOThreshold
* @param LPUARTx LPUART Instance
* @param Threshold This parameter can be one of the following values:
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_2
* @arg @ref LL_LPUART_FIFOTHRESHOLD_3_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_7_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_8_8
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetRXFIFOThreshold(USART_TypeDef *LPUARTx, uint32_t Threshold)
{
ATOMIC_MODIFY_REG(LPUARTx->CR3, USART_CR3_RXFTCFG, Threshold << USART_CR3_RXFTCFG_Pos);
}
/**
* @brief Return RX FIFO Threshold Configuration
* @rmtoll CR3 RXFTCFG LL_LPUART_GetRXFIFOThreshold
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_2
* @arg @ref LL_LPUART_FIFOTHRESHOLD_3_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_7_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_8_8
*/
__STATIC_INLINE uint32_t LL_LPUART_GetRXFIFOThreshold(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR3, USART_CR3_RXFTCFG) >> USART_CR3_RXFTCFG_Pos);
}
/**
* @brief Configure TX and RX FIFOs Threshold
* @rmtoll CR3 TXFTCFG LL_LPUART_ConfigFIFOsThreshold\n
* CR3 RXFTCFG LL_LPUART_ConfigFIFOsThreshold
* @param LPUARTx LPUART Instance
* @param TXThreshold This parameter can be one of the following values:
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_2
* @arg @ref LL_LPUART_FIFOTHRESHOLD_3_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_7_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_8_8
* @param RXThreshold This parameter can be one of the following values:
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_1_2
* @arg @ref LL_LPUART_FIFOTHRESHOLD_3_4
* @arg @ref LL_LPUART_FIFOTHRESHOLD_7_8
* @arg @ref LL_LPUART_FIFOTHRESHOLD_8_8
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ConfigFIFOsThreshold(USART_TypeDef *LPUARTx, uint32_t TXThreshold, uint32_t RXThreshold)
{
ATOMIC_MODIFY_REG(LPUARTx->CR3, USART_CR3_TXFTCFG | USART_CR3_RXFTCFG, (TXThreshold << USART_CR3_TXFTCFG_Pos) | \
(RXThreshold << USART_CR3_RXFTCFG_Pos));
}
/**
* @brief LPUART enabled in STOP Mode
* @note When this function is enabled, LPUART is able to wake up the MCU from Stop mode, provided that
* LPUART clock selection is HSI or LSE in RCC.
* @rmtoll CR1 UESM LL_LPUART_EnableInStopMode
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableInStopMode(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_UESM);
}
/**
* @brief LPUART disabled in STOP Mode
* @note When this function is disabled, LPUART is not able to wake up the MCU from Stop mode
* @rmtoll CR1 UESM LL_LPUART_DisableInStopMode
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableInStopMode(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_UESM);
}
/**
* @brief Indicate if LPUART is enabled in STOP Mode
* (able to wake up MCU from Stop mode or not)
* @rmtoll CR1 UESM LL_LPUART_IsEnabledInStopMode
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledInStopMode(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_UESM) == (USART_CR1_UESM)) ? 1UL : 0UL);
}
/**
* @brief Receiver Enable (Receiver is enabled and begins searching for a start bit)
* @rmtoll CR1 RE LL_LPUART_EnableDirectionRx
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableDirectionRx(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_RE);
}
/**
* @brief Receiver Disable
* @rmtoll CR1 RE LL_LPUART_DisableDirectionRx
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableDirectionRx(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_RE);
}
/**
* @brief Transmitter Enable
* @rmtoll CR1 TE LL_LPUART_EnableDirectionTx
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableDirectionTx(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_TE);
}
/**
* @brief Transmitter Disable
* @rmtoll CR1 TE LL_LPUART_DisableDirectionTx
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableDirectionTx(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_TE);
}
/**
* @brief Configure simultaneously enabled/disabled states
* of Transmitter and Receiver
* @rmtoll CR1 RE LL_LPUART_SetTransferDirection\n
* CR1 TE LL_LPUART_SetTransferDirection
* @param LPUARTx LPUART Instance
* @param TransferDirection This parameter can be one of the following values:
* @arg @ref LL_LPUART_DIRECTION_NONE
* @arg @ref LL_LPUART_DIRECTION_RX
* @arg @ref LL_LPUART_DIRECTION_TX
* @arg @ref LL_LPUART_DIRECTION_TX_RX
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetTransferDirection(USART_TypeDef *LPUARTx, uint32_t TransferDirection)
{
ATOMIC_MODIFY_REG(LPUARTx->CR1, USART_CR1_RE | USART_CR1_TE, TransferDirection);
}
/**
* @brief Return enabled/disabled states of Transmitter and Receiver
* @rmtoll CR1 RE LL_LPUART_GetTransferDirection\n
* CR1 TE LL_LPUART_GetTransferDirection
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_DIRECTION_NONE
* @arg @ref LL_LPUART_DIRECTION_RX
* @arg @ref LL_LPUART_DIRECTION_TX
* @arg @ref LL_LPUART_DIRECTION_TX_RX
*/
__STATIC_INLINE uint32_t LL_LPUART_GetTransferDirection(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR1, USART_CR1_RE | USART_CR1_TE));
}
/**
* @brief Configure Parity (enabled/disabled and parity mode if enabled)
* @note This function selects if hardware parity control (generation and detection) is enabled or disabled.
* When the parity control is enabled (Odd or Even), computed parity bit is inserted at the MSB position
* (depending on data width) and parity is checked on the received data.
* @rmtoll CR1 PS LL_LPUART_SetParity\n
* CR1 PCE LL_LPUART_SetParity
* @param LPUARTx LPUART Instance
* @param Parity This parameter can be one of the following values:
* @arg @ref LL_LPUART_PARITY_NONE
* @arg @ref LL_LPUART_PARITY_EVEN
* @arg @ref LL_LPUART_PARITY_ODD
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetParity(USART_TypeDef *LPUARTx, uint32_t Parity)
{
MODIFY_REG(LPUARTx->CR1, USART_CR1_PS | USART_CR1_PCE, Parity);
}
/**
* @brief Return Parity configuration (enabled/disabled and parity mode if enabled)
* @rmtoll CR1 PS LL_LPUART_GetParity\n
* CR1 PCE LL_LPUART_GetParity
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_PARITY_NONE
* @arg @ref LL_LPUART_PARITY_EVEN
* @arg @ref LL_LPUART_PARITY_ODD
*/
__STATIC_INLINE uint32_t LL_LPUART_GetParity(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR1, USART_CR1_PS | USART_CR1_PCE));
}
/**
* @brief Set Receiver Wake Up method from Mute mode.
* @rmtoll CR1 WAKE LL_LPUART_SetWakeUpMethod
* @param LPUARTx LPUART Instance
* @param Method This parameter can be one of the following values:
* @arg @ref LL_LPUART_WAKEUP_IDLELINE
* @arg @ref LL_LPUART_WAKEUP_ADDRESSMARK
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetWakeUpMethod(USART_TypeDef *LPUARTx, uint32_t Method)
{
MODIFY_REG(LPUARTx->CR1, USART_CR1_WAKE, Method);
}
/**
* @brief Return Receiver Wake Up method from Mute mode
* @rmtoll CR1 WAKE LL_LPUART_GetWakeUpMethod
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_WAKEUP_IDLELINE
* @arg @ref LL_LPUART_WAKEUP_ADDRESSMARK
*/
__STATIC_INLINE uint32_t LL_LPUART_GetWakeUpMethod(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR1, USART_CR1_WAKE));
}
/**
* @brief Set Word length (nb of data bits, excluding start and stop bits)
* @rmtoll CR1 M LL_LPUART_SetDataWidth
* @param LPUARTx LPUART Instance
* @param DataWidth This parameter can be one of the following values:
* @arg @ref LL_LPUART_DATAWIDTH_7B
* @arg @ref LL_LPUART_DATAWIDTH_8B
* @arg @ref LL_LPUART_DATAWIDTH_9B
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetDataWidth(USART_TypeDef *LPUARTx, uint32_t DataWidth)
{
MODIFY_REG(LPUARTx->CR1, USART_CR1_M, DataWidth);
}
/**
* @brief Return Word length (i.e. nb of data bits, excluding start and stop bits)
* @rmtoll CR1 M LL_LPUART_GetDataWidth
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_DATAWIDTH_7B
* @arg @ref LL_LPUART_DATAWIDTH_8B
* @arg @ref LL_LPUART_DATAWIDTH_9B
*/
__STATIC_INLINE uint32_t LL_LPUART_GetDataWidth(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR1, USART_CR1_M));
}
/**
* @brief Allow switch between Mute Mode and Active mode
* @rmtoll CR1 MME LL_LPUART_EnableMuteMode
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableMuteMode(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_MME);
}
/**
* @brief Prevent Mute Mode use. Set Receiver in active mode permanently.
* @rmtoll CR1 MME LL_LPUART_DisableMuteMode
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableMuteMode(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_MME);
}
/**
* @brief Indicate if switch between Mute Mode and Active mode is allowed
* @rmtoll CR1 MME LL_LPUART_IsEnabledMuteMode
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledMuteMode(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_MME) == (USART_CR1_MME)) ? 1UL : 0UL);
}
/**
* @brief Configure Clock source prescaler for baudrate generator and oversampling
* @rmtoll PRESC PRESCALER LL_LPUART_SetPrescaler
* @param LPUARTx LPUART Instance
* @param PrescalerValue This parameter can be one of the following values:
* @arg @ref LL_LPUART_PRESCALER_DIV1
* @arg @ref LL_LPUART_PRESCALER_DIV2
* @arg @ref LL_LPUART_PRESCALER_DIV4
* @arg @ref LL_LPUART_PRESCALER_DIV6
* @arg @ref LL_LPUART_PRESCALER_DIV8
* @arg @ref LL_LPUART_PRESCALER_DIV10
* @arg @ref LL_LPUART_PRESCALER_DIV12
* @arg @ref LL_LPUART_PRESCALER_DIV16
* @arg @ref LL_LPUART_PRESCALER_DIV32
* @arg @ref LL_LPUART_PRESCALER_DIV64
* @arg @ref LL_LPUART_PRESCALER_DIV128
* @arg @ref LL_LPUART_PRESCALER_DIV256
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetPrescaler(USART_TypeDef *LPUARTx, uint32_t PrescalerValue)
{
MODIFY_REG(LPUARTx->PRESC, USART_PRESC_PRESCALER, (uint16_t)PrescalerValue);
}
/**
* @brief Retrieve the Clock source prescaler for baudrate generator and oversampling
* @rmtoll PRESC PRESCALER LL_LPUART_GetPrescaler
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_PRESCALER_DIV1
* @arg @ref LL_LPUART_PRESCALER_DIV2
* @arg @ref LL_LPUART_PRESCALER_DIV4
* @arg @ref LL_LPUART_PRESCALER_DIV6
* @arg @ref LL_LPUART_PRESCALER_DIV8
* @arg @ref LL_LPUART_PRESCALER_DIV10
* @arg @ref LL_LPUART_PRESCALER_DIV12
* @arg @ref LL_LPUART_PRESCALER_DIV16
* @arg @ref LL_LPUART_PRESCALER_DIV32
* @arg @ref LL_LPUART_PRESCALER_DIV64
* @arg @ref LL_LPUART_PRESCALER_DIV128
* @arg @ref LL_LPUART_PRESCALER_DIV256
*/
__STATIC_INLINE uint32_t LL_LPUART_GetPrescaler(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->PRESC, USART_PRESC_PRESCALER));
}
/**
* @brief Set the length of the stop bits
* @rmtoll CR2 STOP LL_LPUART_SetStopBitsLength
* @param LPUARTx LPUART Instance
* @param StopBits This parameter can be one of the following values:
* @arg @ref LL_LPUART_STOPBITS_1
* @arg @ref LL_LPUART_STOPBITS_2
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetStopBitsLength(USART_TypeDef *LPUARTx, uint32_t StopBits)
{
MODIFY_REG(LPUARTx->CR2, USART_CR2_STOP, StopBits);
}
/**
* @brief Retrieve the length of the stop bits
* @rmtoll CR2 STOP LL_LPUART_GetStopBitsLength
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_STOPBITS_1
* @arg @ref LL_LPUART_STOPBITS_2
*/
__STATIC_INLINE uint32_t LL_LPUART_GetStopBitsLength(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_STOP));
}
/**
* @brief Configure Character frame format (Datawidth, Parity control, Stop Bits)
* @note Call of this function is equivalent to following function call sequence :
* - Data Width configuration using @ref LL_LPUART_SetDataWidth() function
* - Parity Control and mode configuration using @ref LL_LPUART_SetParity() function
* - Stop bits configuration using @ref LL_LPUART_SetStopBitsLength() function
* @rmtoll CR1 PS LL_LPUART_ConfigCharacter\n
* CR1 PCE LL_LPUART_ConfigCharacter\n
* CR1 M LL_LPUART_ConfigCharacter\n
* CR2 STOP LL_LPUART_ConfigCharacter
* @param LPUARTx LPUART Instance
* @param DataWidth This parameter can be one of the following values:
* @arg @ref LL_LPUART_DATAWIDTH_7B
* @arg @ref LL_LPUART_DATAWIDTH_8B
* @arg @ref LL_LPUART_DATAWIDTH_9B
* @param Parity This parameter can be one of the following values:
* @arg @ref LL_LPUART_PARITY_NONE
* @arg @ref LL_LPUART_PARITY_EVEN
* @arg @ref LL_LPUART_PARITY_ODD
* @param StopBits This parameter can be one of the following values:
* @arg @ref LL_LPUART_STOPBITS_1
* @arg @ref LL_LPUART_STOPBITS_2
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ConfigCharacter(USART_TypeDef *LPUARTx, uint32_t DataWidth, uint32_t Parity,
uint32_t StopBits)
{
MODIFY_REG(LPUARTx->CR1, USART_CR1_PS | USART_CR1_PCE | USART_CR1_M, Parity | DataWidth);
MODIFY_REG(LPUARTx->CR2, USART_CR2_STOP, StopBits);
}
/**
* @brief Configure TX/RX pins swapping setting.
* @rmtoll CR2 SWAP LL_LPUART_SetTXRXSwap
* @param LPUARTx LPUART Instance
* @param SwapConfig This parameter can be one of the following values:
* @arg @ref LL_LPUART_TXRX_STANDARD
* @arg @ref LL_LPUART_TXRX_SWAPPED
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetTXRXSwap(USART_TypeDef *LPUARTx, uint32_t SwapConfig)
{
MODIFY_REG(LPUARTx->CR2, USART_CR2_SWAP, SwapConfig);
}
/**
* @brief Retrieve TX/RX pins swapping configuration.
* @rmtoll CR2 SWAP LL_LPUART_GetTXRXSwap
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_TXRX_STANDARD
* @arg @ref LL_LPUART_TXRX_SWAPPED
*/
__STATIC_INLINE uint32_t LL_LPUART_GetTXRXSwap(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_SWAP));
}
/**
* @brief Configure RX pin active level logic
* @rmtoll CR2 RXINV LL_LPUART_SetRXPinLevel
* @param LPUARTx LPUART Instance
* @param PinInvMethod This parameter can be one of the following values:
* @arg @ref LL_LPUART_RXPIN_LEVEL_STANDARD
* @arg @ref LL_LPUART_RXPIN_LEVEL_INVERTED
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetRXPinLevel(USART_TypeDef *LPUARTx, uint32_t PinInvMethod)
{
MODIFY_REG(LPUARTx->CR2, USART_CR2_RXINV, PinInvMethod);
}
/**
* @brief Retrieve RX pin active level logic configuration
* @rmtoll CR2 RXINV LL_LPUART_GetRXPinLevel
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_RXPIN_LEVEL_STANDARD
* @arg @ref LL_LPUART_RXPIN_LEVEL_INVERTED
*/
__STATIC_INLINE uint32_t LL_LPUART_GetRXPinLevel(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_RXINV));
}
/**
* @brief Configure TX pin active level logic
* @rmtoll CR2 TXINV LL_LPUART_SetTXPinLevel
* @param LPUARTx LPUART Instance
* @param PinInvMethod This parameter can be one of the following values:
* @arg @ref LL_LPUART_TXPIN_LEVEL_STANDARD
* @arg @ref LL_LPUART_TXPIN_LEVEL_INVERTED
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetTXPinLevel(USART_TypeDef *LPUARTx, uint32_t PinInvMethod)
{
MODIFY_REG(LPUARTx->CR2, USART_CR2_TXINV, PinInvMethod);
}
/**
* @brief Retrieve TX pin active level logic configuration
* @rmtoll CR2 TXINV LL_LPUART_GetTXPinLevel
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_TXPIN_LEVEL_STANDARD
* @arg @ref LL_LPUART_TXPIN_LEVEL_INVERTED
*/
__STATIC_INLINE uint32_t LL_LPUART_GetTXPinLevel(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_TXINV));
}
/**
* @brief Configure Binary data logic.
*
* @note Allow to define how Logical data from the data register are send/received :
* either in positive/direct logic (1=H, 0=L) or in negative/inverse logic (1=L, 0=H)
* @rmtoll CR2 DATAINV LL_LPUART_SetBinaryDataLogic
* @param LPUARTx LPUART Instance
* @param DataLogic This parameter can be one of the following values:
* @arg @ref LL_LPUART_BINARY_LOGIC_POSITIVE
* @arg @ref LL_LPUART_BINARY_LOGIC_NEGATIVE
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetBinaryDataLogic(USART_TypeDef *LPUARTx, uint32_t DataLogic)
{
MODIFY_REG(LPUARTx->CR2, USART_CR2_DATAINV, DataLogic);
}
/**
* @brief Retrieve Binary data configuration
* @rmtoll CR2 DATAINV LL_LPUART_GetBinaryDataLogic
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_BINARY_LOGIC_POSITIVE
* @arg @ref LL_LPUART_BINARY_LOGIC_NEGATIVE
*/
__STATIC_INLINE uint32_t LL_LPUART_GetBinaryDataLogic(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_DATAINV));
}
/**
* @brief Configure transfer bit order (either Less or Most Significant Bit First)
* @note MSB First means data is transmitted/received with the MSB first, following the start bit.
* LSB First means data is transmitted/received with data bit 0 first, following the start bit.
* @rmtoll CR2 MSBFIRST LL_LPUART_SetTransferBitOrder
* @param LPUARTx LPUART Instance
* @param BitOrder This parameter can be one of the following values:
* @arg @ref LL_LPUART_BITORDER_LSBFIRST
* @arg @ref LL_LPUART_BITORDER_MSBFIRST
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetTransferBitOrder(USART_TypeDef *LPUARTx, uint32_t BitOrder)
{
MODIFY_REG(LPUARTx->CR2, USART_CR2_MSBFIRST, BitOrder);
}
/**
* @brief Return transfer bit order (either Less or Most Significant Bit First)
* @note MSB First means data is transmitted/received with the MSB first, following the start bit.
* LSB First means data is transmitted/received with data bit 0 first, following the start bit.
* @rmtoll CR2 MSBFIRST LL_LPUART_GetTransferBitOrder
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_BITORDER_LSBFIRST
* @arg @ref LL_LPUART_BITORDER_MSBFIRST
*/
__STATIC_INLINE uint32_t LL_LPUART_GetTransferBitOrder(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_MSBFIRST));
}
/**
* @brief Set Address of the LPUART node.
* @note This is used in multiprocessor communication during Mute mode or Stop mode,
* for wake up with address mark detection.
* @note 4bits address node is used when 4-bit Address Detection is selected in ADDM7.
* (b7-b4 should be set to 0)
* 8bits address node is used when 7-bit Address Detection is selected in ADDM7.
* (This is used in multiprocessor communication during Mute mode or Stop mode,
* for wake up with 7-bit address mark detection.
* The MSB of the character sent by the transmitter should be equal to 1.
* It may also be used for character detection during normal reception,
* Mute mode inactive (for example, end of block detection in ModBus protocol).
* In this case, the whole received character (8-bit) is compared to the ADD[7:0]
* value and CMF flag is set on match)
* @rmtoll CR2 ADD LL_LPUART_ConfigNodeAddress\n
* CR2 ADDM7 LL_LPUART_ConfigNodeAddress
* @param LPUARTx LPUART Instance
* @param AddressLen This parameter can be one of the following values:
* @arg @ref LL_LPUART_ADDRESS_DETECT_4B
* @arg @ref LL_LPUART_ADDRESS_DETECT_7B
* @param NodeAddress 4 or 7 bit Address of the LPUART node.
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ConfigNodeAddress(USART_TypeDef *LPUARTx, uint32_t AddressLen, uint32_t NodeAddress)
{
MODIFY_REG(LPUARTx->CR2, USART_CR2_ADD | USART_CR2_ADDM7,
(uint32_t)(AddressLen | (NodeAddress << USART_CR2_ADD_Pos)));
}
/**
* @brief Return 8 bit Address of the LPUART node as set in ADD field of CR2.
* @note If 4-bit Address Detection is selected in ADDM7,
* only 4bits (b3-b0) of returned value are relevant (b31-b4 are not relevant)
* If 7-bit Address Detection is selected in ADDM7,
* only 8bits (b7-b0) of returned value are relevant (b31-b8 are not relevant)
* @rmtoll CR2 ADD LL_LPUART_GetNodeAddress
* @param LPUARTx LPUART Instance
* @retval Address of the LPUART node (Value between Min_Data=0 and Max_Data=255)
*/
__STATIC_INLINE uint32_t LL_LPUART_GetNodeAddress(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_ADD) >> USART_CR2_ADD_Pos);
}
/**
* @brief Return Length of Node Address used in Address Detection mode (7-bit or 4-bit)
* @rmtoll CR2 ADDM7 LL_LPUART_GetNodeAddressLen
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_ADDRESS_DETECT_4B
* @arg @ref LL_LPUART_ADDRESS_DETECT_7B
*/
__STATIC_INLINE uint32_t LL_LPUART_GetNodeAddressLen(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR2, USART_CR2_ADDM7));
}
/**
* @brief Enable RTS HW Flow Control
* @rmtoll CR3 RTSE LL_LPUART_EnableRTSHWFlowCtrl
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableRTSHWFlowCtrl(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR3, USART_CR3_RTSE);
}
/**
* @brief Disable RTS HW Flow Control
* @rmtoll CR3 RTSE LL_LPUART_DisableRTSHWFlowCtrl
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableRTSHWFlowCtrl(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR3, USART_CR3_RTSE);
}
/**
* @brief Enable CTS HW Flow Control
* @rmtoll CR3 CTSE LL_LPUART_EnableCTSHWFlowCtrl
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableCTSHWFlowCtrl(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR3, USART_CR3_CTSE);
}
/**
* @brief Disable CTS HW Flow Control
* @rmtoll CR3 CTSE LL_LPUART_DisableCTSHWFlowCtrl
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableCTSHWFlowCtrl(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR3, USART_CR3_CTSE);
}
/**
* @brief Configure HW Flow Control mode (both CTS and RTS)
* @rmtoll CR3 RTSE LL_LPUART_SetHWFlowCtrl\n
* CR3 CTSE LL_LPUART_SetHWFlowCtrl
* @param LPUARTx LPUART Instance
* @param HardwareFlowControl This parameter can be one of the following values:
* @arg @ref LL_LPUART_HWCONTROL_NONE
* @arg @ref LL_LPUART_HWCONTROL_RTS
* @arg @ref LL_LPUART_HWCONTROL_CTS
* @arg @ref LL_LPUART_HWCONTROL_RTS_CTS
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetHWFlowCtrl(USART_TypeDef *LPUARTx, uint32_t HardwareFlowControl)
{
MODIFY_REG(LPUARTx->CR3, USART_CR3_RTSE | USART_CR3_CTSE, HardwareFlowControl);
}
/**
* @brief Return HW Flow Control configuration (both CTS and RTS)
* @rmtoll CR3 RTSE LL_LPUART_GetHWFlowCtrl\n
* CR3 CTSE LL_LPUART_GetHWFlowCtrl
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_HWCONTROL_NONE
* @arg @ref LL_LPUART_HWCONTROL_RTS
* @arg @ref LL_LPUART_HWCONTROL_CTS
* @arg @ref LL_LPUART_HWCONTROL_RTS_CTS
*/
__STATIC_INLINE uint32_t LL_LPUART_GetHWFlowCtrl(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR3, USART_CR3_RTSE | USART_CR3_CTSE));
}
/**
* @brief Enable Overrun detection
* @rmtoll CR3 OVRDIS LL_LPUART_EnableOverrunDetect
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableOverrunDetect(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR3, USART_CR3_OVRDIS);
}
/**
* @brief Disable Overrun detection
* @rmtoll CR3 OVRDIS LL_LPUART_DisableOverrunDetect
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableOverrunDetect(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR3, USART_CR3_OVRDIS);
}
/**
* @brief Indicate if Overrun detection is enabled
* @rmtoll CR3 OVRDIS LL_LPUART_IsEnabledOverrunDetect
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledOverrunDetect(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_OVRDIS) != USART_CR3_OVRDIS) ? 1UL : 0UL);
}
/**
* @brief Select event type for Wake UP Interrupt Flag (WUS[1:0] bits)
* @rmtoll CR3 WUS LL_LPUART_SetWKUPType
* @param LPUARTx LPUART Instance
* @param Type This parameter can be one of the following values:
* @arg @ref LL_LPUART_WAKEUP_ON_ADDRESS
* @arg @ref LL_LPUART_WAKEUP_ON_STARTBIT
* @arg @ref LL_LPUART_WAKEUP_ON_RXNE
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetWKUPType(USART_TypeDef *LPUARTx, uint32_t Type)
{
MODIFY_REG(LPUARTx->CR3, USART_CR3_WUS, Type);
}
/**
* @brief Return event type for Wake UP Interrupt Flag (WUS[1:0] bits)
* @rmtoll CR3 WUS LL_LPUART_GetWKUPType
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_WAKEUP_ON_ADDRESS
* @arg @ref LL_LPUART_WAKEUP_ON_STARTBIT
* @arg @ref LL_LPUART_WAKEUP_ON_RXNE
*/
__STATIC_INLINE uint32_t LL_LPUART_GetWKUPType(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR3, USART_CR3_WUS));
}
/**
* @brief Configure LPUART BRR register for achieving expected Baud Rate value.
*
* @note Compute and set LPUARTDIV value in BRR Register (full BRR content)
* according to used Peripheral Clock and expected Baud Rate values
* @note Peripheral clock and Baud Rate values provided as function parameters should be valid
* (Baud rate value != 0).
* @note Provided that LPUARTx_BRR must be > = 0x300 and LPUART_BRR is 20-bit,
* a care should be taken when generating high baud rates using high PeriphClk
* values. PeriphClk must be in the range [3 x BaudRate, 4096 x BaudRate].
* @rmtoll BRR BRR LL_LPUART_SetBaudRate
* @param LPUARTx LPUART Instance
* @param PeriphClk Peripheral Clock
* @param PrescalerValue This parameter can be one of the following values:
* @arg @ref LL_LPUART_PRESCALER_DIV1
* @arg @ref LL_LPUART_PRESCALER_DIV2
* @arg @ref LL_LPUART_PRESCALER_DIV4
* @arg @ref LL_LPUART_PRESCALER_DIV6
* @arg @ref LL_LPUART_PRESCALER_DIV8
* @arg @ref LL_LPUART_PRESCALER_DIV10
* @arg @ref LL_LPUART_PRESCALER_DIV12
* @arg @ref LL_LPUART_PRESCALER_DIV16
* @arg @ref LL_LPUART_PRESCALER_DIV32
* @arg @ref LL_LPUART_PRESCALER_DIV64
* @arg @ref LL_LPUART_PRESCALER_DIV128
* @arg @ref LL_LPUART_PRESCALER_DIV256
* @param BaudRate Baud Rate
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetBaudRate(USART_TypeDef *LPUARTx, uint32_t PeriphClk, uint32_t PrescalerValue,
uint32_t BaudRate)
{
if (BaudRate != 0U)
{
LPUARTx->BRR = __LL_LPUART_DIV(PeriphClk, PrescalerValue, BaudRate);
}
}
/**
* @brief Return current Baud Rate value, according to LPUARTDIV present in BRR register
* (full BRR content), and to used Peripheral Clock values
* @note In case of non-initialized or invalid value stored in BRR register, value 0 will be returned.
* @rmtoll BRR BRR LL_LPUART_GetBaudRate
* @param LPUARTx LPUART Instance
* @param PeriphClk Peripheral Clock
* @param PrescalerValue This parameter can be one of the following values:
* @arg @ref LL_LPUART_PRESCALER_DIV1
* @arg @ref LL_LPUART_PRESCALER_DIV2
* @arg @ref LL_LPUART_PRESCALER_DIV4
* @arg @ref LL_LPUART_PRESCALER_DIV6
* @arg @ref LL_LPUART_PRESCALER_DIV8
* @arg @ref LL_LPUART_PRESCALER_DIV10
* @arg @ref LL_LPUART_PRESCALER_DIV12
* @arg @ref LL_LPUART_PRESCALER_DIV16
* @arg @ref LL_LPUART_PRESCALER_DIV32
* @arg @ref LL_LPUART_PRESCALER_DIV64
* @arg @ref LL_LPUART_PRESCALER_DIV128
* @arg @ref LL_LPUART_PRESCALER_DIV256
* @retval Baud Rate
*/
__STATIC_INLINE uint32_t LL_LPUART_GetBaudRate(const USART_TypeDef *LPUARTx, uint32_t PeriphClk,
uint32_t PrescalerValue)
{
uint32_t lpuartdiv;
uint32_t brrresult;
uint32_t periphclkpresc = (uint32_t)(PeriphClk / (LPUART_PRESCALER_TAB[(uint16_t)PrescalerValue]));
lpuartdiv = LPUARTx->BRR & LPUART_BRR_MASK;
if (lpuartdiv >= LPUART_BRR_MIN_VALUE)
{
brrresult = (uint32_t)(((uint64_t)(periphclkpresc) * LPUART_LPUARTDIV_FREQ_MUL) / lpuartdiv);
}
else
{
brrresult = 0x0UL;
}
return (brrresult);
}
/**
* @}
*/
/** @defgroup LPUART_LL_EF_Configuration_HalfDuplex Configuration functions related to Half Duplex feature
* @{
*/
/**
* @brief Enable Single Wire Half-Duplex mode
* @rmtoll CR3 HDSEL LL_LPUART_EnableHalfDuplex
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableHalfDuplex(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR3, USART_CR3_HDSEL);
}
/**
* @brief Disable Single Wire Half-Duplex mode
* @rmtoll CR3 HDSEL LL_LPUART_DisableHalfDuplex
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableHalfDuplex(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR3, USART_CR3_HDSEL);
}
/**
* @brief Indicate if Single Wire Half-Duplex mode is enabled
* @rmtoll CR3 HDSEL LL_LPUART_IsEnabledHalfDuplex
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledHalfDuplex(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_HDSEL) == (USART_CR3_HDSEL)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup LPUART_LL_EF_Configuration_DE Configuration functions related to Driver Enable feature
* @{
*/
/**
* @brief Set DEDT (Driver Enable De-Assertion Time), Time value expressed on 5 bits ([4:0] bits).
* @rmtoll CR1 DEDT LL_LPUART_SetDEDeassertionTime
* @param LPUARTx LPUART Instance
* @param Time Value between Min_Data=0 and Max_Data=31
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetDEDeassertionTime(USART_TypeDef *LPUARTx, uint32_t Time)
{
MODIFY_REG(LPUARTx->CR1, USART_CR1_DEDT, Time << USART_CR1_DEDT_Pos);
}
/**
* @brief Return DEDT (Driver Enable De-Assertion Time)
* @rmtoll CR1 DEDT LL_LPUART_GetDEDeassertionTime
* @param LPUARTx LPUART Instance
* @retval Time value expressed on 5 bits ([4:0] bits) : c
*/
__STATIC_INLINE uint32_t LL_LPUART_GetDEDeassertionTime(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR1, USART_CR1_DEDT) >> USART_CR1_DEDT_Pos);
}
/**
* @brief Set DEAT (Driver Enable Assertion Time), Time value expressed on 5 bits ([4:0] bits).
* @rmtoll CR1 DEAT LL_LPUART_SetDEAssertionTime
* @param LPUARTx LPUART Instance
* @param Time Value between Min_Data=0 and Max_Data=31
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetDEAssertionTime(USART_TypeDef *LPUARTx, uint32_t Time)
{
MODIFY_REG(LPUARTx->CR1, USART_CR1_DEAT, Time << USART_CR1_DEAT_Pos);
}
/**
* @brief Return DEAT (Driver Enable Assertion Time)
* @rmtoll CR1 DEAT LL_LPUART_GetDEAssertionTime
* @param LPUARTx LPUART Instance
* @retval Time value expressed on 5 bits ([4:0] bits) : Time Value between Min_Data=0 and Max_Data=31
*/
__STATIC_INLINE uint32_t LL_LPUART_GetDEAssertionTime(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR1, USART_CR1_DEAT) >> USART_CR1_DEAT_Pos);
}
/**
* @brief Enable Driver Enable (DE) Mode
* @rmtoll CR3 DEM LL_LPUART_EnableDEMode
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableDEMode(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR3, USART_CR3_DEM);
}
/**
* @brief Disable Driver Enable (DE) Mode
* @rmtoll CR3 DEM LL_LPUART_DisableDEMode
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableDEMode(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR3, USART_CR3_DEM);
}
/**
* @brief Indicate if Driver Enable (DE) Mode is enabled
* @rmtoll CR3 DEM LL_LPUART_IsEnabledDEMode
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledDEMode(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_DEM) == (USART_CR3_DEM)) ? 1UL : 0UL);
}
/**
* @brief Select Driver Enable Polarity
* @rmtoll CR3 DEP LL_LPUART_SetDESignalPolarity
* @param LPUARTx LPUART Instance
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_LPUART_DE_POLARITY_HIGH
* @arg @ref LL_LPUART_DE_POLARITY_LOW
* @retval None
*/
__STATIC_INLINE void LL_LPUART_SetDESignalPolarity(USART_TypeDef *LPUARTx, uint32_t Polarity)
{
MODIFY_REG(LPUARTx->CR3, USART_CR3_DEP, Polarity);
}
/**
* @brief Return Driver Enable Polarity
* @rmtoll CR3 DEP LL_LPUART_GetDESignalPolarity
* @param LPUARTx LPUART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_LPUART_DE_POLARITY_HIGH
* @arg @ref LL_LPUART_DE_POLARITY_LOW
*/
__STATIC_INLINE uint32_t LL_LPUART_GetDESignalPolarity(const USART_TypeDef *LPUARTx)
{
return (uint32_t)(READ_BIT(LPUARTx->CR3, USART_CR3_DEP));
}
/**
* @}
*/
/** @defgroup LPUART_LL_EF_FLAG_Management FLAG_Management
* @{
*/
/**
* @brief Check if the LPUART Parity Error Flag is set or not
* @rmtoll ISR PE LL_LPUART_IsActiveFlag_PE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_PE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_PE) == (USART_ISR_PE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Framing Error Flag is set or not
* @rmtoll ISR FE LL_LPUART_IsActiveFlag_FE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_FE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_FE) == (USART_ISR_FE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Noise error detected Flag is set or not
* @rmtoll ISR NE LL_LPUART_IsActiveFlag_NE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_NE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_NE) == (USART_ISR_NE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART OverRun Error Flag is set or not
* @rmtoll ISR ORE LL_LPUART_IsActiveFlag_ORE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_ORE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_ORE) == (USART_ISR_ORE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART IDLE line detected Flag is set or not
* @rmtoll ISR IDLE LL_LPUART_IsActiveFlag_IDLE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_IDLE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_IDLE) == (USART_ISR_IDLE)) ? 1UL : 0UL);
}
#define LL_LPUART_IsActiveFlag_RXNE LL_LPUART_IsActiveFlag_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Check if the LPUART Read Data Register or LPUART RX FIFO Not Empty Flag is set or not
* @rmtoll ISR RXNE_RXFNE LL_LPUART_IsActiveFlag_RXNE_RXFNE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_RXNE_RXFNE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_RXNE_RXFNE) == (USART_ISR_RXNE_RXFNE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Transmission Complete Flag is set or not
* @rmtoll ISR TC LL_LPUART_IsActiveFlag_TC
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_TC(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_TC) == (USART_ISR_TC)) ? 1UL : 0UL);
}
#define LL_LPUART_IsActiveFlag_TXE LL_LPUART_IsActiveFlag_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Check if the LPUART Transmit Data Register Empty or LPUART TX FIFO Not Full Flag is set or not
* @rmtoll ISR TXE_TXFNF LL_LPUART_IsActiveFlag_TXE_TXFNF
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_TXE_TXFNF(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_TXE_TXFNF) == (USART_ISR_TXE_TXFNF)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART CTS interrupt Flag is set or not
* @rmtoll ISR CTSIF LL_LPUART_IsActiveFlag_nCTS
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_nCTS(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_CTSIF) == (USART_ISR_CTSIF)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART CTS Flag is set or not
* @rmtoll ISR CTS LL_LPUART_IsActiveFlag_CTS
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_CTS(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_CTS) == (USART_ISR_CTS)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Busy Flag is set or not
* @rmtoll ISR BUSY LL_LPUART_IsActiveFlag_BUSY
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_BUSY(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_BUSY) == (USART_ISR_BUSY)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Character Match Flag is set or not
* @rmtoll ISR CMF LL_LPUART_IsActiveFlag_CM
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_CM(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_CMF) == (USART_ISR_CMF)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Send Break Flag is set or not
* @rmtoll ISR SBKF LL_LPUART_IsActiveFlag_SBK
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_SBK(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_SBKF) == (USART_ISR_SBKF)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Receive Wake Up from mute mode Flag is set or not
* @rmtoll ISR RWU LL_LPUART_IsActiveFlag_RWU
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_RWU(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_RWU) == (USART_ISR_RWU)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Wake Up from stop mode Flag is set or not
* @rmtoll ISR WUF LL_LPUART_IsActiveFlag_WKUP
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_WKUP(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_WUF) == (USART_ISR_WUF)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Transmit Enable Acknowledge Flag is set or not
* @rmtoll ISR TEACK LL_LPUART_IsActiveFlag_TEACK
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_TEACK(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_TEACK) == (USART_ISR_TEACK)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Receive Enable Acknowledge Flag is set or not
* @rmtoll ISR REACK LL_LPUART_IsActiveFlag_REACK
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_REACK(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_REACK) == (USART_ISR_REACK)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART TX FIFO Empty Flag is set or not
* @rmtoll ISR TXFE LL_LPUART_IsActiveFlag_TXFE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_TXFE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_TXFE) == (USART_ISR_TXFE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART RX FIFO Full Flag is set or not
* @rmtoll ISR RXFF LL_LPUART_IsActiveFlag_RXFF
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_RXFF(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_RXFF) == (USART_ISR_RXFF)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART TX FIFO Threshold Flag is set or not
* @rmtoll ISR TXFT LL_LPUART_IsActiveFlag_TXFT
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_TXFT(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_TXFT) == (USART_ISR_TXFT)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART RX FIFO Threshold Flag is set or not
* @rmtoll ISR RXFT LL_LPUART_IsActiveFlag_RXFT
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsActiveFlag_RXFT(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->ISR, USART_ISR_RXFT) == (USART_ISR_RXFT)) ? 1UL : 0UL);
}
/**
* @brief Clear Parity Error Flag
* @rmtoll ICR PECF LL_LPUART_ClearFlag_PE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_PE(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_PECF);
}
/**
* @brief Clear Framing Error Flag
* @rmtoll ICR FECF LL_LPUART_ClearFlag_FE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_FE(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_FECF);
}
/**
* @brief Clear Noise detected Flag
* @rmtoll ICR NECF LL_LPUART_ClearFlag_NE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_NE(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_NECF);
}
/**
* @brief Clear OverRun Error Flag
* @rmtoll ICR ORECF LL_LPUART_ClearFlag_ORE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_ORE(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_ORECF);
}
/**
* @brief Clear IDLE line detected Flag
* @rmtoll ICR IDLECF LL_LPUART_ClearFlag_IDLE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_IDLE(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_IDLECF);
}
/**
* @brief Clear Transmission Complete Flag
* @rmtoll ICR TCCF LL_LPUART_ClearFlag_TC
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_TC(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_TCCF);
}
/**
* @brief Clear CTS Interrupt Flag
* @rmtoll ICR CTSCF LL_LPUART_ClearFlag_nCTS
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_nCTS(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_CTSCF);
}
/**
* @brief Clear Character Match Flag
* @rmtoll ICR CMCF LL_LPUART_ClearFlag_CM
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_CM(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_CMCF);
}
/**
* @brief Clear Wake Up from stop mode Flag
* @rmtoll ICR WUCF LL_LPUART_ClearFlag_WKUP
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_ClearFlag_WKUP(USART_TypeDef *LPUARTx)
{
WRITE_REG(LPUARTx->ICR, USART_ICR_WUCF);
}
/**
* @}
*/
/** @defgroup LPUART_LL_EF_IT_Management IT_Management
* @{
*/
/**
* @brief Enable IDLE Interrupt
* @rmtoll CR1 IDLEIE LL_LPUART_EnableIT_IDLE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_IDLE(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_IDLEIE);
}
#define LL_LPUART_EnableIT_RXNE LL_LPUART_EnableIT_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Enable RX Not Empty and RX FIFO Not Empty Interrupt
* @rmtoll CR1 RXNEIE_RXFNEIE LL_LPUART_EnableIT_RXNE_RXFNE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_RXNE_RXFNE(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_RXNEIE_RXFNEIE);
}
/**
* @brief Enable Transmission Complete Interrupt
* @rmtoll CR1 TCIE LL_LPUART_EnableIT_TC
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_TC(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_TCIE);
}
#define LL_LPUART_EnableIT_TXE LL_LPUART_EnableIT_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Enable TX Empty and TX FIFO Not Full Interrupt
* @rmtoll CR1 TXEIE_TXFNFIE LL_LPUART_EnableIT_TXE_TXFNF
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_TXE_TXFNF(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_TXEIE_TXFNFIE);
}
/**
* @brief Enable Parity Error Interrupt
* @rmtoll CR1 PEIE LL_LPUART_EnableIT_PE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_PE(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_PEIE);
}
/**
* @brief Enable Character Match Interrupt
* @rmtoll CR1 CMIE LL_LPUART_EnableIT_CM
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_CM(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_CMIE);
}
/**
* @brief Enable TX FIFO Empty Interrupt
* @rmtoll CR1 TXFEIE LL_LPUART_EnableIT_TXFE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_TXFE(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_TXFEIE);
}
/**
* @brief Enable RX FIFO Full Interrupt
* @rmtoll CR1 RXFFIE LL_LPUART_EnableIT_RXFF
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_RXFF(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR1, USART_CR1_RXFFIE);
}
/**
* @brief Enable Error Interrupt
* @note When set, Error Interrupt Enable Bit is enabling interrupt generation in case of a framing
* error, overrun error or noise flag (FE=1 or ORE=1 or NF=1 in the LPUARTx_ISR register).
* - 0: Interrupt is inhibited
* - 1: An interrupt is generated when FE=1 or ORE=1 or NF=1 in the LPUARTx_ISR register.
* @rmtoll CR3 EIE LL_LPUART_EnableIT_ERROR
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_ERROR(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR3, USART_CR3_EIE);
}
/**
* @brief Enable CTS Interrupt
* @rmtoll CR3 CTSIE LL_LPUART_EnableIT_CTS
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_CTS(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR3, USART_CR3_CTSIE);
}
/**
* @brief Enable Wake Up from Stop Mode Interrupt
* @rmtoll CR3 WUFIE LL_LPUART_EnableIT_WKUP
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_WKUP(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR3, USART_CR3_WUFIE);
}
/**
* @brief Enable TX FIFO Threshold Interrupt
* @rmtoll CR3 TXFTIE LL_LPUART_EnableIT_TXFT
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_TXFT(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR3, USART_CR3_TXFTIE);
}
/**
* @brief Enable RX FIFO Threshold Interrupt
* @rmtoll CR3 RXFTIE LL_LPUART_EnableIT_RXFT
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableIT_RXFT(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR3, USART_CR3_RXFTIE);
}
/**
* @brief Disable IDLE Interrupt
* @rmtoll CR1 IDLEIE LL_LPUART_DisableIT_IDLE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_IDLE(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_IDLEIE);
}
#define LL_LPUART_DisableIT_RXNE LL_LPUART_DisableIT_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Disable RX Not Empty and RX FIFO Not Empty Interrupt
* @rmtoll CR1 RXNEIE_RXFNEIE LL_LPUART_DisableIT_RXNE_RXFNE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_RXNE_RXFNE(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_RXNEIE_RXFNEIE);
}
/**
* @brief Disable Transmission Complete Interrupt
* @rmtoll CR1 TCIE LL_LPUART_DisableIT_TC
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_TC(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_TCIE);
}
#define LL_LPUART_DisableIT_TXE LL_LPUART_DisableIT_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Disable TX Empty and TX FIFO Not Full Interrupt
* @rmtoll CR1 TXEIE_TXFNFIE LL_LPUART_DisableIT_TXE_TXFNF
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_TXE_TXFNF(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_TXEIE_TXFNFIE);
}
/**
* @brief Disable Parity Error Interrupt
* @rmtoll CR1 PEIE LL_LPUART_DisableIT_PE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_PE(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_PEIE);
}
/**
* @brief Disable Character Match Interrupt
* @rmtoll CR1 CMIE LL_LPUART_DisableIT_CM
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_CM(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_CMIE);
}
/**
* @brief Disable TX FIFO Empty Interrupt
* @rmtoll CR1 TXFEIE LL_LPUART_DisableIT_TXFE
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_TXFE(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_TXFEIE);
}
/**
* @brief Disable RX FIFO Full Interrupt
* @rmtoll CR1 RXFFIE LL_LPUART_DisableIT_RXFF
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_RXFF(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR1, USART_CR1_RXFFIE);
}
/**
* @brief Disable Error Interrupt
* @note When set, Error Interrupt Enable Bit is enabling interrupt generation in case of a framing
* error, overrun error or noise flag (FE=1 or ORE=1 or NF=1 in the LPUARTx_ISR register).
* - 0: Interrupt is inhibited
* - 1: An interrupt is generated when FE=1 or ORE=1 or NF=1 in the LPUARTx_ISR register.
* @rmtoll CR3 EIE LL_LPUART_DisableIT_ERROR
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_ERROR(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR3, USART_CR3_EIE);
}
/**
* @brief Disable CTS Interrupt
* @rmtoll CR3 CTSIE LL_LPUART_DisableIT_CTS
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_CTS(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR3, USART_CR3_CTSIE);
}
/**
* @brief Disable Wake Up from Stop Mode Interrupt
* @rmtoll CR3 WUFIE LL_LPUART_DisableIT_WKUP
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_WKUP(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR3, USART_CR3_WUFIE);
}
/**
* @brief Disable TX FIFO Threshold Interrupt
* @rmtoll CR3 TXFTIE LL_LPUART_DisableIT_TXFT
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_TXFT(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR3, USART_CR3_TXFTIE);
}
/**
* @brief Disable RX FIFO Threshold Interrupt
* @rmtoll CR3 RXFTIE LL_LPUART_DisableIT_RXFT
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableIT_RXFT(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR3, USART_CR3_RXFTIE);
}
/**
* @brief Check if the LPUART IDLE Interrupt source is enabled or disabled.
* @rmtoll CR1 IDLEIE LL_LPUART_IsEnabledIT_IDLE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_IDLE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_IDLEIE) == (USART_CR1_IDLEIE)) ? 1UL : 0UL);
}
#define LL_LPUART_IsEnabledIT_RXNE LL_LPUART_IsEnabledIT_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Check if the LPUART RX Not Empty and LPUART RX FIFO Not Empty Interrupt is enabled or disabled.
* @rmtoll CR1 RXNEIE_RXFNEIE LL_LPUART_IsEnabledIT_RXNE_RXFNE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_RXNE_RXFNE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_RXNEIE_RXFNEIE) == (USART_CR1_RXNEIE_RXFNEIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Transmission Complete Interrupt is enabled or disabled.
* @rmtoll CR1 TCIE LL_LPUART_IsEnabledIT_TC
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_TC(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_TCIE) == (USART_CR1_TCIE)) ? 1UL : 0UL);
}
#define LL_LPUART_IsEnabledIT_TXE LL_LPUART_IsEnabledIT_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Check if the LPUART TX Empty and LPUART TX FIFO Not Full Interrupt is enabled or disabled
* @rmtoll CR1 TXEIE_TXFNFIE LL_LPUART_IsEnabledIT_TXE_TXFNF
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_TXE_TXFNF(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_TXEIE_TXFNFIE) == (USART_CR1_TXEIE_TXFNFIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Parity Error Interrupt is enabled or disabled.
* @rmtoll CR1 PEIE LL_LPUART_IsEnabledIT_PE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_PE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_PEIE) == (USART_CR1_PEIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Character Match Interrupt is enabled or disabled.
* @rmtoll CR1 CMIE LL_LPUART_IsEnabledIT_CM
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_CM(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_CMIE) == (USART_CR1_CMIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART TX FIFO Empty Interrupt is enabled or disabled
* @rmtoll CR1 TXFEIE LL_LPUART_IsEnabledIT_TXFE
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_TXFE(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_TXFEIE) == (USART_CR1_TXFEIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART RX FIFO Full Interrupt is enabled or disabled
* @rmtoll CR1 RXFFIE LL_LPUART_IsEnabledIT_RXFF
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_RXFF(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR1, USART_CR1_RXFFIE) == (USART_CR1_RXFFIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Error Interrupt is enabled or disabled.
* @rmtoll CR3 EIE LL_LPUART_IsEnabledIT_ERROR
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_ERROR(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_EIE) == (USART_CR3_EIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART CTS Interrupt is enabled or disabled.
* @rmtoll CR3 CTSIE LL_LPUART_IsEnabledIT_CTS
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_CTS(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_CTSIE) == (USART_CR3_CTSIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the LPUART Wake Up from Stop Mode Interrupt is enabled or disabled.
* @rmtoll CR3 WUFIE LL_LPUART_IsEnabledIT_WKUP
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_WKUP(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_WUFIE) == (USART_CR3_WUFIE)) ? 1UL : 0UL);
}
/**
* @brief Check if LPUART TX FIFO Threshold Interrupt is enabled or disabled
* @rmtoll CR3 TXFTIE LL_LPUART_IsEnabledIT_TXFT
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_TXFT(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_TXFTIE) == (USART_CR3_TXFTIE)) ? 1UL : 0UL);
}
/**
* @brief Check if LPUART RX FIFO Threshold Interrupt is enabled or disabled
* @rmtoll CR3 RXFTIE LL_LPUART_IsEnabledIT_RXFT
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledIT_RXFT(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_RXFTIE) == (USART_CR3_RXFTIE)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup LPUART_LL_EF_DMA_Management DMA_Management
* @{
*/
/**
* @brief Enable DMA Mode for reception
* @rmtoll CR3 DMAR LL_LPUART_EnableDMAReq_RX
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableDMAReq_RX(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR3, USART_CR3_DMAR);
}
/**
* @brief Disable DMA Mode for reception
* @rmtoll CR3 DMAR LL_LPUART_DisableDMAReq_RX
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableDMAReq_RX(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR3, USART_CR3_DMAR);
}
/**
* @brief Check if DMA Mode is enabled for reception
* @rmtoll CR3 DMAR LL_LPUART_IsEnabledDMAReq_RX
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledDMAReq_RX(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_DMAR) == (USART_CR3_DMAR)) ? 1UL : 0UL);
}
/**
* @brief Enable DMA Mode for transmission
* @rmtoll CR3 DMAT LL_LPUART_EnableDMAReq_TX
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableDMAReq_TX(USART_TypeDef *LPUARTx)
{
ATOMIC_SET_BIT(LPUARTx->CR3, USART_CR3_DMAT);
}
/**
* @brief Disable DMA Mode for transmission
* @rmtoll CR3 DMAT LL_LPUART_DisableDMAReq_TX
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableDMAReq_TX(USART_TypeDef *LPUARTx)
{
ATOMIC_CLEAR_BIT(LPUARTx->CR3, USART_CR3_DMAT);
}
/**
* @brief Check if DMA Mode is enabled for transmission
* @rmtoll CR3 DMAT LL_LPUART_IsEnabledDMAReq_TX
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledDMAReq_TX(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_DMAT) == (USART_CR3_DMAT)) ? 1UL : 0UL);
}
/**
* @brief Enable DMA Disabling on Reception Error
* @rmtoll CR3 DDRE LL_LPUART_EnableDMADeactOnRxErr
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_EnableDMADeactOnRxErr(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->CR3, USART_CR3_DDRE);
}
/**
* @brief Disable DMA Disabling on Reception Error
* @rmtoll CR3 DDRE LL_LPUART_DisableDMADeactOnRxErr
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_DisableDMADeactOnRxErr(USART_TypeDef *LPUARTx)
{
CLEAR_BIT(LPUARTx->CR3, USART_CR3_DDRE);
}
/**
* @brief Indicate if DMA Disabling on Reception Error is disabled
* @rmtoll CR3 DDRE LL_LPUART_IsEnabledDMADeactOnRxErr
* @param LPUARTx LPUART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_LPUART_IsEnabledDMADeactOnRxErr(const USART_TypeDef *LPUARTx)
{
return ((READ_BIT(LPUARTx->CR3, USART_CR3_DDRE) == (USART_CR3_DDRE)) ? 1UL : 0UL);
}
/**
* @brief Get the LPUART data register address used for DMA transfer
* @rmtoll RDR RDR LL_LPUART_DMA_GetRegAddr\n
* @rmtoll TDR TDR LL_LPUART_DMA_GetRegAddr
* @param LPUARTx LPUART Instance
* @param Direction This parameter can be one of the following values:
* @arg @ref LL_LPUART_DMA_REG_DATA_TRANSMIT
* @arg @ref LL_LPUART_DMA_REG_DATA_RECEIVE
* @retval Address of data register
*/
__STATIC_INLINE uint32_t LL_LPUART_DMA_GetRegAddr(const USART_TypeDef *LPUARTx, uint32_t Direction)
{
uint32_t data_reg_addr;
if (Direction == LL_LPUART_DMA_REG_DATA_TRANSMIT)
{
/* return address of TDR register */
data_reg_addr = (uint32_t) &(LPUARTx->TDR);
}
else
{
/* return address of RDR register */
data_reg_addr = (uint32_t) &(LPUARTx->RDR);
}
return data_reg_addr;
}
/**
* @}
*/
/** @defgroup LPUART_LL_EF_Data_Management Data_Management
* @{
*/
/**
* @brief Read Receiver Data register (Receive Data value, 8 bits)
* @rmtoll RDR RDR LL_LPUART_ReceiveData8
* @param LPUARTx LPUART Instance
* @retval Time Value between Min_Data=0x00 and Max_Data=0xFF
*/
__STATIC_INLINE uint8_t LL_LPUART_ReceiveData8(const USART_TypeDef *LPUARTx)
{
return (uint8_t)(READ_BIT(LPUARTx->RDR, USART_RDR_RDR) & 0xFFU);
}
/**
* @brief Read Receiver Data register (Receive Data value, 9 bits)
* @rmtoll RDR RDR LL_LPUART_ReceiveData9
* @param LPUARTx LPUART Instance
* @retval Time Value between Min_Data=0x00 and Max_Data=0x1FF
*/
__STATIC_INLINE uint16_t LL_LPUART_ReceiveData9(const USART_TypeDef *LPUARTx)
{
return (uint16_t)(READ_BIT(LPUARTx->RDR, USART_RDR_RDR));
}
/**
* @brief Write in Transmitter Data Register (Transmit Data value, 8 bits)
* @rmtoll TDR TDR LL_LPUART_TransmitData8
* @param LPUARTx LPUART Instance
* @param Value between Min_Data=0x00 and Max_Data=0xFF
* @retval None
*/
__STATIC_INLINE void LL_LPUART_TransmitData8(USART_TypeDef *LPUARTx, uint8_t Value)
{
LPUARTx->TDR = Value;
}
/**
* @brief Write in Transmitter Data Register (Transmit Data value, 9 bits)
* @rmtoll TDR TDR LL_LPUART_TransmitData9
* @param LPUARTx LPUART Instance
* @param Value between Min_Data=0x00 and Max_Data=0x1FF
* @retval None
*/
__STATIC_INLINE void LL_LPUART_TransmitData9(USART_TypeDef *LPUARTx, uint16_t Value)
{
LPUARTx->TDR = Value & 0x1FFUL;
}
/**
* @}
*/
/** @defgroup LPUART_LL_EF_Execution Execution
* @{
*/
/**
* @brief Request Break sending
* @rmtoll RQR SBKRQ LL_LPUART_RequestBreakSending
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_RequestBreakSending(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->RQR, (uint16_t)USART_RQR_SBKRQ);
}
/**
* @brief Put LPUART in mute mode and set the RWU flag
* @rmtoll RQR MMRQ LL_LPUART_RequestEnterMuteMode
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_RequestEnterMuteMode(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->RQR, (uint16_t)USART_RQR_MMRQ);
}
/**
* @brief Request a Receive Data and FIFO flush
* @note Allows to discard the received data without reading them, and avoid an overrun
* condition.
* @rmtoll RQR RXFRQ LL_LPUART_RequestRxDataFlush
* @param LPUARTx LPUART Instance
* @retval None
*/
__STATIC_INLINE void LL_LPUART_RequestRxDataFlush(USART_TypeDef *LPUARTx)
{
SET_BIT(LPUARTx->RQR, (uint16_t)USART_RQR_RXFRQ);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup LPUART_LL_EF_Init Initialization and de-initialization functions
* @{
*/
ErrorStatus LL_LPUART_DeInit(const USART_TypeDef *LPUARTx);
ErrorStatus LL_LPUART_Init(USART_TypeDef *LPUARTx, const LL_LPUART_InitTypeDef *LPUART_InitStruct);
void LL_LPUART_StructInit(LL_LPUART_InitTypeDef *LPUART_InitStruct);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* LPUART1 */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_LPUART_H */
| 95,343 | C | 35.060514 | 120 | 0.635799 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_flash_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_flash_ex.h
* @author MCD Application Team
* @brief Header file of FLASH HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_FLASH_EX_H
#define STM32G4xx_HAL_FLASH_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup FLASHEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup FLASHEx_Exported_Functions
* @{
*/
/* Extended Program operation functions *************************************/
/** @addtogroup FLASHEx_Exported_Functions_Group1
* @{
*/
HAL_StatusTypeDef HAL_FLASHEx_Erase(FLASH_EraseInitTypeDef *pEraseInit, uint32_t *PageError);
HAL_StatusTypeDef HAL_FLASHEx_Erase_IT(FLASH_EraseInitTypeDef *pEraseInit);
HAL_StatusTypeDef HAL_FLASHEx_OBProgram(FLASH_OBProgramInitTypeDef *pOBInit);
void HAL_FLASHEx_OBGetConfig(FLASH_OBProgramInitTypeDef *pOBInit);
HAL_StatusTypeDef HAL_FLASHEx_EnableSecMemProtection(uint32_t Bank);
void HAL_FLASHEx_EnableDebugger(void);
void HAL_FLASHEx_DisableDebugger(void);
/**
* @}
*/
/**
* @}
*/
/** @addtogroup FLASHEx_Private_Functions
* @{
*/
void FLASH_PageErase(uint32_t Page, uint32_t Banks);
void FLASH_FlushCaches(void);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_FLASH_EX_H */
| 2,407 | C | 25.755555 | 93 | 0.49273 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_crc_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_crc_ex.h
* @author MCD Application Team
* @brief Header file of CRC HAL extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_CRC_EX_H
#define STM32G4xx_HAL_CRC_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup CRCEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup CRCEx_Exported_Constants CRC Extended Exported Constants
* @{
*/
/** @defgroup CRCEx_Input_Data_Inversion Input Data Inversion Modes
* @{
*/
#define CRC_INPUTDATA_INVERSION_NONE 0x00000000U /*!< No input data inversion */
#define CRC_INPUTDATA_INVERSION_BYTE CRC_CR_REV_IN_0 /*!< Byte-wise input data inversion */
#define CRC_INPUTDATA_INVERSION_HALFWORD CRC_CR_REV_IN_1 /*!< HalfWord-wise input data inversion */
#define CRC_INPUTDATA_INVERSION_WORD CRC_CR_REV_IN /*!< Word-wise input data inversion */
/**
* @}
*/
/** @defgroup CRCEx_Output_Data_Inversion Output Data Inversion Modes
* @{
*/
#define CRC_OUTPUTDATA_INVERSION_DISABLE 0x00000000U /*!< No output data inversion */
#define CRC_OUTPUTDATA_INVERSION_ENABLE CRC_CR_REV_OUT /*!< Bit-wise output data inversion */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup CRCEx_Exported_Macros CRC Extended Exported Macros
* @{
*/
/**
* @brief Set CRC output reversal
* @param __HANDLE__ CRC handle
* @retval None
*/
#define __HAL_CRC_OUTPUTREVERSAL_ENABLE(__HANDLE__) ((__HANDLE__)->Instance->CR |= CRC_CR_REV_OUT)
/**
* @brief Unset CRC output reversal
* @param __HANDLE__ CRC handle
* @retval None
*/
#define __HAL_CRC_OUTPUTREVERSAL_DISABLE(__HANDLE__) ((__HANDLE__)->Instance->CR &= ~(CRC_CR_REV_OUT))
/**
* @brief Set CRC non-default polynomial
* @param __HANDLE__ CRC handle
* @param __POLYNOMIAL__ 7, 8, 16 or 32-bit polynomial
* @retval None
*/
#define __HAL_CRC_POLYNOMIAL_CONFIG(__HANDLE__, __POLYNOMIAL__) ((__HANDLE__)->Instance->POL = (__POLYNOMIAL__))
/**
* @}
*/
/* Private macros --------------------------------------------------------*/
/** @defgroup CRCEx_Private_Macros CRC Extended Private Macros
* @{
*/
#define IS_CRC_INPUTDATA_INVERSION_MODE(MODE) (((MODE) == CRC_INPUTDATA_INVERSION_NONE) || \
((MODE) == CRC_INPUTDATA_INVERSION_BYTE) || \
((MODE) == CRC_INPUTDATA_INVERSION_HALFWORD) || \
((MODE) == CRC_INPUTDATA_INVERSION_WORD))
#define IS_CRC_OUTPUTDATA_INVERSION_MODE(MODE) (((MODE) == CRC_OUTPUTDATA_INVERSION_DISABLE) || \
((MODE) == CRC_OUTPUTDATA_INVERSION_ENABLE))
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup CRCEx_Exported_Functions
* @{
*/
/** @addtogroup CRCEx_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions ****************************/
HAL_StatusTypeDef HAL_CRCEx_Polynomial_Set(CRC_HandleTypeDef *hcrc, uint32_t Pol, uint32_t PolyLength);
HAL_StatusTypeDef HAL_CRCEx_Input_Data_Reverse(CRC_HandleTypeDef *hcrc, uint32_t InputReverseMode);
HAL_StatusTypeDef HAL_CRCEx_Output_Data_Reverse(CRC_HandleTypeDef *hcrc, uint32_t OutputReverseMode);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_CRC_EX_H */
| 4,500 | C | 28.807947 | 112 | 0.512889 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_crs.h | /**
******************************************************************************
* @file stm32g4xx_ll_crs.h
* @author MCD Application Team
* @brief Header file of CRS LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2018 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_LL_CRS_H
#define __STM32G4xx_LL_CRS_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined(CRS)
/** @defgroup CRS_LL CRS
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup CRS_LL_Exported_Constants CRS Exported Constants
* @{
*/
/** @defgroup CRS_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_CRS_ReadReg function
* @{
*/
#define LL_CRS_ISR_SYNCOKF CRS_ISR_SYNCOKF
#define LL_CRS_ISR_SYNCWARNF CRS_ISR_SYNCWARNF
#define LL_CRS_ISR_ERRF CRS_ISR_ERRF
#define LL_CRS_ISR_ESYNCF CRS_ISR_ESYNCF
#define LL_CRS_ISR_SYNCERR CRS_ISR_SYNCERR
#define LL_CRS_ISR_SYNCMISS CRS_ISR_SYNCMISS
#define LL_CRS_ISR_TRIMOVF CRS_ISR_TRIMOVF
/**
* @}
*/
/** @defgroup CRS_LL_EC_IT IT Defines
* @brief IT defines which can be used with LL_CRS_ReadReg and LL_CRS_WriteReg functions
* @{
*/
#define LL_CRS_CR_SYNCOKIE CRS_CR_SYNCOKIE
#define LL_CRS_CR_SYNCWARNIE CRS_CR_SYNCWARNIE
#define LL_CRS_CR_ERRIE CRS_CR_ERRIE
#define LL_CRS_CR_ESYNCIE CRS_CR_ESYNCIE
/**
* @}
*/
/** @defgroup CRS_LL_EC_SYNC_DIV Synchronization Signal Divider
* @{
*/
#define LL_CRS_SYNC_DIV_1 ((uint32_t)0x00U) /*!< Synchro Signal not divided (default) */
#define LL_CRS_SYNC_DIV_2 CRS_CFGR_SYNCDIV_0 /*!< Synchro Signal divided by 2 */
#define LL_CRS_SYNC_DIV_4 CRS_CFGR_SYNCDIV_1 /*!< Synchro Signal divided by 4 */
#define LL_CRS_SYNC_DIV_8 (CRS_CFGR_SYNCDIV_1 | CRS_CFGR_SYNCDIV_0) /*!< Synchro Signal divided by 8 */
#define LL_CRS_SYNC_DIV_16 CRS_CFGR_SYNCDIV_2 /*!< Synchro Signal divided by 16 */
#define LL_CRS_SYNC_DIV_32 (CRS_CFGR_SYNCDIV_2 | CRS_CFGR_SYNCDIV_0) /*!< Synchro Signal divided by 32 */
#define LL_CRS_SYNC_DIV_64 (CRS_CFGR_SYNCDIV_2 | CRS_CFGR_SYNCDIV_1) /*!< Synchro Signal divided by 64 */
#define LL_CRS_SYNC_DIV_128 CRS_CFGR_SYNCDIV /*!< Synchro Signal divided by 128 */
/**
* @}
*/
/** @defgroup CRS_LL_EC_SYNC_SOURCE Synchronization Signal Source
* @{
*/
#define LL_CRS_SYNC_SOURCE_GPIO ((uint32_t)0x00U) /*!< Synchro Signal source GPIO */
#define LL_CRS_SYNC_SOURCE_LSE CRS_CFGR_SYNCSRC_0 /*!< Synchro Signal source LSE */
#define LL_CRS_SYNC_SOURCE_USB CRS_CFGR_SYNCSRC_1 /*!< Synchro Signal source USB SOF (default)*/
/**
* @}
*/
/** @defgroup CRS_LL_EC_SYNC_POLARITY Synchronization Signal Polarity
* @{
*/
#define LL_CRS_SYNC_POLARITY_RISING ((uint32_t)0x00U) /*!< Synchro Active on rising edge (default) */
#define LL_CRS_SYNC_POLARITY_FALLING CRS_CFGR_SYNCPOL /*!< Synchro Active on falling edge */
/**
* @}
*/
/** @defgroup CRS_LL_EC_FREQERRORDIR Frequency Error Direction
* @{
*/
#define LL_CRS_FREQ_ERROR_DIR_UP ((uint32_t)0x00U) /*!< Upcounting direction, the actual frequency is above the target */
#define LL_CRS_FREQ_ERROR_DIR_DOWN ((uint32_t)CRS_ISR_FEDIR) /*!< Downcounting direction, the actual frequency is below the target */
/**
* @}
*/
/** @defgroup CRS_LL_EC_DEFAULTVALUES Default Values
* @{
*/
/**
* @brief Reset value of the RELOAD field
* @note The reset value of the RELOAD field corresponds to a target frequency of 48 MHz
* and a synchronization signal frequency of 1 kHz (SOF signal from USB)
*/
#define LL_CRS_RELOADVALUE_DEFAULT ((uint32_t)0xBB7FU)
/**
* @brief Reset value of Frequency error limit.
*/
#define LL_CRS_ERRORLIMIT_DEFAULT ((uint32_t)0x22U)
/**
* @brief Reset value of the HSI48 Calibration field
* @note The default value is 64, which corresponds to the middle of the trimming interval.
* The trimming step is specified in the product datasheet.
* A higher TRIM value corresponds to a higher output frequency
*/
#define LL_CRS_HSI48CALIBRATION_DEFAULT ((uint32_t)0x40U)
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup CRS_LL_Exported_Macros CRS Exported Macros
* @{
*/
/** @defgroup CRS_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in CRS register
* @param __INSTANCE__ CRS Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_CRS_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG(__INSTANCE__->__REG__, (__VALUE__))
/**
* @brief Read a value in CRS register
* @param __INSTANCE__ CRS Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_CRS_ReadReg(__INSTANCE__, __REG__) READ_REG(__INSTANCE__->__REG__)
/**
* @}
*/
/** @defgroup CRS_LL_EM_Exported_Macros_Calculate_Reload Exported_Macros_Calculate_Reload
* @{
*/
/**
* @brief Macro to calculate reload value to be set in CRS register according to target and sync frequencies
* @note The RELOAD value should be selected according to the ratio between
* the target frequency and the frequency of the synchronization source after
* prescaling. It is then decreased by one in order to reach the expected
* synchronization on the zero value. The formula is the following:
* RELOAD = (fTARGET / fSYNC) -1
* @param __FTARGET__ Target frequency (value in Hz)
* @param __FSYNC__ Synchronization signal frequency (value in Hz)
* @retval Reload value (in Hz)
*/
#define __LL_CRS_CALC_CALCULATE_RELOADVALUE(__FTARGET__, __FSYNC__) (((__FTARGET__) / (__FSYNC__)) - 1U)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup CRS_LL_Exported_Functions CRS Exported Functions
* @{
*/
/** @defgroup CRS_LL_EF_Configuration Configuration
* @{
*/
/**
* @brief Enable Frequency error counter
* @note When this bit is set, the CRS_CFGR register is write-protected and cannot be modified
* @rmtoll CR CEN LL_CRS_EnableFreqErrorCounter
* @retval None
*/
__STATIC_INLINE void LL_CRS_EnableFreqErrorCounter(void)
{
SET_BIT(CRS->CR, CRS_CR_CEN);
}
/**
* @brief Disable Frequency error counter
* @rmtoll CR CEN LL_CRS_DisableFreqErrorCounter
* @retval None
*/
__STATIC_INLINE void LL_CRS_DisableFreqErrorCounter(void)
{
CLEAR_BIT(CRS->CR, CRS_CR_CEN);
}
/**
* @brief Check if Frequency error counter is enabled or not
* @rmtoll CR CEN LL_CRS_IsEnabledFreqErrorCounter
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsEnabledFreqErrorCounter(void)
{
return ((READ_BIT(CRS->CR, CRS_CR_CEN) == (CRS_CR_CEN)) ? 1UL : 0UL);
}
/**
* @brief Enable Automatic trimming counter
* @rmtoll CR AUTOTRIMEN LL_CRS_EnableAutoTrimming
* @retval None
*/
__STATIC_INLINE void LL_CRS_EnableAutoTrimming(void)
{
SET_BIT(CRS->CR, CRS_CR_AUTOTRIMEN);
}
/**
* @brief Disable Automatic trimming counter
* @rmtoll CR AUTOTRIMEN LL_CRS_DisableAutoTrimming
* @retval None
*/
__STATIC_INLINE void LL_CRS_DisableAutoTrimming(void)
{
CLEAR_BIT(CRS->CR, CRS_CR_AUTOTRIMEN);
}
/**
* @brief Check if Automatic trimming is enabled or not
* @rmtoll CR AUTOTRIMEN LL_CRS_IsEnabledAutoTrimming
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsEnabledAutoTrimming(void)
{
return ((READ_BIT(CRS->CR, CRS_CR_AUTOTRIMEN) == (CRS_CR_AUTOTRIMEN)) ? 1UL : 0UL);
}
/**
* @brief Set HSI48 oscillator smooth trimming
* @note When the AUTOTRIMEN bit is set, this field is controlled by hardware and is read-only
* @rmtoll CR TRIM LL_CRS_SetHSI48SmoothTrimming
* @param Value a number between Min_Data = 0 and Max_Data = 63
* @note Default value can be set thanks to @ref LL_CRS_HSI48CALIBRATION_DEFAULT
* @retval None
*/
__STATIC_INLINE void LL_CRS_SetHSI48SmoothTrimming(uint32_t Value)
{
MODIFY_REG(CRS->CR, CRS_CR_TRIM, Value << CRS_CR_TRIM_Pos);
}
/**
* @brief Get HSI48 oscillator smooth trimming
* @rmtoll CR TRIM LL_CRS_GetHSI48SmoothTrimming
* @retval a number between Min_Data = 0 and Max_Data = 63
*/
__STATIC_INLINE uint32_t LL_CRS_GetHSI48SmoothTrimming(void)
{
return (uint32_t)(READ_BIT(CRS->CR, CRS_CR_TRIM) >> CRS_CR_TRIM_Pos);
}
/**
* @brief Set counter reload value
* @rmtoll CFGR RELOAD LL_CRS_SetReloadCounter
* @param Value a number between Min_Data = 0 and Max_Data = 0xFFFF
* @note Default value can be set thanks to @ref LL_CRS_RELOADVALUE_DEFAULT
* Otherwise it can be calculated in using macro @ref __LL_CRS_CALC_CALCULATE_RELOADVALUE (_FTARGET_, _FSYNC_)
* @retval None
*/
__STATIC_INLINE void LL_CRS_SetReloadCounter(uint32_t Value)
{
MODIFY_REG(CRS->CFGR, CRS_CFGR_RELOAD, Value);
}
/**
* @brief Get counter reload value
* @rmtoll CFGR RELOAD LL_CRS_GetReloadCounter
* @retval a number between Min_Data = 0 and Max_Data = 0xFFFF
*/
__STATIC_INLINE uint32_t LL_CRS_GetReloadCounter(void)
{
return (uint32_t)(READ_BIT(CRS->CFGR, CRS_CFGR_RELOAD));
}
/**
* @brief Set frequency error limit
* @rmtoll CFGR FELIM LL_CRS_SetFreqErrorLimit
* @param Value a number between Min_Data = 0 and Max_Data = 255
* @note Default value can be set thanks to @ref LL_CRS_ERRORLIMIT_DEFAULT
* @retval None
*/
__STATIC_INLINE void LL_CRS_SetFreqErrorLimit(uint32_t Value)
{
MODIFY_REG(CRS->CFGR, CRS_CFGR_FELIM, Value << CRS_CFGR_FELIM_Pos);
}
/**
* @brief Get frequency error limit
* @rmtoll CFGR FELIM LL_CRS_GetFreqErrorLimit
* @retval A number between Min_Data = 0 and Max_Data = 255
*/
__STATIC_INLINE uint32_t LL_CRS_GetFreqErrorLimit(void)
{
return (uint32_t)(READ_BIT(CRS->CFGR, CRS_CFGR_FELIM) >> CRS_CFGR_FELIM_Pos);
}
/**
* @brief Set division factor for SYNC signal
* @rmtoll CFGR SYNCDIV LL_CRS_SetSyncDivider
* @param Divider This parameter can be one of the following values:
* @arg @ref LL_CRS_SYNC_DIV_1
* @arg @ref LL_CRS_SYNC_DIV_2
* @arg @ref LL_CRS_SYNC_DIV_4
* @arg @ref LL_CRS_SYNC_DIV_8
* @arg @ref LL_CRS_SYNC_DIV_16
* @arg @ref LL_CRS_SYNC_DIV_32
* @arg @ref LL_CRS_SYNC_DIV_64
* @arg @ref LL_CRS_SYNC_DIV_128
* @retval None
*/
__STATIC_INLINE void LL_CRS_SetSyncDivider(uint32_t Divider)
{
MODIFY_REG(CRS->CFGR, CRS_CFGR_SYNCDIV, Divider);
}
/**
* @brief Get division factor for SYNC signal
* @rmtoll CFGR SYNCDIV LL_CRS_GetSyncDivider
* @retval Returned value can be one of the following values:
* @arg @ref LL_CRS_SYNC_DIV_1
* @arg @ref LL_CRS_SYNC_DIV_2
* @arg @ref LL_CRS_SYNC_DIV_4
* @arg @ref LL_CRS_SYNC_DIV_8
* @arg @ref LL_CRS_SYNC_DIV_16
* @arg @ref LL_CRS_SYNC_DIV_32
* @arg @ref LL_CRS_SYNC_DIV_64
* @arg @ref LL_CRS_SYNC_DIV_128
*/
__STATIC_INLINE uint32_t LL_CRS_GetSyncDivider(void)
{
return (uint32_t)(READ_BIT(CRS->CFGR, CRS_CFGR_SYNCDIV));
}
/**
* @brief Set SYNC signal source
* @rmtoll CFGR SYNCSRC LL_CRS_SetSyncSignalSource
* @param Source This parameter can be one of the following values:
* @arg @ref LL_CRS_SYNC_SOURCE_GPIO
* @arg @ref LL_CRS_SYNC_SOURCE_LSE
* @arg @ref LL_CRS_SYNC_SOURCE_USB
* @retval None
*/
__STATIC_INLINE void LL_CRS_SetSyncSignalSource(uint32_t Source)
{
MODIFY_REG(CRS->CFGR, CRS_CFGR_SYNCSRC, Source);
}
/**
* @brief Get SYNC signal source
* @rmtoll CFGR SYNCSRC LL_CRS_GetSyncSignalSource
* @retval Returned value can be one of the following values:
* @arg @ref LL_CRS_SYNC_SOURCE_GPIO
* @arg @ref LL_CRS_SYNC_SOURCE_LSE
* @arg @ref LL_CRS_SYNC_SOURCE_USB
*/
__STATIC_INLINE uint32_t LL_CRS_GetSyncSignalSource(void)
{
return (uint32_t)(READ_BIT(CRS->CFGR, CRS_CFGR_SYNCSRC));
}
/**
* @brief Set input polarity for the SYNC signal source
* @rmtoll CFGR SYNCPOL LL_CRS_SetSyncPolarity
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_CRS_SYNC_POLARITY_RISING
* @arg @ref LL_CRS_SYNC_POLARITY_FALLING
* @retval None
*/
__STATIC_INLINE void LL_CRS_SetSyncPolarity(uint32_t Polarity)
{
MODIFY_REG(CRS->CFGR, CRS_CFGR_SYNCPOL, Polarity);
}
/**
* @brief Get input polarity for the SYNC signal source
* @rmtoll CFGR SYNCPOL LL_CRS_GetSyncPolarity
* @retval Returned value can be one of the following values:
* @arg @ref LL_CRS_SYNC_POLARITY_RISING
* @arg @ref LL_CRS_SYNC_POLARITY_FALLING
*/
__STATIC_INLINE uint32_t LL_CRS_GetSyncPolarity(void)
{
return (uint32_t)(READ_BIT(CRS->CFGR, CRS_CFGR_SYNCPOL));
}
/**
* @brief Configure CRS for the synchronization
* @rmtoll CR TRIM LL_CRS_ConfigSynchronization\n
* CFGR RELOAD LL_CRS_ConfigSynchronization\n
* CFGR FELIM LL_CRS_ConfigSynchronization\n
* CFGR SYNCDIV LL_CRS_ConfigSynchronization\n
* CFGR SYNCSRC LL_CRS_ConfigSynchronization\n
* CFGR SYNCPOL LL_CRS_ConfigSynchronization
* @param HSI48CalibrationValue a number between Min_Data = 0 and Max_Data = 63
* @param ErrorLimitValue a number between Min_Data = 0 and Max_Data = 0xFFFF
* @param ReloadValue a number between Min_Data = 0 and Max_Data = 255
* @param Settings This parameter can be a combination of the following values:
* @arg @ref LL_CRS_SYNC_DIV_1 or @ref LL_CRS_SYNC_DIV_2 or @ref LL_CRS_SYNC_DIV_4 or @ref LL_CRS_SYNC_DIV_8
* or @ref LL_CRS_SYNC_DIV_16 or @ref LL_CRS_SYNC_DIV_32 or @ref LL_CRS_SYNC_DIV_64 or @ref LL_CRS_SYNC_DIV_128
* @arg @ref LL_CRS_SYNC_SOURCE_GPIO or @ref LL_CRS_SYNC_SOURCE_LSE or @ref LL_CRS_SYNC_SOURCE_USB
* @arg @ref LL_CRS_SYNC_POLARITY_RISING or @ref LL_CRS_SYNC_POLARITY_FALLING
* @retval None
*/
__STATIC_INLINE void LL_CRS_ConfigSynchronization(uint32_t HSI48CalibrationValue, uint32_t ErrorLimitValue,
uint32_t ReloadValue, uint32_t Settings)
{
MODIFY_REG(CRS->CR, CRS_CR_TRIM, HSI48CalibrationValue);
MODIFY_REG(CRS->CFGR,
CRS_CFGR_RELOAD | CRS_CFGR_FELIM | CRS_CFGR_SYNCDIV | CRS_CFGR_SYNCSRC | CRS_CFGR_SYNCPOL,
ReloadValue | (ErrorLimitValue << CRS_CFGR_FELIM_Pos) | Settings);
}
/**
* @}
*/
/** @defgroup CRS_LL_EF_CRS_Management CRS_Management
* @{
*/
/**
* @brief Generate software SYNC event
* @rmtoll CR SWSYNC LL_CRS_GenerateEvent_SWSYNC
* @retval None
*/
__STATIC_INLINE void LL_CRS_GenerateEvent_SWSYNC(void)
{
SET_BIT(CRS->CR, CRS_CR_SWSYNC);
}
/**
* @brief Get the frequency error direction latched in the time of the last
* SYNC event
* @rmtoll ISR FEDIR LL_CRS_GetFreqErrorDirection
* @retval Returned value can be one of the following values:
* @arg @ref LL_CRS_FREQ_ERROR_DIR_UP
* @arg @ref LL_CRS_FREQ_ERROR_DIR_DOWN
*/
__STATIC_INLINE uint32_t LL_CRS_GetFreqErrorDirection(void)
{
return (uint32_t)(READ_BIT(CRS->ISR, CRS_ISR_FEDIR));
}
/**
* @brief Get the frequency error counter value latched in the time of the last SYNC event
* @rmtoll ISR FECAP LL_CRS_GetFreqErrorCapture
* @retval A number between Min_Data = 0x0000 and Max_Data = 0xFFFF
*/
__STATIC_INLINE uint32_t LL_CRS_GetFreqErrorCapture(void)
{
return (uint32_t)(READ_BIT(CRS->ISR, CRS_ISR_FECAP) >> CRS_ISR_FECAP_Pos);
}
/**
* @}
*/
/** @defgroup CRS_LL_EF_FLAG_Management FLAG_Management
* @{
*/
/**
* @brief Check if SYNC event OK signal occurred or not
* @rmtoll ISR SYNCOKF LL_CRS_IsActiveFlag_SYNCOK
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsActiveFlag_SYNCOK(void)
{
return ((READ_BIT(CRS->ISR, CRS_ISR_SYNCOKF) == (CRS_ISR_SYNCOKF)) ? 1UL : 0UL);
}
/**
* @brief Check if SYNC warning signal occurred or not
* @rmtoll ISR SYNCWARNF LL_CRS_IsActiveFlag_SYNCWARN
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsActiveFlag_SYNCWARN(void)
{
return ((READ_BIT(CRS->ISR, CRS_ISR_SYNCWARNF) == (CRS_ISR_SYNCWARNF)) ? 1UL : 0UL);
}
/**
* @brief Check if Synchronization or trimming error signal occurred or not
* @rmtoll ISR ERRF LL_CRS_IsActiveFlag_ERR
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsActiveFlag_ERR(void)
{
return ((READ_BIT(CRS->ISR, CRS_ISR_ERRF) == (CRS_ISR_ERRF)) ? 1UL : 0UL);
}
/**
* @brief Check if Expected SYNC signal occurred or not
* @rmtoll ISR ESYNCF LL_CRS_IsActiveFlag_ESYNC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsActiveFlag_ESYNC(void)
{
return ((READ_BIT(CRS->ISR, CRS_ISR_ESYNCF) == (CRS_ISR_ESYNCF)) ? 1UL : 0UL);
}
/**
* @brief Check if SYNC error signal occurred or not
* @rmtoll ISR SYNCERR LL_CRS_IsActiveFlag_SYNCERR
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsActiveFlag_SYNCERR(void)
{
return ((READ_BIT(CRS->ISR, CRS_ISR_SYNCERR) == (CRS_ISR_SYNCERR)) ? 1UL : 0UL);
}
/**
* @brief Check if SYNC missed error signal occurred or not
* @rmtoll ISR SYNCMISS LL_CRS_IsActiveFlag_SYNCMISS
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsActiveFlag_SYNCMISS(void)
{
return ((READ_BIT(CRS->ISR, CRS_ISR_SYNCMISS) == (CRS_ISR_SYNCMISS)) ? 1UL : 0UL);
}
/**
* @brief Check if Trimming overflow or underflow occurred or not
* @rmtoll ISR TRIMOVF LL_CRS_IsActiveFlag_TRIMOVF
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsActiveFlag_TRIMOVF(void)
{
return ((READ_BIT(CRS->ISR, CRS_ISR_TRIMOVF) == (CRS_ISR_TRIMOVF)) ? 1UL : 0UL);
}
/**
* @brief Clear the SYNC event OK flag
* @rmtoll ICR SYNCOKC LL_CRS_ClearFlag_SYNCOK
* @retval None
*/
__STATIC_INLINE void LL_CRS_ClearFlag_SYNCOK(void)
{
WRITE_REG(CRS->ICR, CRS_ICR_SYNCOKC);
}
/**
* @brief Clear the SYNC warning flag
* @rmtoll ICR SYNCWARNC LL_CRS_ClearFlag_SYNCWARN
* @retval None
*/
__STATIC_INLINE void LL_CRS_ClearFlag_SYNCWARN(void)
{
WRITE_REG(CRS->ICR, CRS_ICR_SYNCWARNC);
}
/**
* @brief Clear TRIMOVF, SYNCMISS and SYNCERR bits and consequently also
* the ERR flag
* @rmtoll ICR ERRC LL_CRS_ClearFlag_ERR
* @retval None
*/
__STATIC_INLINE void LL_CRS_ClearFlag_ERR(void)
{
WRITE_REG(CRS->ICR, CRS_ICR_ERRC);
}
/**
* @brief Clear Expected SYNC flag
* @rmtoll ICR ESYNCC LL_CRS_ClearFlag_ESYNC
* @retval None
*/
__STATIC_INLINE void LL_CRS_ClearFlag_ESYNC(void)
{
WRITE_REG(CRS->ICR, CRS_ICR_ESYNCC);
}
/**
* @}
*/
/** @defgroup CRS_LL_EF_IT_Management IT_Management
* @{
*/
/**
* @brief Enable SYNC event OK interrupt
* @rmtoll CR SYNCOKIE LL_CRS_EnableIT_SYNCOK
* @retval None
*/
__STATIC_INLINE void LL_CRS_EnableIT_SYNCOK(void)
{
SET_BIT(CRS->CR, CRS_CR_SYNCOKIE);
}
/**
* @brief Disable SYNC event OK interrupt
* @rmtoll CR SYNCOKIE LL_CRS_DisableIT_SYNCOK
* @retval None
*/
__STATIC_INLINE void LL_CRS_DisableIT_SYNCOK(void)
{
CLEAR_BIT(CRS->CR, CRS_CR_SYNCOKIE);
}
/**
* @brief Check if SYNC event OK interrupt is enabled or not
* @rmtoll CR SYNCOKIE LL_CRS_IsEnabledIT_SYNCOK
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsEnabledIT_SYNCOK(void)
{
return ((READ_BIT(CRS->CR, CRS_CR_SYNCOKIE) == (CRS_CR_SYNCOKIE)) ? 1UL : 0UL);
}
/**
* @brief Enable SYNC warning interrupt
* @rmtoll CR SYNCWARNIE LL_CRS_EnableIT_SYNCWARN
* @retval None
*/
__STATIC_INLINE void LL_CRS_EnableIT_SYNCWARN(void)
{
SET_BIT(CRS->CR, CRS_CR_SYNCWARNIE);
}
/**
* @brief Disable SYNC warning interrupt
* @rmtoll CR SYNCWARNIE LL_CRS_DisableIT_SYNCWARN
* @retval None
*/
__STATIC_INLINE void LL_CRS_DisableIT_SYNCWARN(void)
{
CLEAR_BIT(CRS->CR, CRS_CR_SYNCWARNIE);
}
/**
* @brief Check if SYNC warning interrupt is enabled or not
* @rmtoll CR SYNCWARNIE LL_CRS_IsEnabledIT_SYNCWARN
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsEnabledIT_SYNCWARN(void)
{
return ((READ_BIT(CRS->CR, CRS_CR_SYNCWARNIE) == (CRS_CR_SYNCWARNIE)) ? 1UL : 0UL);
}
/**
* @brief Enable Synchronization or trimming error interrupt
* @rmtoll CR ERRIE LL_CRS_EnableIT_ERR
* @retval None
*/
__STATIC_INLINE void LL_CRS_EnableIT_ERR(void)
{
SET_BIT(CRS->CR, CRS_CR_ERRIE);
}
/**
* @brief Disable Synchronization or trimming error interrupt
* @rmtoll CR ERRIE LL_CRS_DisableIT_ERR
* @retval None
*/
__STATIC_INLINE void LL_CRS_DisableIT_ERR(void)
{
CLEAR_BIT(CRS->CR, CRS_CR_ERRIE);
}
/**
* @brief Check if Synchronization or trimming error interrupt is enabled or not
* @rmtoll CR ERRIE LL_CRS_IsEnabledIT_ERR
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsEnabledIT_ERR(void)
{
return ((READ_BIT(CRS->CR, CRS_CR_ERRIE) == (CRS_CR_ERRIE)) ? 1UL : 0UL);
}
/**
* @brief Enable Expected SYNC interrupt
* @rmtoll CR ESYNCIE LL_CRS_EnableIT_ESYNC
* @retval None
*/
__STATIC_INLINE void LL_CRS_EnableIT_ESYNC(void)
{
SET_BIT(CRS->CR, CRS_CR_ESYNCIE);
}
/**
* @brief Disable Expected SYNC interrupt
* @rmtoll CR ESYNCIE LL_CRS_DisableIT_ESYNC
* @retval None
*/
__STATIC_INLINE void LL_CRS_DisableIT_ESYNC(void)
{
CLEAR_BIT(CRS->CR, CRS_CR_ESYNCIE);
}
/**
* @brief Check if Expected SYNC interrupt is enabled or not
* @rmtoll CR ESYNCIE LL_CRS_IsEnabledIT_ESYNC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_CRS_IsEnabledIT_ESYNC(void)
{
return ((READ_BIT(CRS->CR, CRS_CR_ESYNCIE) == (CRS_CR_ESYNCIE)) ? 1UL : 0UL);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup CRS_LL_EF_Init Initialization and de-initialization functions
* @{
*/
ErrorStatus LL_CRS_DeInit(void);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* defined(CRS) */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_LL_CRS_H */
| 24,270 | C | 30.037084 | 143 | 0.606098 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_cortex.h | /**
******************************************************************************
* @file stm32g4xx_ll_cortex.h
* @author MCD Application Team
* @brief Header file of CORTEX LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
The LL CORTEX driver contains a set of generic APIs that can be
used by user:
(+) SYSTICK configuration used by LL_mDelay and LL_Init1msTick
functions
(+) Low power mode configuration (SCB register of Cortex-MCU)
(+) MPU API to configure and enable regions
(+) API to access to MCU info (CPUID register)
(+) API to enable fault handler (SHCSR accesses)
@endverbatim
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_LL_CORTEX_H
#define __STM32G4xx_LL_CORTEX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
/** @defgroup CORTEX_LL CORTEX
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup CORTEX_LL_Exported_Constants CORTEX Exported Constants
* @{
*/
/** @defgroup CORTEX_LL_EC_CLKSOURCE_HCLK SYSTICK Clock Source
* @{
*/
#define LL_SYSTICK_CLKSOURCE_HCLK_DIV8 0x00000000U /*!< AHB clock divided by 8 selected as SysTick clock source.*/
#define LL_SYSTICK_CLKSOURCE_HCLK SysTick_CTRL_CLKSOURCE_Msk /*!< AHB clock selected as SysTick clock source. */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_FAULT Handler Fault type
* @{
*/
#define LL_HANDLER_FAULT_USG SCB_SHCSR_USGFAULTENA_Msk /*!< Usage fault */
#define LL_HANDLER_FAULT_BUS SCB_SHCSR_BUSFAULTENA_Msk /*!< Bus fault */
#define LL_HANDLER_FAULT_MEM SCB_SHCSR_MEMFAULTENA_Msk /*!< Memory management fault */
/**
* @}
*/
#if __MPU_PRESENT
/** @defgroup CORTEX_LL_EC_CTRL_HFNMI_PRIVDEF MPU Control
* @{
*/
#define LL_MPU_CTRL_HFNMI_PRIVDEF_NONE 0x00000000U /*!< Disable NMI and privileged SW access */
#define LL_MPU_CTRL_HARDFAULT_NMI MPU_CTRL_HFNMIENA_Msk /*!< Enables the operation of MPU during hard fault, NMI, and FAULTMASK handlers */
#define LL_MPU_CTRL_PRIVILEGED_DEFAULT MPU_CTRL_PRIVDEFENA_Msk /*!< Enable privileged software access to default memory map */
#define LL_MPU_CTRL_HFNMI_PRIVDEF (MPU_CTRL_HFNMIENA_Msk | MPU_CTRL_PRIVDEFENA_Msk) /*!< Enable NMI and privileged SW access */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_REGION MPU Region Number
* @{
*/
#define LL_MPU_REGION_NUMBER0 0x00U /*!< REGION Number 0 */
#define LL_MPU_REGION_NUMBER1 0x01U /*!< REGION Number 1 */
#define LL_MPU_REGION_NUMBER2 0x02U /*!< REGION Number 2 */
#define LL_MPU_REGION_NUMBER3 0x03U /*!< REGION Number 3 */
#define LL_MPU_REGION_NUMBER4 0x04U /*!< REGION Number 4 */
#define LL_MPU_REGION_NUMBER5 0x05U /*!< REGION Number 5 */
#define LL_MPU_REGION_NUMBER6 0x06U /*!< REGION Number 6 */
#define LL_MPU_REGION_NUMBER7 0x07U /*!< REGION Number 7 */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_REGION_SIZE MPU Region Size
* @{
*/
#define LL_MPU_REGION_SIZE_32B (0x04U << MPU_RASR_SIZE_Pos) /*!< 32B Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_64B (0x05U << MPU_RASR_SIZE_Pos) /*!< 64B Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_128B (0x06U << MPU_RASR_SIZE_Pos) /*!< 128B Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_256B (0x07U << MPU_RASR_SIZE_Pos) /*!< 256B Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_512B (0x08U << MPU_RASR_SIZE_Pos) /*!< 512B Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_1KB (0x09U << MPU_RASR_SIZE_Pos) /*!< 1KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_2KB (0x0AU << MPU_RASR_SIZE_Pos) /*!< 2KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_4KB (0x0BU << MPU_RASR_SIZE_Pos) /*!< 4KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_8KB (0x0CU << MPU_RASR_SIZE_Pos) /*!< 8KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_16KB (0x0DU << MPU_RASR_SIZE_Pos) /*!< 16KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_32KB (0x0EU << MPU_RASR_SIZE_Pos) /*!< 32KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_64KB (0x0FU << MPU_RASR_SIZE_Pos) /*!< 64KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_128KB (0x10U << MPU_RASR_SIZE_Pos) /*!< 128KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_256KB (0x11U << MPU_RASR_SIZE_Pos) /*!< 256KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_512KB (0x12U << MPU_RASR_SIZE_Pos) /*!< 512KB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_1MB (0x13U << MPU_RASR_SIZE_Pos) /*!< 1MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_2MB (0x14U << MPU_RASR_SIZE_Pos) /*!< 2MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_4MB (0x15U << MPU_RASR_SIZE_Pos) /*!< 4MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_8MB (0x16U << MPU_RASR_SIZE_Pos) /*!< 8MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_16MB (0x17U << MPU_RASR_SIZE_Pos) /*!< 16MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_32MB (0x18U << MPU_RASR_SIZE_Pos) /*!< 32MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_64MB (0x19U << MPU_RASR_SIZE_Pos) /*!< 64MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_128MB (0x1AU << MPU_RASR_SIZE_Pos) /*!< 128MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_256MB (0x1BU << MPU_RASR_SIZE_Pos) /*!< 256MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_512MB (0x1CU << MPU_RASR_SIZE_Pos) /*!< 512MB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_1GB (0x1DU << MPU_RASR_SIZE_Pos) /*!< 1GB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_2GB (0x1EU << MPU_RASR_SIZE_Pos) /*!< 2GB Size of the MPU protection region */
#define LL_MPU_REGION_SIZE_4GB (0x1FU << MPU_RASR_SIZE_Pos) /*!< 4GB Size of the MPU protection region */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_REGION_PRIVILEDGES MPU Region Privileges
* @{
*/
#define LL_MPU_REGION_NO_ACCESS (0x00U << MPU_RASR_AP_Pos) /*!< No access*/
#define LL_MPU_REGION_PRIV_RW (0x01U << MPU_RASR_AP_Pos) /*!< RW privileged (privileged access only)*/
#define LL_MPU_REGION_PRIV_RW_URO (0x02U << MPU_RASR_AP_Pos) /*!< RW privileged - RO user (Write in a user program generates a fault) */
#define LL_MPU_REGION_FULL_ACCESS (0x03U << MPU_RASR_AP_Pos) /*!< RW privileged & user (Full access) */
#define LL_MPU_REGION_PRIV_RO (0x05U << MPU_RASR_AP_Pos) /*!< RO privileged (privileged read only)*/
#define LL_MPU_REGION_PRIV_RO_URO (0x06U << MPU_RASR_AP_Pos) /*!< RO privileged & user (read only) */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_TEX MPU TEX Level
* @{
*/
#define LL_MPU_TEX_LEVEL0 (0x00U << MPU_RASR_TEX_Pos) /*!< b000 for TEX bits */
#define LL_MPU_TEX_LEVEL1 (0x01U << MPU_RASR_TEX_Pos) /*!< b001 for TEX bits */
#define LL_MPU_TEX_LEVEL2 (0x02U << MPU_RASR_TEX_Pos) /*!< b010 for TEX bits */
#define LL_MPU_TEX_LEVEL4 (0x04U << MPU_RASR_TEX_Pos) /*!< b100 for TEX bits */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_INSTRUCTION_ACCESS MPU Instruction Access
* @{
*/
#define LL_MPU_INSTRUCTION_ACCESS_ENABLE 0x00U /*!< Instruction fetches enabled */
#define LL_MPU_INSTRUCTION_ACCESS_DISABLE MPU_RASR_XN_Msk /*!< Instruction fetches disabled*/
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_SHAREABLE_ACCESS MPU Shareable Access
* @{
*/
#define LL_MPU_ACCESS_SHAREABLE MPU_RASR_S_Msk /*!< Shareable memory attribute */
#define LL_MPU_ACCESS_NOT_SHAREABLE 0x00U /*!< Not Shareable memory attribute */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_CACHEABLE_ACCESS MPU Cacheable Access
* @{
*/
#define LL_MPU_ACCESS_CACHEABLE MPU_RASR_C_Msk /*!< Cacheable memory attribute */
#define LL_MPU_ACCESS_NOT_CACHEABLE 0x00U /*!< Not Cacheable memory attribute */
/**
* @}
*/
/** @defgroup CORTEX_LL_EC_BUFFERABLE_ACCESS MPU Bufferable Access
* @{
*/
#define LL_MPU_ACCESS_BUFFERABLE MPU_RASR_B_Msk /*!< Bufferable memory attribute */
#define LL_MPU_ACCESS_NOT_BUFFERABLE 0x00U /*!< Not Bufferable memory attribute */
/**
* @}
*/
#endif /* __MPU_PRESENT */
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup CORTEX_LL_Exported_Functions CORTEX Exported Functions
* @{
*/
/** @defgroup CORTEX_LL_EF_SYSTICK SYSTICK
* @{
*/
/**
* @brief This function checks if the Systick counter flag is active or not.
* @note It can be used in timeout function on application side.
* @rmtoll STK_CTRL COUNTFLAG LL_SYSTICK_IsActiveCounterFlag
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSTICK_IsActiveCounterFlag(void)
{
return (((SysTick->CTRL & SysTick_CTRL_COUNTFLAG_Msk) == (SysTick_CTRL_COUNTFLAG_Msk)) ? 1UL : 0UL);
}
/**
* @brief Configures the SysTick clock source
* @rmtoll STK_CTRL CLKSOURCE LL_SYSTICK_SetClkSource
* @param Source This parameter can be one of the following values:
* @arg @ref LL_SYSTICK_CLKSOURCE_HCLK_DIV8
* @arg @ref LL_SYSTICK_CLKSOURCE_HCLK
* @retval None
*/
__STATIC_INLINE void LL_SYSTICK_SetClkSource(uint32_t Source)
{
if (Source == LL_SYSTICK_CLKSOURCE_HCLK)
{
SET_BIT(SysTick->CTRL, LL_SYSTICK_CLKSOURCE_HCLK);
}
else
{
CLEAR_BIT(SysTick->CTRL, LL_SYSTICK_CLKSOURCE_HCLK);
}
}
/**
* @brief Get the SysTick clock source
* @rmtoll STK_CTRL CLKSOURCE LL_SYSTICK_GetClkSource
* @retval Returned value can be one of the following values:
* @arg @ref LL_SYSTICK_CLKSOURCE_HCLK_DIV8
* @arg @ref LL_SYSTICK_CLKSOURCE_HCLK
*/
__STATIC_INLINE uint32_t LL_SYSTICK_GetClkSource(void)
{
return READ_BIT(SysTick->CTRL, LL_SYSTICK_CLKSOURCE_HCLK);
}
/**
* @brief Enable SysTick exception request
* @rmtoll STK_CTRL TICKINT LL_SYSTICK_EnableIT
* @retval None
*/
__STATIC_INLINE void LL_SYSTICK_EnableIT(void)
{
SET_BIT(SysTick->CTRL, SysTick_CTRL_TICKINT_Msk);
}
/**
* @brief Disable SysTick exception request
* @rmtoll STK_CTRL TICKINT LL_SYSTICK_DisableIT
* @retval None
*/
__STATIC_INLINE void LL_SYSTICK_DisableIT(void)
{
CLEAR_BIT(SysTick->CTRL, SysTick_CTRL_TICKINT_Msk);
}
/**
* @brief Checks if the SYSTICK interrupt is enabled or disabled.
* @rmtoll STK_CTRL TICKINT LL_SYSTICK_IsEnabledIT
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSTICK_IsEnabledIT(void)
{
return ((READ_BIT(SysTick->CTRL, SysTick_CTRL_TICKINT_Msk) == (SysTick_CTRL_TICKINT_Msk)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup CORTEX_LL_EF_LOW_POWER_MODE LOW POWER MODE
* @{
*/
/**
* @brief Processor uses sleep as its low power mode
* @rmtoll SCB_SCR SLEEPDEEP LL_LPM_EnableSleep
* @retval None
*/
__STATIC_INLINE void LL_LPM_EnableSleep(void)
{
/* Clear SLEEPDEEP bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
}
/**
* @brief Processor uses deep sleep as its low power mode
* @rmtoll SCB_SCR SLEEPDEEP LL_LPM_EnableDeepSleep
* @retval None
*/
__STATIC_INLINE void LL_LPM_EnableDeepSleep(void)
{
/* Set SLEEPDEEP bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPDEEP_Msk));
}
/**
* @brief Configures sleep-on-exit when returning from Handler mode to Thread mode.
* @note Setting this bit to 1 enables an interrupt-driven application to avoid returning to an
* empty main application.
* @rmtoll SCB_SCR SLEEPONEXIT LL_LPM_EnableSleepOnExit
* @retval None
*/
__STATIC_INLINE void LL_LPM_EnableSleepOnExit(void)
{
/* Set SLEEPONEXIT bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPONEXIT_Msk));
}
/**
* @brief Do not sleep when returning to Thread mode.
* @rmtoll SCB_SCR SLEEPONEXIT LL_LPM_DisableSleepOnExit
* @retval None
*/
__STATIC_INLINE void LL_LPM_DisableSleepOnExit(void)
{
/* Clear SLEEPONEXIT bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SLEEPONEXIT_Msk));
}
/**
* @brief Enabled events and all interrupts, including disabled interrupts, can wakeup the
* processor.
* @rmtoll SCB_SCR SEVEONPEND LL_LPM_EnableEventOnPend
* @retval None
*/
__STATIC_INLINE void LL_LPM_EnableEventOnPend(void)
{
/* Set SEVEONPEND bit of Cortex System Control Register */
SET_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SEVONPEND_Msk));
}
/**
* @brief Only enabled interrupts or events can wakeup the processor, disabled interrupts are
* excluded
* @rmtoll SCB_SCR SEVEONPEND LL_LPM_DisableEventOnPend
* @retval None
*/
__STATIC_INLINE void LL_LPM_DisableEventOnPend(void)
{
/* Clear SEVEONPEND bit of Cortex System Control Register */
CLEAR_BIT(SCB->SCR, ((uint32_t)SCB_SCR_SEVONPEND_Msk));
}
/**
* @}
*/
/** @defgroup CORTEX_LL_EF_HANDLER HANDLER
* @{
*/
/**
* @brief Enable a fault in System handler control register (SHCSR)
* @rmtoll SCB_SHCSR MEMFAULTENA LL_HANDLER_EnableFault
* @param Fault This parameter can be a combination of the following values:
* @arg @ref LL_HANDLER_FAULT_USG
* @arg @ref LL_HANDLER_FAULT_BUS
* @arg @ref LL_HANDLER_FAULT_MEM
* @retval None
*/
__STATIC_INLINE void LL_HANDLER_EnableFault(uint32_t Fault)
{
/* Enable the system handler fault */
SET_BIT(SCB->SHCSR, Fault);
}
/**
* @brief Disable a fault in System handler control register (SHCSR)
* @rmtoll SCB_SHCSR MEMFAULTENA LL_HANDLER_DisableFault
* @param Fault This parameter can be a combination of the following values:
* @arg @ref LL_HANDLER_FAULT_USG
* @arg @ref LL_HANDLER_FAULT_BUS
* @arg @ref LL_HANDLER_FAULT_MEM
* @retval None
*/
__STATIC_INLINE void LL_HANDLER_DisableFault(uint32_t Fault)
{
/* Disable the system handler fault */
CLEAR_BIT(SCB->SHCSR, Fault);
}
/**
* @}
*/
/** @defgroup CORTEX_LL_EF_MCU_INFO MCU INFO
* @{
*/
/**
* @brief Get Implementer code
* @rmtoll SCB_CPUID IMPLEMENTER LL_CPUID_GetImplementer
* @retval Value should be equal to 0x41 for ARM
*/
__STATIC_INLINE uint32_t LL_CPUID_GetImplementer(void)
{
return (uint32_t)(READ_BIT(SCB->CPUID, SCB_CPUID_IMPLEMENTER_Msk) >> SCB_CPUID_IMPLEMENTER_Pos);
}
/**
* @brief Get Variant number (The r value in the rnpn product revision identifier)
* @rmtoll SCB_CPUID VARIANT LL_CPUID_GetVariant
* @retval Value between 0 and 255 (0x0: revision 0)
*/
__STATIC_INLINE uint32_t LL_CPUID_GetVariant(void)
{
return (uint32_t)(READ_BIT(SCB->CPUID, SCB_CPUID_VARIANT_Msk) >> SCB_CPUID_VARIANT_Pos);
}
/**
* @brief Get Architecture number
* @rmtoll SCB_CPUID ARCHITECTURE LL_CPUID_GetArchitecture
* @retval Value should be equal to 0xF for Cortex-M4 devices
*/
__STATIC_INLINE uint32_t LL_CPUID_GetArchitecture(void)
{
return (uint32_t)(READ_BIT(SCB->CPUID, SCB_CPUID_ARCHITECTURE_Msk) >> SCB_CPUID_ARCHITECTURE_Pos);
}
/**
* @brief Get Part number
* @rmtoll SCB_CPUID PARTNO LL_CPUID_GetParNo
* @retval Value should be equal to 0xC24 for Cortex-M4
*/
__STATIC_INLINE uint32_t LL_CPUID_GetParNo(void)
{
return (uint32_t)(READ_BIT(SCB->CPUID, SCB_CPUID_PARTNO_Msk) >> SCB_CPUID_PARTNO_Pos);
}
/**
* @brief Get Revision number (The p value in the rnpn product revision identifier, indicates patch release)
* @rmtoll SCB_CPUID REVISION LL_CPUID_GetRevision
* @retval Value between 0 and 255 (0x1: patch 1)
*/
__STATIC_INLINE uint32_t LL_CPUID_GetRevision(void)
{
return (uint32_t)(READ_BIT(SCB->CPUID, SCB_CPUID_REVISION_Msk) >> SCB_CPUID_REVISION_Pos);
}
/**
* @}
*/
#if __MPU_PRESENT
/** @defgroup CORTEX_LL_EF_MPU MPU
* @{
*/
/**
* @brief Enable MPU with input options
* @rmtoll MPU_CTRL ENABLE LL_MPU_Enable
* @param Options This parameter can be one of the following values:
* @arg @ref LL_MPU_CTRL_HFNMI_PRIVDEF_NONE
* @arg @ref LL_MPU_CTRL_HARDFAULT_NMI
* @arg @ref LL_MPU_CTRL_PRIVILEGED_DEFAULT
* @arg @ref LL_MPU_CTRL_HFNMI_PRIVDEF
* @retval None
*/
__STATIC_INLINE void LL_MPU_Enable(uint32_t Options)
{
/* Enable the MPU*/
WRITE_REG(MPU->CTRL, (MPU_CTRL_ENABLE_Msk | Options));
/* Ensure MPU settings take effects */
__DSB();
/* Sequence instruction fetches using update settings */
__ISB();
}
/**
* @brief Disable MPU
* @rmtoll MPU_CTRL ENABLE LL_MPU_Disable
* @retval None
*/
__STATIC_INLINE void LL_MPU_Disable(void)
{
/* Make sure outstanding transfers are done */
__DMB();
/* Disable MPU*/
WRITE_REG(MPU->CTRL, 0U);
}
/**
* @brief Check if MPU is enabled or not
* @rmtoll MPU_CTRL ENABLE LL_MPU_IsEnabled
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_MPU_IsEnabled(void)
{
return ((READ_BIT(MPU->CTRL, MPU_CTRL_ENABLE_Msk) == (MPU_CTRL_ENABLE_Msk)) ? 1UL : 0UL);
}
/**
* @brief Enable a MPU region
* @rmtoll MPU_RASR ENABLE LL_MPU_EnableRegion
* @param Region This parameter can be one of the following values:
* @arg @ref LL_MPU_REGION_NUMBER0
* @arg @ref LL_MPU_REGION_NUMBER1
* @arg @ref LL_MPU_REGION_NUMBER2
* @arg @ref LL_MPU_REGION_NUMBER3
* @arg @ref LL_MPU_REGION_NUMBER4
* @arg @ref LL_MPU_REGION_NUMBER5
* @arg @ref LL_MPU_REGION_NUMBER6
* @arg @ref LL_MPU_REGION_NUMBER7
* @retval None
*/
__STATIC_INLINE void LL_MPU_EnableRegion(uint32_t Region)
{
/* Set Region number */
WRITE_REG(MPU->RNR, Region);
/* Enable the MPU region */
SET_BIT(MPU->RASR, MPU_RASR_ENABLE_Msk);
}
/**
* @brief Configure and enable a region
* @rmtoll MPU_RNR REGION LL_MPU_ConfigRegion\n
* MPU_RBAR REGION LL_MPU_ConfigRegion\n
* MPU_RBAR ADDR LL_MPU_ConfigRegion\n
* MPU_RASR XN LL_MPU_ConfigRegion\n
* MPU_RASR AP LL_MPU_ConfigRegion\n
* MPU_RASR S LL_MPU_ConfigRegion\n
* MPU_RASR C LL_MPU_ConfigRegion\n
* MPU_RASR B LL_MPU_ConfigRegion\n
* MPU_RASR SIZE LL_MPU_ConfigRegion
* @param Region This parameter can be one of the following values:
* @arg @ref LL_MPU_REGION_NUMBER0
* @arg @ref LL_MPU_REGION_NUMBER1
* @arg @ref LL_MPU_REGION_NUMBER2
* @arg @ref LL_MPU_REGION_NUMBER3
* @arg @ref LL_MPU_REGION_NUMBER4
* @arg @ref LL_MPU_REGION_NUMBER5
* @arg @ref LL_MPU_REGION_NUMBER6
* @arg @ref LL_MPU_REGION_NUMBER7
* @param Address Value of region base address
* @param SubRegionDisable Sub-region disable value between Min_Data = 0x00 and Max_Data = 0xFF
* @param Attributes This parameter can be a combination of the following values:
* @arg @ref LL_MPU_REGION_SIZE_32B or @ref LL_MPU_REGION_SIZE_64B or @ref LL_MPU_REGION_SIZE_128B or @ref LL_MPU_REGION_SIZE_256B or @ref LL_MPU_REGION_SIZE_512B
* or @ref LL_MPU_REGION_SIZE_1KB or @ref LL_MPU_REGION_SIZE_2KB or @ref LL_MPU_REGION_SIZE_4KB or @ref LL_MPU_REGION_SIZE_8KB or @ref LL_MPU_REGION_SIZE_16KB
* or @ref LL_MPU_REGION_SIZE_32KB or @ref LL_MPU_REGION_SIZE_64KB or @ref LL_MPU_REGION_SIZE_128KB or @ref LL_MPU_REGION_SIZE_256KB or @ref LL_MPU_REGION_SIZE_512KB
* or @ref LL_MPU_REGION_SIZE_1MB or @ref LL_MPU_REGION_SIZE_2MB or @ref LL_MPU_REGION_SIZE_4MB or @ref LL_MPU_REGION_SIZE_8MB or @ref LL_MPU_REGION_SIZE_16MB
* or @ref LL_MPU_REGION_SIZE_32MB or @ref LL_MPU_REGION_SIZE_64MB or @ref LL_MPU_REGION_SIZE_128MB or @ref LL_MPU_REGION_SIZE_256MB or @ref LL_MPU_REGION_SIZE_512MB
* or @ref LL_MPU_REGION_SIZE_1GB or @ref LL_MPU_REGION_SIZE_2GB or @ref LL_MPU_REGION_SIZE_4GB
* @arg @ref LL_MPU_REGION_NO_ACCESS or @ref LL_MPU_REGION_PRIV_RW or @ref LL_MPU_REGION_PRIV_RW_URO or @ref LL_MPU_REGION_FULL_ACCESS
* or @ref LL_MPU_REGION_PRIV_RO or @ref LL_MPU_REGION_PRIV_RO_URO
* @arg @ref LL_MPU_TEX_LEVEL0 or @ref LL_MPU_TEX_LEVEL1 or @ref LL_MPU_TEX_LEVEL2 or @ref LL_MPU_TEX_LEVEL4
* @arg @ref LL_MPU_INSTRUCTION_ACCESS_ENABLE or @ref LL_MPU_INSTRUCTION_ACCESS_DISABLE
* @arg @ref LL_MPU_ACCESS_SHAREABLE or @ref LL_MPU_ACCESS_NOT_SHAREABLE
* @arg @ref LL_MPU_ACCESS_CACHEABLE or @ref LL_MPU_ACCESS_NOT_CACHEABLE
* @arg @ref LL_MPU_ACCESS_BUFFERABLE or @ref LL_MPU_ACCESS_NOT_BUFFERABLE
* @retval None
*/
__STATIC_INLINE void LL_MPU_ConfigRegion(uint32_t Region, uint32_t SubRegionDisable, uint32_t Address, uint32_t Attributes)
{
/* Set Region number */
WRITE_REG(MPU->RNR, Region);
/* Set base address */
WRITE_REG(MPU->RBAR, (Address & 0xFFFFFFE0U));
/* Configure MPU */
WRITE_REG(MPU->RASR, (MPU_RASR_ENABLE_Msk | Attributes | (SubRegionDisable << MPU_RASR_SRD_Pos)));
}
/**
* @brief Disable a region
* @rmtoll MPU_RNR REGION LL_MPU_DisableRegion\n
* MPU_RASR ENABLE LL_MPU_DisableRegion
* @param Region This parameter can be one of the following values:
* @arg @ref LL_MPU_REGION_NUMBER0
* @arg @ref LL_MPU_REGION_NUMBER1
* @arg @ref LL_MPU_REGION_NUMBER2
* @arg @ref LL_MPU_REGION_NUMBER3
* @arg @ref LL_MPU_REGION_NUMBER4
* @arg @ref LL_MPU_REGION_NUMBER5
* @arg @ref LL_MPU_REGION_NUMBER6
* @arg @ref LL_MPU_REGION_NUMBER7
* @retval None
*/
__STATIC_INLINE void LL_MPU_DisableRegion(uint32_t Region)
{
/* Set Region number */
WRITE_REG(MPU->RNR, Region);
/* Disable the MPU region */
CLEAR_BIT(MPU->RASR, MPU_RASR_ENABLE_Msk);
}
/**
* @}
*/
#endif /* __MPU_PRESENT */
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_LL_CORTEX_H */
| 24,173 | C | 36.890282 | 176 | 0.606793 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_crc.h | /**
******************************************************************************
* @file stm32g4xx_ll_crc.h
* @author MCD Application Team
* @brief Header file of CRC LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_CRC_H
#define STM32G4xx_LL_CRC_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined(CRC)
/** @defgroup CRC_LL CRC
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup CRC_LL_Exported_Constants CRC Exported Constants
* @{
*/
/** @defgroup CRC_LL_EC_POLYLENGTH Polynomial length
* @{
*/
#define LL_CRC_POLYLENGTH_32B 0x00000000U /*!< 32 bits Polynomial size */
#define LL_CRC_POLYLENGTH_16B CRC_CR_POLYSIZE_0 /*!< 16 bits Polynomial size */
#define LL_CRC_POLYLENGTH_8B CRC_CR_POLYSIZE_1 /*!< 8 bits Polynomial size */
#define LL_CRC_POLYLENGTH_7B (CRC_CR_POLYSIZE_1 | CRC_CR_POLYSIZE_0) /*!< 7 bits Polynomial size */
/**
* @}
*/
/** @defgroup CRC_LL_EC_INDATA_REVERSE Input Data Reverse
* @{
*/
#define LL_CRC_INDATA_REVERSE_NONE 0x00000000U /*!< Input Data bit order not affected */
#define LL_CRC_INDATA_REVERSE_BYTE CRC_CR_REV_IN_0 /*!< Input Data bit reversal done by byte */
#define LL_CRC_INDATA_REVERSE_HALFWORD CRC_CR_REV_IN_1 /*!< Input Data bit reversal done by half-word */
#define LL_CRC_INDATA_REVERSE_WORD (CRC_CR_REV_IN_1 | CRC_CR_REV_IN_0) /*!< Input Data bit reversal done by word */
/**
* @}
*/
/** @defgroup CRC_LL_EC_OUTDATA_REVERSE Output Data Reverse
* @{
*/
#define LL_CRC_OUTDATA_REVERSE_NONE 0x00000000U /*!< Output Data bit order not affected */
#define LL_CRC_OUTDATA_REVERSE_BIT CRC_CR_REV_OUT /*!< Output Data bit reversal done by bit */
/**
* @}
*/
/** @defgroup CRC_LL_EC_Default_Polynomial_Value Default CRC generating polynomial value
* @brief Normal representation of this polynomial value is
* X^32 + X^26 + X^23 + X^22 + X^16 + X^12 + X^11 + X^10 +X^8 + X^7 + X^5 + X^4 + X^2 + X + 1 .
* @{
*/
#define LL_CRC_DEFAULT_CRC32_POLY 0x04C11DB7U /*!< Default CRC generating polynomial value */
/**
* @}
*/
/** @defgroup CRC_LL_EC_Default_InitValue Default CRC computation initialization value
* @{
*/
#define LL_CRC_DEFAULT_CRC_INITVALUE 0xFFFFFFFFU /*!< Default CRC computation initialization value */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup CRC_LL_Exported_Macros CRC Exported Macros
* @{
*/
/** @defgroup CRC_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in CRC register
* @param __INSTANCE__ CRC Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_CRC_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG(__INSTANCE__->__REG__, __VALUE__)
/**
* @brief Read a value in CRC register
* @param __INSTANCE__ CRC Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_CRC_ReadReg(__INSTANCE__, __REG__) READ_REG(__INSTANCE__->__REG__)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup CRC_LL_Exported_Functions CRC Exported Functions
* @{
*/
/** @defgroup CRC_LL_EF_Configuration CRC Configuration functions
* @{
*/
/**
* @brief Reset the CRC calculation unit.
* @note If Programmable Initial CRC value feature
* is available, also set the Data Register to the value stored in the
* CRC_INIT register, otherwise, reset Data Register to its default value.
* @rmtoll CR RESET LL_CRC_ResetCRCCalculationUnit
* @param CRCx CRC Instance
* @retval None
*/
__STATIC_INLINE void LL_CRC_ResetCRCCalculationUnit(CRC_TypeDef *CRCx)
{
SET_BIT(CRCx->CR, CRC_CR_RESET);
}
/**
* @brief Configure size of the polynomial.
* @rmtoll CR POLYSIZE LL_CRC_SetPolynomialSize
* @param CRCx CRC Instance
* @param PolySize This parameter can be one of the following values:
* @arg @ref LL_CRC_POLYLENGTH_32B
* @arg @ref LL_CRC_POLYLENGTH_16B
* @arg @ref LL_CRC_POLYLENGTH_8B
* @arg @ref LL_CRC_POLYLENGTH_7B
* @retval None
*/
__STATIC_INLINE void LL_CRC_SetPolynomialSize(CRC_TypeDef *CRCx, uint32_t PolySize)
{
MODIFY_REG(CRCx->CR, CRC_CR_POLYSIZE, PolySize);
}
/**
* @brief Return size of the polynomial.
* @rmtoll CR POLYSIZE LL_CRC_GetPolynomialSize
* @param CRCx CRC Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_CRC_POLYLENGTH_32B
* @arg @ref LL_CRC_POLYLENGTH_16B
* @arg @ref LL_CRC_POLYLENGTH_8B
* @arg @ref LL_CRC_POLYLENGTH_7B
*/
__STATIC_INLINE uint32_t LL_CRC_GetPolynomialSize(const CRC_TypeDef *CRCx)
{
return (uint32_t)(READ_BIT(CRCx->CR, CRC_CR_POLYSIZE));
}
/**
* @brief Configure the reversal of the bit order of the input data
* @rmtoll CR REV_IN LL_CRC_SetInputDataReverseMode
* @param CRCx CRC Instance
* @param ReverseMode This parameter can be one of the following values:
* @arg @ref LL_CRC_INDATA_REVERSE_NONE
* @arg @ref LL_CRC_INDATA_REVERSE_BYTE
* @arg @ref LL_CRC_INDATA_REVERSE_HALFWORD
* @arg @ref LL_CRC_INDATA_REVERSE_WORD
* @retval None
*/
__STATIC_INLINE void LL_CRC_SetInputDataReverseMode(CRC_TypeDef *CRCx, uint32_t ReverseMode)
{
MODIFY_REG(CRCx->CR, CRC_CR_REV_IN, ReverseMode);
}
/**
* @brief Return type of reversal for input data bit order
* @rmtoll CR REV_IN LL_CRC_GetInputDataReverseMode
* @param CRCx CRC Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_CRC_INDATA_REVERSE_NONE
* @arg @ref LL_CRC_INDATA_REVERSE_BYTE
* @arg @ref LL_CRC_INDATA_REVERSE_HALFWORD
* @arg @ref LL_CRC_INDATA_REVERSE_WORD
*/
__STATIC_INLINE uint32_t LL_CRC_GetInputDataReverseMode(const CRC_TypeDef *CRCx)
{
return (uint32_t)(READ_BIT(CRCx->CR, CRC_CR_REV_IN));
}
/**
* @brief Configure the reversal of the bit order of the Output data
* @rmtoll CR REV_OUT LL_CRC_SetOutputDataReverseMode
* @param CRCx CRC Instance
* @param ReverseMode This parameter can be one of the following values:
* @arg @ref LL_CRC_OUTDATA_REVERSE_NONE
* @arg @ref LL_CRC_OUTDATA_REVERSE_BIT
* @retval None
*/
__STATIC_INLINE void LL_CRC_SetOutputDataReverseMode(CRC_TypeDef *CRCx, uint32_t ReverseMode)
{
MODIFY_REG(CRCx->CR, CRC_CR_REV_OUT, ReverseMode);
}
/**
* @brief Return type of reversal of the bit order of the Output data
* @rmtoll CR REV_OUT LL_CRC_GetOutputDataReverseMode
* @param CRCx CRC Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_CRC_OUTDATA_REVERSE_NONE
* @arg @ref LL_CRC_OUTDATA_REVERSE_BIT
*/
__STATIC_INLINE uint32_t LL_CRC_GetOutputDataReverseMode(const CRC_TypeDef *CRCx)
{
return (uint32_t)(READ_BIT(CRCx->CR, CRC_CR_REV_OUT));
}
/**
* @brief Initialize the Programmable initial CRC value.
* @note If the CRC size is less than 32 bits, the least significant bits
* are used to write the correct value
* @note LL_CRC_DEFAULT_CRC_INITVALUE could be used as value for InitCrc parameter.
* @rmtoll INIT INIT LL_CRC_SetInitialData
* @param CRCx CRC Instance
* @param InitCrc Value to be programmed in Programmable initial CRC value register
* @retval None
*/
__STATIC_INLINE void LL_CRC_SetInitialData(CRC_TypeDef *CRCx, uint32_t InitCrc)
{
WRITE_REG(CRCx->INIT, InitCrc);
}
/**
* @brief Return current Initial CRC value.
* @note If the CRC size is less than 32 bits, the least significant bits
* are used to read the correct value
* @rmtoll INIT INIT LL_CRC_GetInitialData
* @param CRCx CRC Instance
* @retval Value programmed in Programmable initial CRC value register
*/
__STATIC_INLINE uint32_t LL_CRC_GetInitialData(const CRC_TypeDef *CRCx)
{
return (uint32_t)(READ_REG(CRCx->INIT));
}
/**
* @brief Initialize the Programmable polynomial value
* (coefficients of the polynomial to be used for CRC calculation).
* @note LL_CRC_DEFAULT_CRC32_POLY could be used as value for PolynomCoef parameter.
* @note Please check Reference Manual and existing Errata Sheets,
* regarding possible limitations for Polynomial values usage.
* For example, for a polynomial of degree 7, X^7 + X^6 + X^5 + X^2 + 1 is written 0x65
* @rmtoll POL POL LL_CRC_SetPolynomialCoef
* @param CRCx CRC Instance
* @param PolynomCoef Value to be programmed in Programmable Polynomial value register
* @retval None
*/
__STATIC_INLINE void LL_CRC_SetPolynomialCoef(CRC_TypeDef *CRCx, uint32_t PolynomCoef)
{
WRITE_REG(CRCx->POL, PolynomCoef);
}
/**
* @brief Return current Programmable polynomial value
* @note Please check Reference Manual and existing Errata Sheets,
* regarding possible limitations for Polynomial values usage.
* For example, for a polynomial of degree 7, X^7 + X^6 + X^5 + X^2 + 1 is written 0x65
* @rmtoll POL POL LL_CRC_GetPolynomialCoef
* @param CRCx CRC Instance
* @retval Value programmed in Programmable Polynomial value register
*/
__STATIC_INLINE uint32_t LL_CRC_GetPolynomialCoef(const CRC_TypeDef *CRCx)
{
return (uint32_t)(READ_REG(CRCx->POL));
}
/**
* @}
*/
/** @defgroup CRC_LL_EF_Data_Management Data_Management
* @{
*/
/**
* @brief Write given 32-bit data to the CRC calculator
* @rmtoll DR DR LL_CRC_FeedData32
* @param CRCx CRC Instance
* @param InData value to be provided to CRC calculator between between Min_Data=0 and Max_Data=0xFFFFFFFF
* @retval None
*/
__STATIC_INLINE void LL_CRC_FeedData32(CRC_TypeDef *CRCx, uint32_t InData)
{
WRITE_REG(CRCx->DR, InData);
}
/**
* @brief Write given 16-bit data to the CRC calculator
* @rmtoll DR DR LL_CRC_FeedData16
* @param CRCx CRC Instance
* @param InData 16 bit value to be provided to CRC calculator between between Min_Data=0 and Max_Data=0xFFFF
* @retval None
*/
__STATIC_INLINE void LL_CRC_FeedData16(CRC_TypeDef *CRCx, uint16_t InData)
{
__IO uint16_t *pReg;
pReg = (__IO uint16_t *)(__IO void *)(&CRCx->DR); /* Derogation MisraC2012 R.11.5 */
*pReg = InData;
}
/**
* @brief Write given 8-bit data to the CRC calculator
* @rmtoll DR DR LL_CRC_FeedData8
* @param CRCx CRC Instance
* @param InData 8 bit value to be provided to CRC calculator between between Min_Data=0 and Max_Data=0xFF
* @retval None
*/
__STATIC_INLINE void LL_CRC_FeedData8(CRC_TypeDef *CRCx, uint8_t InData)
{
*(uint8_t __IO *)(&CRCx->DR) = (uint8_t) InData;
}
/**
* @brief Return current CRC calculation result. 32 bits value is returned.
* @rmtoll DR DR LL_CRC_ReadData32
* @param CRCx CRC Instance
* @retval Current CRC calculation result as stored in CRC_DR register (32 bits).
*/
__STATIC_INLINE uint32_t LL_CRC_ReadData32(const CRC_TypeDef *CRCx)
{
return (uint32_t)(READ_REG(CRCx->DR));
}
/**
* @brief Return current CRC calculation result. 16 bits value is returned.
* @note This function is expected to be used in a 16 bits CRC polynomial size context.
* @rmtoll DR DR LL_CRC_ReadData16
* @param CRCx CRC Instance
* @retval Current CRC calculation result as stored in CRC_DR register (16 bits).
*/
__STATIC_INLINE uint16_t LL_CRC_ReadData16(const CRC_TypeDef *CRCx)
{
return (uint16_t)READ_REG(CRCx->DR);
}
/**
* @brief Return current CRC calculation result. 8 bits value is returned.
* @note This function is expected to be used in a 8 bits CRC polynomial size context.
* @rmtoll DR DR LL_CRC_ReadData8
* @param CRCx CRC Instance
* @retval Current CRC calculation result as stored in CRC_DR register (8 bits).
*/
__STATIC_INLINE uint8_t LL_CRC_ReadData8(const CRC_TypeDef *CRCx)
{
return (uint8_t)READ_REG(CRCx->DR);
}
/**
* @brief Return current CRC calculation result. 7 bits value is returned.
* @note This function is expected to be used in a 7 bits CRC polynomial size context.
* @rmtoll DR DR LL_CRC_ReadData7
* @param CRCx CRC Instance
* @retval Current CRC calculation result as stored in CRC_DR register (7 bits).
*/
__STATIC_INLINE uint8_t LL_CRC_ReadData7(const CRC_TypeDef *CRCx)
{
return (uint8_t)(READ_REG(CRCx->DR) & 0x7FU);
}
/**
* @brief Return data stored in the Independent Data(IDR) register.
* @note This register can be used as a temporary storage location for one 32-bit long data.
* @rmtoll IDR IDR LL_CRC_Read_IDR
* @param CRCx CRC Instance
* @retval Value stored in CRC_IDR register (General-purpose 32-bit data register).
*/
__STATIC_INLINE uint32_t LL_CRC_Read_IDR(const CRC_TypeDef *CRCx)
{
return (uint32_t)(READ_REG(CRCx->IDR));
}
/**
* @brief Store data in the Independent Data(IDR) register.
* @note This register can be used as a temporary storage location for one 32-bit long data.
* @rmtoll IDR IDR LL_CRC_Write_IDR
* @param CRCx CRC Instance
* @param InData value to be stored in CRC_IDR register (32-bit) between Min_Data=0 and Max_Data=0xFFFFFFFF
* @retval None
*/
__STATIC_INLINE void LL_CRC_Write_IDR(CRC_TypeDef *CRCx, uint32_t InData)
{
*((uint32_t __IO *)(&CRCx->IDR)) = (uint32_t) InData;
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup CRC_LL_EF_Init Initialization and de-initialization functions
* @{
*/
ErrorStatus LL_CRC_DeInit(const CRC_TypeDef *CRCx);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* defined(CRC) */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_CRC_H */
| 15,586 | C | 32.738095 | 137 | 0.602785 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_utils.h | /**
******************************************************************************
* @file stm32g4xx_ll_utils.h
* @author MCD Application Team
* @brief Header file of UTILS LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
The LL UTILS driver contains a set of generic APIs that can be
used by user:
(+) Device electronic signature
(+) Timing functions
(+) PLL configuration functions
@endverbatim
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_UTILS_H
#define STM32G4xx_LL_UTILS_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
/** @defgroup UTILS_LL UTILS
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup UTILS_LL_Private_Constants UTILS Private Constants
* @{
*/
/* Max delay can be used in LL_mDelay */
#define LL_MAX_DELAY 0xFFFFFFFFU
/**
* @brief Unique device ID register base address
*/
#define UID_BASE_ADDRESS UID_BASE
/**
* @brief Flash size data register base address
*/
#define FLASHSIZE_BASE_ADDRESS FLASHSIZE_BASE
/**
* @brief Package data register base address
*/
#define PACKAGE_BASE_ADDRESS PACKAGE_BASE
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup UTILS_LL_Private_Macros UTILS Private Macros
* @{
*/
/**
* @}
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup UTILS_LL_ES_INIT UTILS Exported structures
* @{
*/
/**
* @brief UTILS PLL structure definition
*/
typedef struct
{
uint32_t PLLM; /*!< Division factor for PLL VCO input clock.
This parameter can be a value of @ref RCC_LL_EC_PLLM_DIV
This feature can be modified afterwards using unitary function
@ref LL_RCC_PLL_ConfigDomain_SYS(). */
uint32_t PLLN; /*!< Multiplication factor for PLL VCO output clock.
This parameter must be a number between Min_Data = 8 and Max_Data = 86
This feature can be modified afterwards using unitary function
@ref LL_RCC_PLL_ConfigDomain_SYS(). */
uint32_t PLLR; /*!< Division for the main system clock.
This parameter can be a value of @ref RCC_LL_EC_PLLR_DIV
This feature can be modified afterwards using unitary function
@ref LL_RCC_PLL_ConfigDomain_SYS(). */
} LL_UTILS_PLLInitTypeDef;
/**
* @brief UTILS System, AHB and APB buses clock configuration structure definition
*/
typedef struct
{
uint32_t AHBCLKDivider; /*!< The AHB clock (HCLK) divider. This clock is derived from the system clock (SYSCLK).
This parameter can be a value of @ref RCC_LL_EC_SYSCLK_DIV
This feature can be modified afterwards using unitary function
@ref LL_RCC_SetAHBPrescaler(). */
uint32_t APB1CLKDivider; /*!< The APB1 clock (PCLK1) divider. This clock is derived from the AHB clock (HCLK).
This parameter can be a value of @ref RCC_LL_EC_APB1_DIV
This feature can be modified afterwards using unitary function
@ref LL_RCC_SetAPB1Prescaler(). */
uint32_t APB2CLKDivider; /*!< The APB2 clock (PCLK2) divider. This clock is derived from the AHB clock (HCLK).
This parameter can be a value of @ref RCC_LL_EC_APB2_DIV
This feature can be modified afterwards using unitary function
@ref LL_RCC_SetAPB2Prescaler(). */
} LL_UTILS_ClkInitTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup UTILS_LL_Exported_Constants UTILS Exported Constants
* @{
*/
/** @defgroup UTILS_EC_HSE_BYPASS HSE Bypass activation
* @{
*/
#define LL_UTILS_HSEBYPASS_OFF 0x00000000U /*!< HSE Bypass is not enabled */
#define LL_UTILS_HSEBYPASS_ON 0x00000001U /*!< HSE Bypass is enabled */
/**
* @}
*/
/** @defgroup UTILS_EC_PACKAGETYPE PACKAGE TYPE
* @{
*/
#define LL_UTILS_PACKAGETYPE_LQFP64 0x00000000U /*!< LQFP64 package type */
#define LL_UTILS_PACKAGETYPE_WLCSP64 0x00000001U /*!< WLCSP64 package type */
#if defined (STM32G431xx) || defined (STM32G441xx) || defined (STM32G471xx) || \
defined (STM32G473xx) || defined (STM32G483xx) || defined (STM32G474xx) || \
defined (STM32G484xx)
#define LL_UTILS_PACKAGETYPE_LQFP100_LQFP80 0x00000002U /*!< LQFP100 \ LQFP80 package type */
#define LL_UTILS_PACKAGETYPE_LQFP100 LL_UTILS_PACKAGETYPE_LQFP100_LQFP80 /*!< For backward compatibility */
#else
#define LL_UTILS_PACKAGETYPE_LQFP100 0x00000002U /*!< LQFP100 package type */
#endif /* STM32G431xx || STM32G441xx || STM32G471xx || STM32G473xx || STM32G483xx ||STM32G474xx || STM32G484xx */
#define LL_UTILS_PACKAGETYPE_WLCSP81 0x00000005U /*!< WLCSP81 package type */
#define LL_UTILS_PACKAGETYPE_LQFP128_UFBGA121 0x00000007U /*!< LQFP128 \ UFBGA121 package type */
#define LL_UTILS_PACKAGETYPE_LQFP128 LL_UTILS_PACKAGETYPE_LQFP128_UFBGA121 /*!< For backward compatibility */
#define LL_UTILS_PACKAGETYPE_UFQFPN32 0x00000008U /*!< UFQFPN32 package type */
#define LL_UTILS_PACKAGETYPE_LQFP32 0x00000009U /*!< LQFP32 package type */
#define LL_UTILS_PACKAGETYPE_UFQFPN48 0x0000000AU /*!< UFQFPN48 package type */
#define LL_UTILS_PACKAGETYPE_LQFP48 0x0000000BU /*!< LQFP48 package type */
#define LL_UTILS_PACKAGETYPE_WLCSP49 0x0000000CU /*!< WLCSP49 package type */
#define LL_UTILS_PACKAGETYPE_UFBGA64 0x0000000DU /*!< UFBGA64 package type */
#define LL_UTILS_PACKAGETYPE_TFBGA100 0x0000000EU /*!< TFBGA100 package type */
#define LL_UTILS_PACKAGETYPE_UFBGA100 LL_UTILS_PACKAGETYPE_TFBGA100 /*!< For backward compatibility */
#define LL_UTILS_PACKAGETYPE_LQFP48_EBIKE 0x00000010U /*!< LQFP48 EBIKE package type */
#if defined (STM32G491xx) || defined (STM32G4A1xx)
#define LL_UTILS_PACKAGETYPE_LQFP80 0x00000011U /*!< LQFP80 package type */
#endif /* STM32G491xx || STM32G4A1xx */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup UTILS_LL_Exported_Functions UTILS Exported Functions
* @{
*/
/** @defgroup UTILS_EF_DEVICE_ELECTRONIC_SIGNATURE DEVICE ELECTRONIC SIGNATURE
* @{
*/
/**
* @brief Get Word0 of the unique device identifier (UID based on 96 bits)
* @retval UID[31:0]: X and Y coordinates on the wafer expressed in BCD format
*/
__STATIC_INLINE uint32_t LL_GetUID_Word0(void)
{
return (uint32_t)(READ_REG(*((uint32_t *)UID_BASE_ADDRESS)));
}
/**
* @brief Get Word1 of the unique device identifier (UID based on 96 bits)
* @retval UID[63:32]: Wafer number (UID[39:32]) & LOT_NUM[23:0] (UID[63:40])
*/
__STATIC_INLINE uint32_t LL_GetUID_Word1(void)
{
return (uint32_t)(READ_REG(*((uint32_t *)(UID_BASE_ADDRESS + 4U))));
}
/**
* @brief Get Word2 of the unique device identifier (UID based on 96 bits)
* @retval UID[95:64]: Lot number (ASCII encoded) - LOT_NUM[55:24]
*/
__STATIC_INLINE uint32_t LL_GetUID_Word2(void)
{
return (uint32_t)(READ_REG(*((uint32_t *)(UID_BASE_ADDRESS + 8U))));
}
/**
* @brief Get Flash memory size
* @note This bitfield indicates the size of the device Flash memory expressed in
* Kbytes. As an example, 0x040 corresponds to 64 Kbytes.
* @retval FLASH_SIZE[15:0]: Flash memory size
*/
__STATIC_INLINE uint32_t LL_GetFlashSize(void)
{
return (uint32_t)(READ_REG(*((uint32_t *)FLASHSIZE_BASE_ADDRESS)) & 0x0000FFFFUL);
}
/**
* @brief Get Package type
* @retval Returned value can be one of the following values:
* @arg @ref LL_UTILS_PACKAGETYPE_LQFP64
* @arg @ref LL_UTILS_PACKAGETYPE_LQFP100
* @arg @ref LL_UTILS_PACKAGETYPE_WLCSP81
* @arg @ref LL_UTILS_PACKAGETYPE_LQFP128
* @arg @ref LL_UTILS_PACKAGETYPE_UFQFPN32
* @arg @ref LL_UTILS_PACKAGETYPE_LQFP32
* @arg @ref LL_UTILS_PACKAGETYPE_UFQFPN48
* @arg @ref LL_UTILS_PACKAGETYPE_LQFP48
* @arg @ref LL_UTILS_PACKAGETYPE_WLCSP49
* @arg @ref LL_UTILS_PACKAGETYPE_UFBGA64
* @arg @ref LL_UTILS_PACKAGETYPE_UFBGA100
* @arg @ref LL_UTILS_PACKAGETYPE_LQFP48_EBIKE
*
*/
__STATIC_INLINE uint32_t LL_GetPackageType(void)
{
return (uint32_t)(READ_REG(*((uint32_t *)PACKAGE_BASE_ADDRESS)) & 0x1FU);
}
/**
* @}
*/
/** @defgroup UTILS_LL_EF_DELAY DELAY
* @{
*/
/**
* @brief This function configures the Cortex-M SysTick source of the time base.
* @param HCLKFrequency HCLK frequency in Hz (can be calculated thanks to RCC helper macro)
* @note When a RTOS is used, it is recommended to avoid changing the SysTick
* configuration by calling this function, for a delay use rather osDelay RTOS service.
* @param Ticks Frequency of Ticks (Hz)
* @retval None
*/
__STATIC_INLINE void LL_InitTick(uint32_t HCLKFrequency, uint32_t Ticks)
{
/* Configure the SysTick to have interrupt in 1ms time base */
SysTick->LOAD = (uint32_t)((HCLKFrequency / Ticks) - 1UL); /* set reload register */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable the Systick Timer */
}
void LL_Init1msTick(uint32_t HCLKFrequency);
void LL_mDelay(uint32_t Delay);
/**
* @}
*/
/** @defgroup UTILS_EF_SYSTEM SYSTEM
* @{
*/
void LL_SetSystemCoreClock(uint32_t HCLKFrequency);
ErrorStatus LL_SetFlashLatency(uint32_t HCLKFrequency);
ErrorStatus LL_PLL_ConfigSystemClock_HSI(LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct,
LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct);
ErrorStatus LL_PLL_ConfigSystemClock_HSE(uint32_t HSEFrequency, uint32_t HSEBypass,
LL_UTILS_PLLInitTypeDef *UTILS_PLLInitStruct, LL_UTILS_ClkInitTypeDef *UTILS_ClkInitStruct);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_UTILS_H */
| 12,005 | C | 35.271903 | 133 | 0.558684 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_usart.h | /**
******************************************************************************
* @file stm32g4xx_ll_usart.h
* @author MCD Application Team
* @brief Header file of USART LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_USART_H
#define STM32G4xx_LL_USART_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined(USART1) || defined(USART2) || defined(USART3) || defined(UART4) || defined(UART5)
/** @defgroup USART_LL USART
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup USART_LL_Private_Variables USART Private Variables
* @{
*/
/* Array used to get the USART prescaler division decimal values versus @ref USART_LL_EC_PRESCALER values */
static const uint32_t USART_PRESCALER_TAB[] =
{
1UL,
2UL,
4UL,
6UL,
8UL,
10UL,
12UL,
16UL,
32UL,
64UL,
128UL,
256UL
};
/**
* @}
*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup USART_LL_Private_Constants USART Private Constants
* @{
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup USART_LL_Private_Macros USART Private Macros
* @{
*/
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported types ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup USART_LL_ES_INIT USART Exported Init structures
* @{
*/
/**
* @brief LL USART Init Structure definition
*/
typedef struct
{
uint32_t PrescalerValue; /*!< Specifies the Prescaler to compute the communication baud rate.
This parameter can be a value of @ref USART_LL_EC_PRESCALER.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetPrescaler().*/
uint32_t BaudRate; /*!< This field defines expected Usart communication baud rate.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetBaudRate().*/
uint32_t DataWidth; /*!< Specifies the number of data bits transmitted or received in a frame.
This parameter can be a value of @ref USART_LL_EC_DATAWIDTH.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetDataWidth().*/
uint32_t StopBits; /*!< Specifies the number of stop bits transmitted.
This parameter can be a value of @ref USART_LL_EC_STOPBITS.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetStopBitsLength().*/
uint32_t Parity; /*!< Specifies the parity mode.
This parameter can be a value of @ref USART_LL_EC_PARITY.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetParity().*/
uint32_t TransferDirection; /*!< Specifies whether the Receive and/or Transmit mode is enabled or disabled.
This parameter can be a value of @ref USART_LL_EC_DIRECTION.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetTransferDirection().*/
uint32_t HardwareFlowControl; /*!< Specifies whether the hardware flow control mode is enabled or disabled.
This parameter can be a value of @ref USART_LL_EC_HWCONTROL.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetHWFlowCtrl().*/
uint32_t OverSampling; /*!< Specifies whether USART oversampling mode is 16 or 8.
This parameter can be a value of @ref USART_LL_EC_OVERSAMPLING.
This feature can be modified afterwards using unitary
function @ref LL_USART_SetOverSampling().*/
} LL_USART_InitTypeDef;
/**
* @brief LL USART Clock Init Structure definition
*/
typedef struct
{
uint32_t ClockOutput; /*!< Specifies whether the USART clock is enabled or disabled.
This parameter can be a value of @ref USART_LL_EC_CLOCK.
USART HW configuration can be modified afterwards using unitary functions
@ref LL_USART_EnableSCLKOutput() or @ref LL_USART_DisableSCLKOutput().
For more details, refer to description of this function. */
uint32_t ClockPolarity; /*!< Specifies the steady state of the serial clock.
This parameter can be a value of @ref USART_LL_EC_POLARITY.
USART HW configuration can be modified afterwards using unitary
functions @ref LL_USART_SetClockPolarity().
For more details, refer to description of this function. */
uint32_t ClockPhase; /*!< Specifies the clock transition on which the bit capture is made.
This parameter can be a value of @ref USART_LL_EC_PHASE.
USART HW configuration can be modified afterwards using unitary
functions @ref LL_USART_SetClockPhase().
For more details, refer to description of this function. */
uint32_t LastBitClockPulse; /*!< Specifies whether the clock pulse corresponding to the last transmitted
data bit (MSB) has to be output on the SCLK pin in synchronous mode.
This parameter can be a value of @ref USART_LL_EC_LASTCLKPULSE.
USART HW configuration can be modified afterwards using unitary
functions @ref LL_USART_SetLastClkPulseOutput().
For more details, refer to description of this function. */
} LL_USART_ClockInitTypeDef;
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/* Exported constants --------------------------------------------------------*/
/** @defgroup USART_LL_Exported_Constants USART Exported Constants
* @{
*/
/** @defgroup USART_LL_EC_CLEAR_FLAG Clear Flags Defines
* @brief Flags defines which can be used with LL_USART_WriteReg function
* @{
*/
#define LL_USART_ICR_PECF USART_ICR_PECF /*!< Parity error clear flag */
#define LL_USART_ICR_FECF USART_ICR_FECF /*!< Framing error clear flag */
#define LL_USART_ICR_NECF USART_ICR_NECF /*!< Noise error detected clear flag */
#define LL_USART_ICR_ORECF USART_ICR_ORECF /*!< Overrun error clear flag */
#define LL_USART_ICR_IDLECF USART_ICR_IDLECF /*!< Idle line detected clear flag */
#define LL_USART_ICR_TXFECF USART_ICR_TXFECF /*!< TX FIFO Empty clear flag */
#define LL_USART_ICR_TCCF USART_ICR_TCCF /*!< Transmission complete clear flag */
#define LL_USART_ICR_TCBGTCF USART_ICR_TCBGTCF /*!< Transmission completed before guard time clear flag */
#define LL_USART_ICR_LBDCF USART_ICR_LBDCF /*!< LIN break detection clear flag */
#define LL_USART_ICR_CTSCF USART_ICR_CTSCF /*!< CTS clear flag */
#define LL_USART_ICR_RTOCF USART_ICR_RTOCF /*!< Receiver timeout clear flag */
#define LL_USART_ICR_EOBCF USART_ICR_EOBCF /*!< End of block clear flag */
#define LL_USART_ICR_UDRCF USART_ICR_UDRCF /*!< SPI Slave Underrun clear flag */
#define LL_USART_ICR_CMCF USART_ICR_CMCF /*!< Character match clear flag */
#define LL_USART_ICR_WUCF USART_ICR_WUCF /*!< Wakeup from Stop mode clear flag */
/**
* @}
*/
/** @defgroup USART_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_USART_ReadReg function
* @{
*/
#define LL_USART_ISR_PE USART_ISR_PE /*!< Parity error flag */
#define LL_USART_ISR_FE USART_ISR_FE /*!< Framing error flag */
#define LL_USART_ISR_NE USART_ISR_NE /*!< Noise detected flag */
#define LL_USART_ISR_ORE USART_ISR_ORE /*!< Overrun error flag */
#define LL_USART_ISR_IDLE USART_ISR_IDLE /*!< Idle line detected flag */
#define LL_USART_ISR_RXNE_RXFNE USART_ISR_RXNE_RXFNE /*!< Read data register or RX FIFO not empty flag */
#define LL_USART_ISR_TC USART_ISR_TC /*!< Transmission complete flag */
#define LL_USART_ISR_TXE_TXFNF USART_ISR_TXE_TXFNF /*!< Transmit data register empty or TX FIFO Not Full flag*/
#define LL_USART_ISR_LBDF USART_ISR_LBDF /*!< LIN break detection flag */
#define LL_USART_ISR_CTSIF USART_ISR_CTSIF /*!< CTS interrupt flag */
#define LL_USART_ISR_CTS USART_ISR_CTS /*!< CTS flag */
#define LL_USART_ISR_RTOF USART_ISR_RTOF /*!< Receiver timeout flag */
#define LL_USART_ISR_EOBF USART_ISR_EOBF /*!< End of block flag */
#define LL_USART_ISR_UDR USART_ISR_UDR /*!< SPI Slave underrun error flag */
#define LL_USART_ISR_ABRE USART_ISR_ABRE /*!< Auto baud rate error flag */
#define LL_USART_ISR_ABRF USART_ISR_ABRF /*!< Auto baud rate flag */
#define LL_USART_ISR_BUSY USART_ISR_BUSY /*!< Busy flag */
#define LL_USART_ISR_CMF USART_ISR_CMF /*!< Character match flag */
#define LL_USART_ISR_SBKF USART_ISR_SBKF /*!< Send break flag */
#define LL_USART_ISR_RWU USART_ISR_RWU /*!< Receiver wakeup from Mute mode flag */
#define LL_USART_ISR_WUF USART_ISR_WUF /*!< Wakeup from Stop mode flag */
#define LL_USART_ISR_TEACK USART_ISR_TEACK /*!< Transmit enable acknowledge flag */
#define LL_USART_ISR_REACK USART_ISR_REACK /*!< Receive enable acknowledge flag */
#define LL_USART_ISR_TXFE USART_ISR_TXFE /*!< TX FIFO empty flag */
#define LL_USART_ISR_RXFF USART_ISR_RXFF /*!< RX FIFO full flag */
#define LL_USART_ISR_TCBGT USART_ISR_TCBGT /*!< Transmission complete before guard time completion flag */
#define LL_USART_ISR_RXFT USART_ISR_RXFT /*!< RX FIFO threshold flag */
#define LL_USART_ISR_TXFT USART_ISR_TXFT /*!< TX FIFO threshold flag */
/**
* @}
*/
/** @defgroup USART_LL_EC_IT IT Defines
* @brief IT defines which can be used with LL_USART_ReadReg and LL_USART_WriteReg functions
* @{
*/
#define LL_USART_CR1_IDLEIE USART_CR1_IDLEIE /*!< IDLE interrupt enable */
#define LL_USART_CR1_RXNEIE_RXFNEIE USART_CR1_RXNEIE_RXFNEIE /*!< Read data register and RXFIFO not empty interrupt enable */
#define LL_USART_CR1_TCIE USART_CR1_TCIE /*!< Transmission complete interrupt enable */
#define LL_USART_CR1_TXEIE_TXFNFIE USART_CR1_TXEIE_TXFNFIE /*!< Transmit data register empty and TX FIFO not full interrupt enable */
#define LL_USART_CR1_PEIE USART_CR1_PEIE /*!< Parity error */
#define LL_USART_CR1_CMIE USART_CR1_CMIE /*!< Character match interrupt enable */
#define LL_USART_CR1_RTOIE USART_CR1_RTOIE /*!< Receiver timeout interrupt enable */
#define LL_USART_CR1_EOBIE USART_CR1_EOBIE /*!< End of Block interrupt enable */
#define LL_USART_CR1_TXFEIE USART_CR1_TXFEIE /*!< TX FIFO empty interrupt enable */
#define LL_USART_CR1_RXFFIE USART_CR1_RXFFIE /*!< RX FIFO full interrupt enable */
#define LL_USART_CR2_LBDIE USART_CR2_LBDIE /*!< LIN break detection interrupt enable */
#define LL_USART_CR3_EIE USART_CR3_EIE /*!< Error interrupt enable */
#define LL_USART_CR3_CTSIE USART_CR3_CTSIE /*!< CTS interrupt enable */
#define LL_USART_CR3_WUFIE USART_CR3_WUFIE /*!< Wakeup from Stop mode interrupt enable */
#define LL_USART_CR3_TXFTIE USART_CR3_TXFTIE /*!< TX FIFO threshold interrupt enable */
#define LL_USART_CR3_TCBGTIE USART_CR3_TCBGTIE /*!< Transmission complete before guard time interrupt enable */
#define LL_USART_CR3_RXFTIE USART_CR3_RXFTIE /*!< RX FIFO threshold interrupt enable */
/**
* @}
*/
/** @defgroup USART_LL_EC_FIFOTHRESHOLD FIFO Threshold
* @{
*/
#define LL_USART_FIFOTHRESHOLD_1_8 0x00000000U /*!< FIFO reaches 1/8 of its depth */
#define LL_USART_FIFOTHRESHOLD_1_4 0x00000001U /*!< FIFO reaches 1/4 of its depth */
#define LL_USART_FIFOTHRESHOLD_1_2 0x00000002U /*!< FIFO reaches 1/2 of its depth */
#define LL_USART_FIFOTHRESHOLD_3_4 0x00000003U /*!< FIFO reaches 3/4 of its depth */
#define LL_USART_FIFOTHRESHOLD_7_8 0x00000004U /*!< FIFO reaches 7/8 of its depth */
#define LL_USART_FIFOTHRESHOLD_8_8 0x00000005U /*!< FIFO becomes empty for TX and full for RX */
/**
* @}
*/
/** @defgroup USART_LL_EC_DIRECTION Communication Direction
* @{
*/
#define LL_USART_DIRECTION_NONE 0x00000000U /*!< Transmitter and Receiver are disabled */
#define LL_USART_DIRECTION_RX USART_CR1_RE /*!< Transmitter is disabled and Receiver is enabled */
#define LL_USART_DIRECTION_TX USART_CR1_TE /*!< Transmitter is enabled and Receiver is disabled */
#define LL_USART_DIRECTION_TX_RX (USART_CR1_TE |USART_CR1_RE) /*!< Transmitter and Receiver are enabled */
/**
* @}
*/
/** @defgroup USART_LL_EC_PARITY Parity Control
* @{
*/
#define LL_USART_PARITY_NONE 0x00000000U /*!< Parity control disabled */
#define LL_USART_PARITY_EVEN USART_CR1_PCE /*!< Parity control enabled and Even Parity is selected */
#define LL_USART_PARITY_ODD (USART_CR1_PCE | USART_CR1_PS) /*!< Parity control enabled and Odd Parity is selected */
/**
* @}
*/
/** @defgroup USART_LL_EC_WAKEUP Wakeup
* @{
*/
#define LL_USART_WAKEUP_IDLELINE 0x00000000U /*!< USART wake up from Mute mode on Idle Line */
#define LL_USART_WAKEUP_ADDRESSMARK USART_CR1_WAKE /*!< USART wake up from Mute mode on Address Mark */
/**
* @}
*/
/** @defgroup USART_LL_EC_DATAWIDTH Datawidth
* @{
*/
#define LL_USART_DATAWIDTH_7B USART_CR1_M1 /*!< 7 bits word length : Start bit, 7 data bits, n stop bits */
#define LL_USART_DATAWIDTH_8B 0x00000000U /*!< 8 bits word length : Start bit, 8 data bits, n stop bits */
#define LL_USART_DATAWIDTH_9B USART_CR1_M0 /*!< 9 bits word length : Start bit, 9 data bits, n stop bits */
/**
* @}
*/
/** @defgroup USART_LL_EC_OVERSAMPLING Oversampling
* @{
*/
#define LL_USART_OVERSAMPLING_16 0x00000000U /*!< Oversampling by 16 */
#define LL_USART_OVERSAMPLING_8 USART_CR1_OVER8 /*!< Oversampling by 8 */
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup USART_LL_EC_CLOCK Clock Signal
* @{
*/
#define LL_USART_CLOCK_DISABLE 0x00000000U /*!< Clock signal not provided */
#define LL_USART_CLOCK_ENABLE USART_CR2_CLKEN /*!< Clock signal provided */
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/** @defgroup USART_LL_EC_LASTCLKPULSE Last Clock Pulse
* @{
*/
#define LL_USART_LASTCLKPULSE_NO_OUTPUT 0x00000000U /*!< The clock pulse of the last data bit is not output to the SCLK pin */
#define LL_USART_LASTCLKPULSE_OUTPUT USART_CR2_LBCL /*!< The clock pulse of the last data bit is output to the SCLK pin */
/**
* @}
*/
/** @defgroup USART_LL_EC_PHASE Clock Phase
* @{
*/
#define LL_USART_PHASE_1EDGE 0x00000000U /*!< The first clock transition is the first data capture edge */
#define LL_USART_PHASE_2EDGE USART_CR2_CPHA /*!< The second clock transition is the first data capture edge */
/**
* @}
*/
/** @defgroup USART_LL_EC_POLARITY Clock Polarity
* @{
*/
#define LL_USART_POLARITY_LOW 0x00000000U /*!< Steady low value on SCLK pin outside transmission window*/
#define LL_USART_POLARITY_HIGH USART_CR2_CPOL /*!< Steady high value on SCLK pin outside transmission window */
/**
* @}
*/
/** @defgroup USART_LL_EC_PRESCALER Clock Source Prescaler
* @{
*/
#define LL_USART_PRESCALER_DIV1 0x00000000U /*!< Input clock not divided */
#define LL_USART_PRESCALER_DIV2 (USART_PRESC_PRESCALER_0) /*!< Input clock divided by 2 */
#define LL_USART_PRESCALER_DIV4 (USART_PRESC_PRESCALER_1) /*!< Input clock divided by 4 */
#define LL_USART_PRESCALER_DIV6 (USART_PRESC_PRESCALER_1 | USART_PRESC_PRESCALER_0) /*!< Input clock divided by 6 */
#define LL_USART_PRESCALER_DIV8 (USART_PRESC_PRESCALER_2) /*!< Input clock divided by 8 */
#define LL_USART_PRESCALER_DIV10 (USART_PRESC_PRESCALER_2 | USART_PRESC_PRESCALER_0) /*!< Input clock divided by 10 */
#define LL_USART_PRESCALER_DIV12 (USART_PRESC_PRESCALER_2 | USART_PRESC_PRESCALER_1) /*!< Input clock divided by 12 */
#define LL_USART_PRESCALER_DIV16 (USART_PRESC_PRESCALER_2 | USART_PRESC_PRESCALER_1 | USART_PRESC_PRESCALER_0) /*!< Input clock divided by 16 */
#define LL_USART_PRESCALER_DIV32 (USART_PRESC_PRESCALER_3) /*!< Input clock divided by 32 */
#define LL_USART_PRESCALER_DIV64 (USART_PRESC_PRESCALER_3 | USART_PRESC_PRESCALER_0) /*!< Input clock divided by 64 */
#define LL_USART_PRESCALER_DIV128 (USART_PRESC_PRESCALER_3 | USART_PRESC_PRESCALER_1) /*!< Input clock divided by 128 */
#define LL_USART_PRESCALER_DIV256 (USART_PRESC_PRESCALER_3 | USART_PRESC_PRESCALER_1 | USART_PRESC_PRESCALER_0) /*!< Input clock divided by 256 */
/**
* @}
*/
/** @defgroup USART_LL_EC_STOPBITS Stop Bits
* @{
*/
#define LL_USART_STOPBITS_0_5 USART_CR2_STOP_0 /*!< 0.5 stop bit */
#define LL_USART_STOPBITS_1 0x00000000U /*!< 1 stop bit */
#define LL_USART_STOPBITS_1_5 (USART_CR2_STOP_0 | USART_CR2_STOP_1) /*!< 1.5 stop bits */
#define LL_USART_STOPBITS_2 USART_CR2_STOP_1 /*!< 2 stop bits */
/**
* @}
*/
/** @defgroup USART_LL_EC_TXRX TX RX Pins Swap
* @{
*/
#define LL_USART_TXRX_STANDARD 0x00000000U /*!< TX/RX pins are used as defined in standard pinout */
#define LL_USART_TXRX_SWAPPED (USART_CR2_SWAP) /*!< TX and RX pins functions are swapped. */
/**
* @}
*/
/** @defgroup USART_LL_EC_RXPIN_LEVEL RX Pin Active Level Inversion
* @{
*/
#define LL_USART_RXPIN_LEVEL_STANDARD 0x00000000U /*!< RX pin signal works using the standard logic levels */
#define LL_USART_RXPIN_LEVEL_INVERTED (USART_CR2_RXINV) /*!< RX pin signal values are inverted. */
/**
* @}
*/
/** @defgroup USART_LL_EC_TXPIN_LEVEL TX Pin Active Level Inversion
* @{
*/
#define LL_USART_TXPIN_LEVEL_STANDARD 0x00000000U /*!< TX pin signal works using the standard logic levels */
#define LL_USART_TXPIN_LEVEL_INVERTED (USART_CR2_TXINV) /*!< TX pin signal values are inverted. */
/**
* @}
*/
/** @defgroup USART_LL_EC_BINARY_LOGIC Binary Data Inversion
* @{
*/
#define LL_USART_BINARY_LOGIC_POSITIVE 0x00000000U /*!< Logical data from the data register are send/received in positive/direct logic. (1=H, 0=L) */
#define LL_USART_BINARY_LOGIC_NEGATIVE USART_CR2_DATAINV /*!< Logical data from the data register are send/received in negative/inverse logic. (1=L, 0=H). The parity bit is also inverted. */
/**
* @}
*/
/** @defgroup USART_LL_EC_BITORDER Bit Order
* @{
*/
#define LL_USART_BITORDER_LSBFIRST 0x00000000U /*!< data is transmitted/received with data bit 0 first, following the start bit */
#define LL_USART_BITORDER_MSBFIRST USART_CR2_MSBFIRST /*!< data is transmitted/received with the MSB first, following the start bit */
/**
* @}
*/
/** @defgroup USART_LL_EC_AUTOBAUD_DETECT_ON Autobaud Detection
* @{
*/
#define LL_USART_AUTOBAUD_DETECT_ON_STARTBIT 0x00000000U /*!< Measurement of the start bit is used to detect the baud rate */
#define LL_USART_AUTOBAUD_DETECT_ON_FALLINGEDGE USART_CR2_ABRMODE_0 /*!< Falling edge to falling edge measurement. Received frame must start with a single bit = 1 -> Frame = Start10xxxxxx */
#define LL_USART_AUTOBAUD_DETECT_ON_7F_FRAME USART_CR2_ABRMODE_1 /*!< 0x7F frame detection */
#define LL_USART_AUTOBAUD_DETECT_ON_55_FRAME (USART_CR2_ABRMODE_1 | USART_CR2_ABRMODE_0) /*!< 0x55 frame detection */
/**
* @}
*/
/** @defgroup USART_LL_EC_ADDRESS_DETECT Address Length Detection
* @{
*/
#define LL_USART_ADDRESS_DETECT_4B 0x00000000U /*!< 4-bit address detection method selected */
#define LL_USART_ADDRESS_DETECT_7B USART_CR2_ADDM7 /*!< 7-bit address detection (in 8-bit data mode) method selected */
/**
* @}
*/
/** @defgroup USART_LL_EC_HWCONTROL Hardware Control
* @{
*/
#define LL_USART_HWCONTROL_NONE 0x00000000U /*!< CTS and RTS hardware flow control disabled */
#define LL_USART_HWCONTROL_RTS USART_CR3_RTSE /*!< RTS output enabled, data is only requested when there is space in the receive buffer */
#define LL_USART_HWCONTROL_CTS USART_CR3_CTSE /*!< CTS mode enabled, data is only transmitted when the nCTS input is asserted (tied to 0) */
#define LL_USART_HWCONTROL_RTS_CTS (USART_CR3_RTSE | USART_CR3_CTSE) /*!< CTS and RTS hardware flow control enabled */
/**
* @}
*/
/** @defgroup USART_LL_EC_WAKEUP_ON Wakeup Activation
* @{
*/
#define LL_USART_WAKEUP_ON_ADDRESS 0x00000000U /*!< Wake up active on address match */
#define LL_USART_WAKEUP_ON_STARTBIT USART_CR3_WUS_1 /*!< Wake up active on Start bit detection */
#define LL_USART_WAKEUP_ON_RXNE (USART_CR3_WUS_0 | USART_CR3_WUS_1) /*!< Wake up active on RXNE */
/**
* @}
*/
/** @defgroup USART_LL_EC_IRDA_POWER IrDA Power
* @{
*/
#define LL_USART_IRDA_POWER_NORMAL 0x00000000U /*!< IrDA normal power mode */
#define LL_USART_IRDA_POWER_LOW USART_CR3_IRLP /*!< IrDA low power mode */
/**
* @}
*/
/** @defgroup USART_LL_EC_LINBREAK_DETECT LIN Break Detection Length
* @{
*/
#define LL_USART_LINBREAK_DETECT_10B 0x00000000U /*!< 10-bit break detection method selected */
#define LL_USART_LINBREAK_DETECT_11B USART_CR2_LBDL /*!< 11-bit break detection method selected */
/**
* @}
*/
/** @defgroup USART_LL_EC_DE_POLARITY Driver Enable Polarity
* @{
*/
#define LL_USART_DE_POLARITY_HIGH 0x00000000U /*!< DE signal is active high */
#define LL_USART_DE_POLARITY_LOW USART_CR3_DEP /*!< DE signal is active low */
/**
* @}
*/
/** @defgroup USART_LL_EC_DMA_REG_DATA DMA Register Data
* @{
*/
#define LL_USART_DMA_REG_DATA_TRANSMIT 0x00000000U /*!< Get address of data register used for transmission */
#define LL_USART_DMA_REG_DATA_RECEIVE 0x00000001U /*!< Get address of data register used for reception */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup USART_LL_Exported_Macros USART Exported Macros
* @{
*/
/** @defgroup USART_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in USART register
* @param __INSTANCE__ USART Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_USART_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG(__INSTANCE__->__REG__, (__VALUE__))
/**
* @brief Read a value in USART register
* @param __INSTANCE__ USART Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_USART_ReadReg(__INSTANCE__, __REG__) READ_REG(__INSTANCE__->__REG__)
/**
* @}
*/
/** @defgroup USART_LL_EM_Exported_Macros_Helper Exported_Macros_Helper
* @{
*/
/**
* @brief Compute USARTDIV value according to Peripheral Clock and
* expected Baud Rate in 8 bits sampling mode (32 bits value of USARTDIV is returned)
* @param __PERIPHCLK__ Peripheral Clock frequency used for USART instance
* @param __PRESCALER__ This parameter can be one of the following values:
* @arg @ref LL_USART_PRESCALER_DIV1
* @arg @ref LL_USART_PRESCALER_DIV2
* @arg @ref LL_USART_PRESCALER_DIV4
* @arg @ref LL_USART_PRESCALER_DIV6
* @arg @ref LL_USART_PRESCALER_DIV8
* @arg @ref LL_USART_PRESCALER_DIV10
* @arg @ref LL_USART_PRESCALER_DIV12
* @arg @ref LL_USART_PRESCALER_DIV16
* @arg @ref LL_USART_PRESCALER_DIV32
* @arg @ref LL_USART_PRESCALER_DIV64
* @arg @ref LL_USART_PRESCALER_DIV128
* @arg @ref LL_USART_PRESCALER_DIV256
* @param __BAUDRATE__ Baud rate value to achieve
* @retval USARTDIV value to be used for BRR register filling in OverSampling_8 case
*/
#define __LL_USART_DIV_SAMPLING8(__PERIPHCLK__, __PRESCALER__, __BAUDRATE__) \
(((((__PERIPHCLK__)/(USART_PRESCALER_TAB[(__PRESCALER__)]))*2U)\
+ ((__BAUDRATE__)/2U))/(__BAUDRATE__))
/**
* @brief Compute USARTDIV value according to Peripheral Clock and
* expected Baud Rate in 16 bits sampling mode (32 bits value of USARTDIV is returned)
* @param __PERIPHCLK__ Peripheral Clock frequency used for USART instance
* @param __PRESCALER__ This parameter can be one of the following values:
* @arg @ref LL_USART_PRESCALER_DIV1
* @arg @ref LL_USART_PRESCALER_DIV2
* @arg @ref LL_USART_PRESCALER_DIV4
* @arg @ref LL_USART_PRESCALER_DIV6
* @arg @ref LL_USART_PRESCALER_DIV8
* @arg @ref LL_USART_PRESCALER_DIV10
* @arg @ref LL_USART_PRESCALER_DIV12
* @arg @ref LL_USART_PRESCALER_DIV16
* @arg @ref LL_USART_PRESCALER_DIV32
* @arg @ref LL_USART_PRESCALER_DIV64
* @arg @ref LL_USART_PRESCALER_DIV128
* @arg @ref LL_USART_PRESCALER_DIV256
* @param __BAUDRATE__ Baud rate value to achieve
* @retval USARTDIV value to be used for BRR register filling in OverSampling_16 case
*/
#define __LL_USART_DIV_SAMPLING16(__PERIPHCLK__, __PRESCALER__, __BAUDRATE__) \
((((__PERIPHCLK__)/(USART_PRESCALER_TAB[(__PRESCALER__)]))\
+ ((__BAUDRATE__)/2U))/(__BAUDRATE__))
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup USART_LL_Exported_Functions USART Exported Functions
* @{
*/
/** @defgroup USART_LL_EF_Configuration Configuration functions
* @{
*/
/**
* @brief USART Enable
* @rmtoll CR1 UE LL_USART_Enable
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_Enable(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR1, USART_CR1_UE);
}
/**
* @brief USART Disable (all USART prescalers and outputs are disabled)
* @note When USART is disabled, USART prescalers and outputs are stopped immediately,
* and current operations are discarded. The configuration of the USART is kept, but all the status
* flags, in the USARTx_ISR are set to their default values.
* @rmtoll CR1 UE LL_USART_Disable
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_Disable(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR1, USART_CR1_UE);
}
/**
* @brief Indicate if USART is enabled
* @rmtoll CR1 UE LL_USART_IsEnabled
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabled(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_UE) == (USART_CR1_UE)) ? 1UL : 0UL);
}
/**
* @brief FIFO Mode Enable
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 FIFOEN LL_USART_EnableFIFO
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableFIFO(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR1, USART_CR1_FIFOEN);
}
/**
* @brief FIFO Mode Disable
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 FIFOEN LL_USART_DisableFIFO
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableFIFO(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR1, USART_CR1_FIFOEN);
}
/**
* @brief Indicate if FIFO Mode is enabled
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 FIFOEN LL_USART_IsEnabledFIFO
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledFIFO(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_FIFOEN) == (USART_CR1_FIFOEN)) ? 1UL : 0UL);
}
/**
* @brief Configure TX FIFO Threshold
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 TXFTCFG LL_USART_SetTXFIFOThreshold
* @param USARTx USART Instance
* @param Threshold This parameter can be one of the following values:
* @arg @ref LL_USART_FIFOTHRESHOLD_1_8
* @arg @ref LL_USART_FIFOTHRESHOLD_1_4
* @arg @ref LL_USART_FIFOTHRESHOLD_1_2
* @arg @ref LL_USART_FIFOTHRESHOLD_3_4
* @arg @ref LL_USART_FIFOTHRESHOLD_7_8
* @arg @ref LL_USART_FIFOTHRESHOLD_8_8
* @retval None
*/
__STATIC_INLINE void LL_USART_SetTXFIFOThreshold(USART_TypeDef *USARTx, uint32_t Threshold)
{
ATOMIC_MODIFY_REG(USARTx->CR3, USART_CR3_TXFTCFG, Threshold << USART_CR3_TXFTCFG_Pos);
}
/**
* @brief Return TX FIFO Threshold Configuration
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 TXFTCFG LL_USART_GetTXFIFOThreshold
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_FIFOTHRESHOLD_1_8
* @arg @ref LL_USART_FIFOTHRESHOLD_1_4
* @arg @ref LL_USART_FIFOTHRESHOLD_1_2
* @arg @ref LL_USART_FIFOTHRESHOLD_3_4
* @arg @ref LL_USART_FIFOTHRESHOLD_7_8
* @arg @ref LL_USART_FIFOTHRESHOLD_8_8
*/
__STATIC_INLINE uint32_t LL_USART_GetTXFIFOThreshold(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR3, USART_CR3_TXFTCFG) >> USART_CR3_TXFTCFG_Pos);
}
/**
* @brief Configure RX FIFO Threshold
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 RXFTCFG LL_USART_SetRXFIFOThreshold
* @param USARTx USART Instance
* @param Threshold This parameter can be one of the following values:
* @arg @ref LL_USART_FIFOTHRESHOLD_1_8
* @arg @ref LL_USART_FIFOTHRESHOLD_1_4
* @arg @ref LL_USART_FIFOTHRESHOLD_1_2
* @arg @ref LL_USART_FIFOTHRESHOLD_3_4
* @arg @ref LL_USART_FIFOTHRESHOLD_7_8
* @arg @ref LL_USART_FIFOTHRESHOLD_8_8
* @retval None
*/
__STATIC_INLINE void LL_USART_SetRXFIFOThreshold(USART_TypeDef *USARTx, uint32_t Threshold)
{
ATOMIC_MODIFY_REG(USARTx->CR3, USART_CR3_RXFTCFG, Threshold << USART_CR3_RXFTCFG_Pos);
}
/**
* @brief Return RX FIFO Threshold Configuration
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 RXFTCFG LL_USART_GetRXFIFOThreshold
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_FIFOTHRESHOLD_1_8
* @arg @ref LL_USART_FIFOTHRESHOLD_1_4
* @arg @ref LL_USART_FIFOTHRESHOLD_1_2
* @arg @ref LL_USART_FIFOTHRESHOLD_3_4
* @arg @ref LL_USART_FIFOTHRESHOLD_7_8
* @arg @ref LL_USART_FIFOTHRESHOLD_8_8
*/
__STATIC_INLINE uint32_t LL_USART_GetRXFIFOThreshold(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR3, USART_CR3_RXFTCFG) >> USART_CR3_RXFTCFG_Pos);
}
/**
* @brief Configure TX and RX FIFOs Threshold
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 TXFTCFG LL_USART_ConfigFIFOsThreshold\n
* CR3 RXFTCFG LL_USART_ConfigFIFOsThreshold
* @param USARTx USART Instance
* @param TXThreshold This parameter can be one of the following values:
* @arg @ref LL_USART_FIFOTHRESHOLD_1_8
* @arg @ref LL_USART_FIFOTHRESHOLD_1_4
* @arg @ref LL_USART_FIFOTHRESHOLD_1_2
* @arg @ref LL_USART_FIFOTHRESHOLD_3_4
* @arg @ref LL_USART_FIFOTHRESHOLD_7_8
* @arg @ref LL_USART_FIFOTHRESHOLD_8_8
* @param RXThreshold This parameter can be one of the following values:
* @arg @ref LL_USART_FIFOTHRESHOLD_1_8
* @arg @ref LL_USART_FIFOTHRESHOLD_1_4
* @arg @ref LL_USART_FIFOTHRESHOLD_1_2
* @arg @ref LL_USART_FIFOTHRESHOLD_3_4
* @arg @ref LL_USART_FIFOTHRESHOLD_7_8
* @arg @ref LL_USART_FIFOTHRESHOLD_8_8
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigFIFOsThreshold(USART_TypeDef *USARTx, uint32_t TXThreshold, uint32_t RXThreshold)
{
ATOMIC_MODIFY_REG(USARTx->CR3, USART_CR3_TXFTCFG | USART_CR3_RXFTCFG, (TXThreshold << USART_CR3_TXFTCFG_Pos) |
(RXThreshold << USART_CR3_RXFTCFG_Pos));
}
/**
* @brief USART enabled in STOP Mode.
* @note When this function is enabled, USART is able to wake up the MCU from Stop mode, provided that
* USART clock selection is HSI or LSE in RCC.
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR1 UESM LL_USART_EnableInStopMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableInStopMode(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_UESM);
}
/**
* @brief USART disabled in STOP Mode.
* @note When this function is disabled, USART is not able to wake up the MCU from Stop mode
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR1 UESM LL_USART_DisableInStopMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableInStopMode(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_UESM);
}
/**
* @brief Indicate if USART is enabled in STOP Mode (able to wake up MCU from Stop mode or not)
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR1 UESM LL_USART_IsEnabledInStopMode
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledInStopMode(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_UESM) == (USART_CR1_UESM)) ? 1UL : 0UL);
}
/**
* @brief Receiver Enable (Receiver is enabled and begins searching for a start bit)
* @rmtoll CR1 RE LL_USART_EnableDirectionRx
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableDirectionRx(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_RE);
}
/**
* @brief Receiver Disable
* @rmtoll CR1 RE LL_USART_DisableDirectionRx
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableDirectionRx(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_RE);
}
/**
* @brief Transmitter Enable
* @rmtoll CR1 TE LL_USART_EnableDirectionTx
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableDirectionTx(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_TE);
}
/**
* @brief Transmitter Disable
* @rmtoll CR1 TE LL_USART_DisableDirectionTx
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableDirectionTx(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_TE);
}
/**
* @brief Configure simultaneously enabled/disabled states
* of Transmitter and Receiver
* @rmtoll CR1 RE LL_USART_SetTransferDirection\n
* CR1 TE LL_USART_SetTransferDirection
* @param USARTx USART Instance
* @param TransferDirection This parameter can be one of the following values:
* @arg @ref LL_USART_DIRECTION_NONE
* @arg @ref LL_USART_DIRECTION_RX
* @arg @ref LL_USART_DIRECTION_TX
* @arg @ref LL_USART_DIRECTION_TX_RX
* @retval None
*/
__STATIC_INLINE void LL_USART_SetTransferDirection(USART_TypeDef *USARTx, uint32_t TransferDirection)
{
ATOMIC_MODIFY_REG(USARTx->CR1, USART_CR1_RE | USART_CR1_TE, TransferDirection);
}
/**
* @brief Return enabled/disabled states of Transmitter and Receiver
* @rmtoll CR1 RE LL_USART_GetTransferDirection\n
* CR1 TE LL_USART_GetTransferDirection
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_DIRECTION_NONE
* @arg @ref LL_USART_DIRECTION_RX
* @arg @ref LL_USART_DIRECTION_TX
* @arg @ref LL_USART_DIRECTION_TX_RX
*/
__STATIC_INLINE uint32_t LL_USART_GetTransferDirection(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR1, USART_CR1_RE | USART_CR1_TE));
}
/**
* @brief Configure Parity (enabled/disabled and parity mode if enabled).
* @note This function selects if hardware parity control (generation and detection) is enabled or disabled.
* When the parity control is enabled (Odd or Even), computed parity bit is inserted at the MSB position
* (9th or 8th bit depending on data width) and parity is checked on the received data.
* @rmtoll CR1 PS LL_USART_SetParity\n
* CR1 PCE LL_USART_SetParity
* @param USARTx USART Instance
* @param Parity This parameter can be one of the following values:
* @arg @ref LL_USART_PARITY_NONE
* @arg @ref LL_USART_PARITY_EVEN
* @arg @ref LL_USART_PARITY_ODD
* @retval None
*/
__STATIC_INLINE void LL_USART_SetParity(USART_TypeDef *USARTx, uint32_t Parity)
{
MODIFY_REG(USARTx->CR1, USART_CR1_PS | USART_CR1_PCE, Parity);
}
/**
* @brief Return Parity configuration (enabled/disabled and parity mode if enabled)
* @rmtoll CR1 PS LL_USART_GetParity\n
* CR1 PCE LL_USART_GetParity
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_PARITY_NONE
* @arg @ref LL_USART_PARITY_EVEN
* @arg @ref LL_USART_PARITY_ODD
*/
__STATIC_INLINE uint32_t LL_USART_GetParity(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR1, USART_CR1_PS | USART_CR1_PCE));
}
/**
* @brief Set Receiver Wake Up method from Mute mode.
* @rmtoll CR1 WAKE LL_USART_SetWakeUpMethod
* @param USARTx USART Instance
* @param Method This parameter can be one of the following values:
* @arg @ref LL_USART_WAKEUP_IDLELINE
* @arg @ref LL_USART_WAKEUP_ADDRESSMARK
* @retval None
*/
__STATIC_INLINE void LL_USART_SetWakeUpMethod(USART_TypeDef *USARTx, uint32_t Method)
{
MODIFY_REG(USARTx->CR1, USART_CR1_WAKE, Method);
}
/**
* @brief Return Receiver Wake Up method from Mute mode
* @rmtoll CR1 WAKE LL_USART_GetWakeUpMethod
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_WAKEUP_IDLELINE
* @arg @ref LL_USART_WAKEUP_ADDRESSMARK
*/
__STATIC_INLINE uint32_t LL_USART_GetWakeUpMethod(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR1, USART_CR1_WAKE));
}
/**
* @brief Set Word length (i.e. nb of data bits, excluding start and stop bits)
* @rmtoll CR1 M0 LL_USART_SetDataWidth\n
* CR1 M1 LL_USART_SetDataWidth
* @param USARTx USART Instance
* @param DataWidth This parameter can be one of the following values:
* @arg @ref LL_USART_DATAWIDTH_7B
* @arg @ref LL_USART_DATAWIDTH_8B
* @arg @ref LL_USART_DATAWIDTH_9B
* @retval None
*/
__STATIC_INLINE void LL_USART_SetDataWidth(USART_TypeDef *USARTx, uint32_t DataWidth)
{
MODIFY_REG(USARTx->CR1, USART_CR1_M, DataWidth);
}
/**
* @brief Return Word length (i.e. nb of data bits, excluding start and stop bits)
* @rmtoll CR1 M0 LL_USART_GetDataWidth\n
* CR1 M1 LL_USART_GetDataWidth
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_DATAWIDTH_7B
* @arg @ref LL_USART_DATAWIDTH_8B
* @arg @ref LL_USART_DATAWIDTH_9B
*/
__STATIC_INLINE uint32_t LL_USART_GetDataWidth(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR1, USART_CR1_M));
}
/**
* @brief Allow switch between Mute Mode and Active mode
* @rmtoll CR1 MME LL_USART_EnableMuteMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableMuteMode(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_MME);
}
/**
* @brief Prevent Mute Mode use. Set Receiver in active mode permanently.
* @rmtoll CR1 MME LL_USART_DisableMuteMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableMuteMode(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_MME);
}
/**
* @brief Indicate if switch between Mute Mode and Active mode is allowed
* @rmtoll CR1 MME LL_USART_IsEnabledMuteMode
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledMuteMode(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_MME) == (USART_CR1_MME)) ? 1UL : 0UL);
}
/**
* @brief Set Oversampling to 8-bit or 16-bit mode
* @rmtoll CR1 OVER8 LL_USART_SetOverSampling
* @param USARTx USART Instance
* @param OverSampling This parameter can be one of the following values:
* @arg @ref LL_USART_OVERSAMPLING_16
* @arg @ref LL_USART_OVERSAMPLING_8
* @retval None
*/
__STATIC_INLINE void LL_USART_SetOverSampling(USART_TypeDef *USARTx, uint32_t OverSampling)
{
MODIFY_REG(USARTx->CR1, USART_CR1_OVER8, OverSampling);
}
/**
* @brief Return Oversampling mode
* @rmtoll CR1 OVER8 LL_USART_GetOverSampling
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_OVERSAMPLING_16
* @arg @ref LL_USART_OVERSAMPLING_8
*/
__STATIC_INLINE uint32_t LL_USART_GetOverSampling(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR1, USART_CR1_OVER8));
}
/**
* @brief Configure if Clock pulse of the last data bit is output to the SCLK pin or not
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 LBCL LL_USART_SetLastClkPulseOutput
* @param USARTx USART Instance
* @param LastBitClockPulse This parameter can be one of the following values:
* @arg @ref LL_USART_LASTCLKPULSE_NO_OUTPUT
* @arg @ref LL_USART_LASTCLKPULSE_OUTPUT
* @retval None
*/
__STATIC_INLINE void LL_USART_SetLastClkPulseOutput(USART_TypeDef *USARTx, uint32_t LastBitClockPulse)
{
MODIFY_REG(USARTx->CR2, USART_CR2_LBCL, LastBitClockPulse);
}
/**
* @brief Retrieve Clock pulse of the last data bit output configuration
* (Last bit Clock pulse output to the SCLK pin or not)
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 LBCL LL_USART_GetLastClkPulseOutput
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_LASTCLKPULSE_NO_OUTPUT
* @arg @ref LL_USART_LASTCLKPULSE_OUTPUT
*/
__STATIC_INLINE uint32_t LL_USART_GetLastClkPulseOutput(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_LBCL));
}
/**
* @brief Select the phase of the clock output on the SCLK pin in synchronous mode
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 CPHA LL_USART_SetClockPhase
* @param USARTx USART Instance
* @param ClockPhase This parameter can be one of the following values:
* @arg @ref LL_USART_PHASE_1EDGE
* @arg @ref LL_USART_PHASE_2EDGE
* @retval None
*/
__STATIC_INLINE void LL_USART_SetClockPhase(USART_TypeDef *USARTx, uint32_t ClockPhase)
{
MODIFY_REG(USARTx->CR2, USART_CR2_CPHA, ClockPhase);
}
/**
* @brief Return phase of the clock output on the SCLK pin in synchronous mode
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 CPHA LL_USART_GetClockPhase
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_PHASE_1EDGE
* @arg @ref LL_USART_PHASE_2EDGE
*/
__STATIC_INLINE uint32_t LL_USART_GetClockPhase(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_CPHA));
}
/**
* @brief Select the polarity of the clock output on the SCLK pin in synchronous mode
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 CPOL LL_USART_SetClockPolarity
* @param USARTx USART Instance
* @param ClockPolarity This parameter can be one of the following values:
* @arg @ref LL_USART_POLARITY_LOW
* @arg @ref LL_USART_POLARITY_HIGH
* @retval None
*/
__STATIC_INLINE void LL_USART_SetClockPolarity(USART_TypeDef *USARTx, uint32_t ClockPolarity)
{
MODIFY_REG(USARTx->CR2, USART_CR2_CPOL, ClockPolarity);
}
/**
* @brief Return polarity of the clock output on the SCLK pin in synchronous mode
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 CPOL LL_USART_GetClockPolarity
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_POLARITY_LOW
* @arg @ref LL_USART_POLARITY_HIGH
*/
__STATIC_INLINE uint32_t LL_USART_GetClockPolarity(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_CPOL));
}
/**
* @brief Configure Clock signal format (Phase Polarity and choice about output of last bit clock pulse)
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @note Call of this function is equivalent to following function call sequence :
* - Clock Phase configuration using @ref LL_USART_SetClockPhase() function
* - Clock Polarity configuration using @ref LL_USART_SetClockPolarity() function
* - Output of Last bit Clock pulse configuration using @ref LL_USART_SetLastClkPulseOutput() function
* @rmtoll CR2 CPHA LL_USART_ConfigClock\n
* CR2 CPOL LL_USART_ConfigClock\n
* CR2 LBCL LL_USART_ConfigClock
* @param USARTx USART Instance
* @param Phase This parameter can be one of the following values:
* @arg @ref LL_USART_PHASE_1EDGE
* @arg @ref LL_USART_PHASE_2EDGE
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_USART_POLARITY_LOW
* @arg @ref LL_USART_POLARITY_HIGH
* @param LBCPOutput This parameter can be one of the following values:
* @arg @ref LL_USART_LASTCLKPULSE_NO_OUTPUT
* @arg @ref LL_USART_LASTCLKPULSE_OUTPUT
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigClock(USART_TypeDef *USARTx, uint32_t Phase, uint32_t Polarity, uint32_t LBCPOutput)
{
MODIFY_REG(USARTx->CR2, USART_CR2_CPHA | USART_CR2_CPOL | USART_CR2_LBCL, Phase | Polarity | LBCPOutput);
}
/**
* @brief Configure Clock source prescaler for baudrate generator and oversampling
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll PRESC PRESCALER LL_USART_SetPrescaler
* @param USARTx USART Instance
* @param PrescalerValue This parameter can be one of the following values:
* @arg @ref LL_USART_PRESCALER_DIV1
* @arg @ref LL_USART_PRESCALER_DIV2
* @arg @ref LL_USART_PRESCALER_DIV4
* @arg @ref LL_USART_PRESCALER_DIV6
* @arg @ref LL_USART_PRESCALER_DIV8
* @arg @ref LL_USART_PRESCALER_DIV10
* @arg @ref LL_USART_PRESCALER_DIV12
* @arg @ref LL_USART_PRESCALER_DIV16
* @arg @ref LL_USART_PRESCALER_DIV32
* @arg @ref LL_USART_PRESCALER_DIV64
* @arg @ref LL_USART_PRESCALER_DIV128
* @arg @ref LL_USART_PRESCALER_DIV256
* @retval None
*/
__STATIC_INLINE void LL_USART_SetPrescaler(USART_TypeDef *USARTx, uint32_t PrescalerValue)
{
MODIFY_REG(USARTx->PRESC, USART_PRESC_PRESCALER, (uint16_t)PrescalerValue);
}
/**
* @brief Retrieve the Clock source prescaler for baudrate generator and oversampling
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll PRESC PRESCALER LL_USART_GetPrescaler
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_PRESCALER_DIV1
* @arg @ref LL_USART_PRESCALER_DIV2
* @arg @ref LL_USART_PRESCALER_DIV4
* @arg @ref LL_USART_PRESCALER_DIV6
* @arg @ref LL_USART_PRESCALER_DIV8
* @arg @ref LL_USART_PRESCALER_DIV10
* @arg @ref LL_USART_PRESCALER_DIV12
* @arg @ref LL_USART_PRESCALER_DIV16
* @arg @ref LL_USART_PRESCALER_DIV32
* @arg @ref LL_USART_PRESCALER_DIV64
* @arg @ref LL_USART_PRESCALER_DIV128
* @arg @ref LL_USART_PRESCALER_DIV256
*/
__STATIC_INLINE uint32_t LL_USART_GetPrescaler(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->PRESC, USART_PRESC_PRESCALER));
}
/**
* @brief Enable Clock output on SCLK pin
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 CLKEN LL_USART_EnableSCLKOutput
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableSCLKOutput(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR2, USART_CR2_CLKEN);
}
/**
* @brief Disable Clock output on SCLK pin
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 CLKEN LL_USART_DisableSCLKOutput
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableSCLKOutput(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR2, USART_CR2_CLKEN);
}
/**
* @brief Indicate if Clock output on SCLK pin is enabled
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @rmtoll CR2 CLKEN LL_USART_IsEnabledSCLKOutput
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledSCLKOutput(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR2, USART_CR2_CLKEN) == (USART_CR2_CLKEN)) ? 1UL : 0UL);
}
/**
* @brief Set the length of the stop bits
* @rmtoll CR2 STOP LL_USART_SetStopBitsLength
* @param USARTx USART Instance
* @param StopBits This parameter can be one of the following values:
* @arg @ref LL_USART_STOPBITS_0_5
* @arg @ref LL_USART_STOPBITS_1
* @arg @ref LL_USART_STOPBITS_1_5
* @arg @ref LL_USART_STOPBITS_2
* @retval None
*/
__STATIC_INLINE void LL_USART_SetStopBitsLength(USART_TypeDef *USARTx, uint32_t StopBits)
{
MODIFY_REG(USARTx->CR2, USART_CR2_STOP, StopBits);
}
/**
* @brief Retrieve the length of the stop bits
* @rmtoll CR2 STOP LL_USART_GetStopBitsLength
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_STOPBITS_0_5
* @arg @ref LL_USART_STOPBITS_1
* @arg @ref LL_USART_STOPBITS_1_5
* @arg @ref LL_USART_STOPBITS_2
*/
__STATIC_INLINE uint32_t LL_USART_GetStopBitsLength(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_STOP));
}
/**
* @brief Configure Character frame format (Datawidth, Parity control, Stop Bits)
* @note Call of this function is equivalent to following function call sequence :
* - Data Width configuration using @ref LL_USART_SetDataWidth() function
* - Parity Control and mode configuration using @ref LL_USART_SetParity() function
* - Stop bits configuration using @ref LL_USART_SetStopBitsLength() function
* @rmtoll CR1 PS LL_USART_ConfigCharacter\n
* CR1 PCE LL_USART_ConfigCharacter\n
* CR1 M0 LL_USART_ConfigCharacter\n
* CR1 M1 LL_USART_ConfigCharacter\n
* CR2 STOP LL_USART_ConfigCharacter
* @param USARTx USART Instance
* @param DataWidth This parameter can be one of the following values:
* @arg @ref LL_USART_DATAWIDTH_7B
* @arg @ref LL_USART_DATAWIDTH_8B
* @arg @ref LL_USART_DATAWIDTH_9B
* @param Parity This parameter can be one of the following values:
* @arg @ref LL_USART_PARITY_NONE
* @arg @ref LL_USART_PARITY_EVEN
* @arg @ref LL_USART_PARITY_ODD
* @param StopBits This parameter can be one of the following values:
* @arg @ref LL_USART_STOPBITS_0_5
* @arg @ref LL_USART_STOPBITS_1
* @arg @ref LL_USART_STOPBITS_1_5
* @arg @ref LL_USART_STOPBITS_2
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigCharacter(USART_TypeDef *USARTx, uint32_t DataWidth, uint32_t Parity,
uint32_t StopBits)
{
MODIFY_REG(USARTx->CR1, USART_CR1_PS | USART_CR1_PCE | USART_CR1_M, Parity | DataWidth);
MODIFY_REG(USARTx->CR2, USART_CR2_STOP, StopBits);
}
/**
* @brief Configure TX/RX pins swapping setting.
* @rmtoll CR2 SWAP LL_USART_SetTXRXSwap
* @param USARTx USART Instance
* @param SwapConfig This parameter can be one of the following values:
* @arg @ref LL_USART_TXRX_STANDARD
* @arg @ref LL_USART_TXRX_SWAPPED
* @retval None
*/
__STATIC_INLINE void LL_USART_SetTXRXSwap(USART_TypeDef *USARTx, uint32_t SwapConfig)
{
MODIFY_REG(USARTx->CR2, USART_CR2_SWAP, SwapConfig);
}
/**
* @brief Retrieve TX/RX pins swapping configuration.
* @rmtoll CR2 SWAP LL_USART_GetTXRXSwap
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_TXRX_STANDARD
* @arg @ref LL_USART_TXRX_SWAPPED
*/
__STATIC_INLINE uint32_t LL_USART_GetTXRXSwap(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_SWAP));
}
/**
* @brief Configure RX pin active level logic
* @rmtoll CR2 RXINV LL_USART_SetRXPinLevel
* @param USARTx USART Instance
* @param PinInvMethod This parameter can be one of the following values:
* @arg @ref LL_USART_RXPIN_LEVEL_STANDARD
* @arg @ref LL_USART_RXPIN_LEVEL_INVERTED
* @retval None
*/
__STATIC_INLINE void LL_USART_SetRXPinLevel(USART_TypeDef *USARTx, uint32_t PinInvMethod)
{
MODIFY_REG(USARTx->CR2, USART_CR2_RXINV, PinInvMethod);
}
/**
* @brief Retrieve RX pin active level logic configuration
* @rmtoll CR2 RXINV LL_USART_GetRXPinLevel
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_RXPIN_LEVEL_STANDARD
* @arg @ref LL_USART_RXPIN_LEVEL_INVERTED
*/
__STATIC_INLINE uint32_t LL_USART_GetRXPinLevel(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_RXINV));
}
/**
* @brief Configure TX pin active level logic
* @rmtoll CR2 TXINV LL_USART_SetTXPinLevel
* @param USARTx USART Instance
* @param PinInvMethod This parameter can be one of the following values:
* @arg @ref LL_USART_TXPIN_LEVEL_STANDARD
* @arg @ref LL_USART_TXPIN_LEVEL_INVERTED
* @retval None
*/
__STATIC_INLINE void LL_USART_SetTXPinLevel(USART_TypeDef *USARTx, uint32_t PinInvMethod)
{
MODIFY_REG(USARTx->CR2, USART_CR2_TXINV, PinInvMethod);
}
/**
* @brief Retrieve TX pin active level logic configuration
* @rmtoll CR2 TXINV LL_USART_GetTXPinLevel
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_TXPIN_LEVEL_STANDARD
* @arg @ref LL_USART_TXPIN_LEVEL_INVERTED
*/
__STATIC_INLINE uint32_t LL_USART_GetTXPinLevel(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_TXINV));
}
/**
* @brief Configure Binary data logic.
* @note Allow to define how Logical data from the data register are send/received :
* either in positive/direct logic (1=H, 0=L) or in negative/inverse logic (1=L, 0=H)
* @rmtoll CR2 DATAINV LL_USART_SetBinaryDataLogic
* @param USARTx USART Instance
* @param DataLogic This parameter can be one of the following values:
* @arg @ref LL_USART_BINARY_LOGIC_POSITIVE
* @arg @ref LL_USART_BINARY_LOGIC_NEGATIVE
* @retval None
*/
__STATIC_INLINE void LL_USART_SetBinaryDataLogic(USART_TypeDef *USARTx, uint32_t DataLogic)
{
MODIFY_REG(USARTx->CR2, USART_CR2_DATAINV, DataLogic);
}
/**
* @brief Retrieve Binary data configuration
* @rmtoll CR2 DATAINV LL_USART_GetBinaryDataLogic
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_BINARY_LOGIC_POSITIVE
* @arg @ref LL_USART_BINARY_LOGIC_NEGATIVE
*/
__STATIC_INLINE uint32_t LL_USART_GetBinaryDataLogic(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_DATAINV));
}
/**
* @brief Configure transfer bit order (either Less or Most Significant Bit First)
* @note MSB First means data is transmitted/received with the MSB first, following the start bit.
* LSB First means data is transmitted/received with data bit 0 first, following the start bit.
* @rmtoll CR2 MSBFIRST LL_USART_SetTransferBitOrder
* @param USARTx USART Instance
* @param BitOrder This parameter can be one of the following values:
* @arg @ref LL_USART_BITORDER_LSBFIRST
* @arg @ref LL_USART_BITORDER_MSBFIRST
* @retval None
*/
__STATIC_INLINE void LL_USART_SetTransferBitOrder(USART_TypeDef *USARTx, uint32_t BitOrder)
{
MODIFY_REG(USARTx->CR2, USART_CR2_MSBFIRST, BitOrder);
}
/**
* @brief Return transfer bit order (either Less or Most Significant Bit First)
* @note MSB First means data is transmitted/received with the MSB first, following the start bit.
* LSB First means data is transmitted/received with data bit 0 first, following the start bit.
* @rmtoll CR2 MSBFIRST LL_USART_GetTransferBitOrder
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_BITORDER_LSBFIRST
* @arg @ref LL_USART_BITORDER_MSBFIRST
*/
__STATIC_INLINE uint32_t LL_USART_GetTransferBitOrder(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_MSBFIRST));
}
/**
* @brief Enable Auto Baud-Rate Detection
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll CR2 ABREN LL_USART_EnableAutoBaudRate
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableAutoBaudRate(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR2, USART_CR2_ABREN);
}
/**
* @brief Disable Auto Baud-Rate Detection
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll CR2 ABREN LL_USART_DisableAutoBaudRate
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableAutoBaudRate(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR2, USART_CR2_ABREN);
}
/**
* @brief Indicate if Auto Baud-Rate Detection mechanism is enabled
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll CR2 ABREN LL_USART_IsEnabledAutoBaud
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledAutoBaud(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR2, USART_CR2_ABREN) == (USART_CR2_ABREN)) ? 1UL : 0UL);
}
/**
* @brief Set Auto Baud-Rate mode bits
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll CR2 ABRMODE LL_USART_SetAutoBaudRateMode
* @param USARTx USART Instance
* @param AutoBaudRateMode This parameter can be one of the following values:
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_STARTBIT
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_FALLINGEDGE
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_7F_FRAME
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_55_FRAME
* @retval None
*/
__STATIC_INLINE void LL_USART_SetAutoBaudRateMode(USART_TypeDef *USARTx, uint32_t AutoBaudRateMode)
{
MODIFY_REG(USARTx->CR2, USART_CR2_ABRMODE, AutoBaudRateMode);
}
/**
* @brief Return Auto Baud-Rate mode
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll CR2 ABRMODE LL_USART_GetAutoBaudRateMode
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_STARTBIT
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_FALLINGEDGE
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_7F_FRAME
* @arg @ref LL_USART_AUTOBAUD_DETECT_ON_55_FRAME
*/
__STATIC_INLINE uint32_t LL_USART_GetAutoBaudRateMode(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_ABRMODE));
}
/**
* @brief Enable Receiver Timeout
* @rmtoll CR2 RTOEN LL_USART_EnableRxTimeout
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableRxTimeout(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR2, USART_CR2_RTOEN);
}
/**
* @brief Disable Receiver Timeout
* @rmtoll CR2 RTOEN LL_USART_DisableRxTimeout
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableRxTimeout(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR2, USART_CR2_RTOEN);
}
/**
* @brief Indicate if Receiver Timeout feature is enabled
* @rmtoll CR2 RTOEN LL_USART_IsEnabledRxTimeout
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledRxTimeout(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR2, USART_CR2_RTOEN) == (USART_CR2_RTOEN)) ? 1UL : 0UL);
}
/**
* @brief Set Address of the USART node.
* @note This is used in multiprocessor communication during Mute mode or Stop mode,
* for wake up with address mark detection.
* @note 4bits address node is used when 4-bit Address Detection is selected in ADDM7.
* (b7-b4 should be set to 0)
* 8bits address node is used when 7-bit Address Detection is selected in ADDM7.
* (This is used in multiprocessor communication during Mute mode or Stop mode,
* for wake up with 7-bit address mark detection.
* The MSB of the character sent by the transmitter should be equal to 1.
* It may also be used for character detection during normal reception,
* Mute mode inactive (for example, end of block detection in ModBus protocol).
* In this case, the whole received character (8-bit) is compared to the ADD[7:0]
* value and CMF flag is set on match)
* @rmtoll CR2 ADD LL_USART_ConfigNodeAddress\n
* CR2 ADDM7 LL_USART_ConfigNodeAddress
* @param USARTx USART Instance
* @param AddressLen This parameter can be one of the following values:
* @arg @ref LL_USART_ADDRESS_DETECT_4B
* @arg @ref LL_USART_ADDRESS_DETECT_7B
* @param NodeAddress 4 or 7 bit Address of the USART node.
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigNodeAddress(USART_TypeDef *USARTx, uint32_t AddressLen, uint32_t NodeAddress)
{
MODIFY_REG(USARTx->CR2, USART_CR2_ADD | USART_CR2_ADDM7,
(uint32_t)(AddressLen | (NodeAddress << USART_CR2_ADD_Pos)));
}
/**
* @brief Return 8 bit Address of the USART node as set in ADD field of CR2.
* @note If 4-bit Address Detection is selected in ADDM7,
* only 4bits (b3-b0) of returned value are relevant (b31-b4 are not relevant)
* If 7-bit Address Detection is selected in ADDM7,
* only 8bits (b7-b0) of returned value are relevant (b31-b8 are not relevant)
* @rmtoll CR2 ADD LL_USART_GetNodeAddress
* @param USARTx USART Instance
* @retval Address of the USART node (Value between Min_Data=0 and Max_Data=255)
*/
__STATIC_INLINE uint32_t LL_USART_GetNodeAddress(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_ADD) >> USART_CR2_ADD_Pos);
}
/**
* @brief Return Length of Node Address used in Address Detection mode (7-bit or 4-bit)
* @rmtoll CR2 ADDM7 LL_USART_GetNodeAddressLen
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_ADDRESS_DETECT_4B
* @arg @ref LL_USART_ADDRESS_DETECT_7B
*/
__STATIC_INLINE uint32_t LL_USART_GetNodeAddressLen(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_ADDM7));
}
/**
* @brief Enable RTS HW Flow Control
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 RTSE LL_USART_EnableRTSHWFlowCtrl
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableRTSHWFlowCtrl(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_RTSE);
}
/**
* @brief Disable RTS HW Flow Control
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 RTSE LL_USART_DisableRTSHWFlowCtrl
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableRTSHWFlowCtrl(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_RTSE);
}
/**
* @brief Enable CTS HW Flow Control
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 CTSE LL_USART_EnableCTSHWFlowCtrl
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableCTSHWFlowCtrl(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_CTSE);
}
/**
* @brief Disable CTS HW Flow Control
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 CTSE LL_USART_DisableCTSHWFlowCtrl
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableCTSHWFlowCtrl(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_CTSE);
}
/**
* @brief Configure HW Flow Control mode (both CTS and RTS)
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 RTSE LL_USART_SetHWFlowCtrl\n
* CR3 CTSE LL_USART_SetHWFlowCtrl
* @param USARTx USART Instance
* @param HardwareFlowControl This parameter can be one of the following values:
* @arg @ref LL_USART_HWCONTROL_NONE
* @arg @ref LL_USART_HWCONTROL_RTS
* @arg @ref LL_USART_HWCONTROL_CTS
* @arg @ref LL_USART_HWCONTROL_RTS_CTS
* @retval None
*/
__STATIC_INLINE void LL_USART_SetHWFlowCtrl(USART_TypeDef *USARTx, uint32_t HardwareFlowControl)
{
MODIFY_REG(USARTx->CR3, USART_CR3_RTSE | USART_CR3_CTSE, HardwareFlowControl);
}
/**
* @brief Return HW Flow Control configuration (both CTS and RTS)
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 RTSE LL_USART_GetHWFlowCtrl\n
* CR3 CTSE LL_USART_GetHWFlowCtrl
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_HWCONTROL_NONE
* @arg @ref LL_USART_HWCONTROL_RTS
* @arg @ref LL_USART_HWCONTROL_CTS
* @arg @ref LL_USART_HWCONTROL_RTS_CTS
*/
__STATIC_INLINE uint32_t LL_USART_GetHWFlowCtrl(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR3, USART_CR3_RTSE | USART_CR3_CTSE));
}
/**
* @brief Enable One bit sampling method
* @rmtoll CR3 ONEBIT LL_USART_EnableOneBitSamp
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableOneBitSamp(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_ONEBIT);
}
/**
* @brief Disable One bit sampling method
* @rmtoll CR3 ONEBIT LL_USART_DisableOneBitSamp
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableOneBitSamp(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_ONEBIT);
}
/**
* @brief Indicate if One bit sampling method is enabled
* @rmtoll CR3 ONEBIT LL_USART_IsEnabledOneBitSamp
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledOneBitSamp(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_ONEBIT) == (USART_CR3_ONEBIT)) ? 1UL : 0UL);
}
/**
* @brief Enable Overrun detection
* @rmtoll CR3 OVRDIS LL_USART_EnableOverrunDetect
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableOverrunDetect(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_OVRDIS);
}
/**
* @brief Disable Overrun detection
* @rmtoll CR3 OVRDIS LL_USART_DisableOverrunDetect
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableOverrunDetect(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_OVRDIS);
}
/**
* @brief Indicate if Overrun detection is enabled
* @rmtoll CR3 OVRDIS LL_USART_IsEnabledOverrunDetect
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledOverrunDetect(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_OVRDIS) != USART_CR3_OVRDIS) ? 1UL : 0UL);
}
/**
* @brief Select event type for Wake UP Interrupt Flag (WUS[1:0] bits)
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR3 WUS LL_USART_SetWKUPType
* @param USARTx USART Instance
* @param Type This parameter can be one of the following values:
* @arg @ref LL_USART_WAKEUP_ON_ADDRESS
* @arg @ref LL_USART_WAKEUP_ON_STARTBIT
* @arg @ref LL_USART_WAKEUP_ON_RXNE
* @retval None
*/
__STATIC_INLINE void LL_USART_SetWKUPType(USART_TypeDef *USARTx, uint32_t Type)
{
MODIFY_REG(USARTx->CR3, USART_CR3_WUS, Type);
}
/**
* @brief Return event type for Wake UP Interrupt Flag (WUS[1:0] bits)
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR3 WUS LL_USART_GetWKUPType
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_WAKEUP_ON_ADDRESS
* @arg @ref LL_USART_WAKEUP_ON_STARTBIT
* @arg @ref LL_USART_WAKEUP_ON_RXNE
*/
__STATIC_INLINE uint32_t LL_USART_GetWKUPType(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR3, USART_CR3_WUS));
}
/**
* @brief Configure USART BRR register for achieving expected Baud Rate value.
* @note Compute and set USARTDIV value in BRR Register (full BRR content)
* according to used Peripheral Clock, Oversampling mode, and expected Baud Rate values
* @note Peripheral clock and Baud rate values provided as function parameters should be valid
* (Baud rate value != 0)
* @note In case of oversampling by 16 and 8, BRR content must be greater than or equal to 16d.
* @rmtoll BRR BRR LL_USART_SetBaudRate
* @param USARTx USART Instance
* @param PeriphClk Peripheral Clock
* @param PrescalerValue This parameter can be one of the following values:
* @arg @ref LL_USART_PRESCALER_DIV1
* @arg @ref LL_USART_PRESCALER_DIV2
* @arg @ref LL_USART_PRESCALER_DIV4
* @arg @ref LL_USART_PRESCALER_DIV6
* @arg @ref LL_USART_PRESCALER_DIV8
* @arg @ref LL_USART_PRESCALER_DIV10
* @arg @ref LL_USART_PRESCALER_DIV12
* @arg @ref LL_USART_PRESCALER_DIV16
* @arg @ref LL_USART_PRESCALER_DIV32
* @arg @ref LL_USART_PRESCALER_DIV64
* @arg @ref LL_USART_PRESCALER_DIV128
* @arg @ref LL_USART_PRESCALER_DIV256
* @param OverSampling This parameter can be one of the following values:
* @arg @ref LL_USART_OVERSAMPLING_16
* @arg @ref LL_USART_OVERSAMPLING_8
* @param BaudRate Baud Rate
* @retval None
*/
__STATIC_INLINE void LL_USART_SetBaudRate(USART_TypeDef *USARTx, uint32_t PeriphClk, uint32_t PrescalerValue,
uint32_t OverSampling,
uint32_t BaudRate)
{
uint32_t usartdiv;
uint32_t brrtemp;
if (PrescalerValue > LL_USART_PRESCALER_DIV256)
{
/* Do not overstep the size of USART_PRESCALER_TAB */
}
else if (BaudRate == 0U)
{
/* Can Not divide per 0 */
}
else if (OverSampling == LL_USART_OVERSAMPLING_8)
{
usartdiv = (uint16_t)(__LL_USART_DIV_SAMPLING8(PeriphClk, (uint8_t)PrescalerValue, BaudRate));
brrtemp = usartdiv & 0xFFF0U;
brrtemp |= (uint16_t)((usartdiv & (uint16_t)0x000FU) >> 1U);
USARTx->BRR = brrtemp;
}
else
{
USARTx->BRR = (uint16_t)(__LL_USART_DIV_SAMPLING16(PeriphClk, (uint8_t)PrescalerValue, BaudRate));
}
}
/**
* @brief Return current Baud Rate value, according to USARTDIV present in BRR register
* (full BRR content), and to used Peripheral Clock and Oversampling mode values
* @note In case of non-initialized or invalid value stored in BRR register, value 0 will be returned.
* @note In case of oversampling by 16 and 8, BRR content must be greater than or equal to 16d.
* @rmtoll BRR BRR LL_USART_GetBaudRate
* @param USARTx USART Instance
* @param PeriphClk Peripheral Clock
* @param PrescalerValue This parameter can be one of the following values:
* @arg @ref LL_USART_PRESCALER_DIV1
* @arg @ref LL_USART_PRESCALER_DIV2
* @arg @ref LL_USART_PRESCALER_DIV4
* @arg @ref LL_USART_PRESCALER_DIV6
* @arg @ref LL_USART_PRESCALER_DIV8
* @arg @ref LL_USART_PRESCALER_DIV10
* @arg @ref LL_USART_PRESCALER_DIV12
* @arg @ref LL_USART_PRESCALER_DIV16
* @arg @ref LL_USART_PRESCALER_DIV32
* @arg @ref LL_USART_PRESCALER_DIV64
* @arg @ref LL_USART_PRESCALER_DIV128
* @arg @ref LL_USART_PRESCALER_DIV256
* @param OverSampling This parameter can be one of the following values:
* @arg @ref LL_USART_OVERSAMPLING_16
* @arg @ref LL_USART_OVERSAMPLING_8
* @retval Baud Rate
*/
__STATIC_INLINE uint32_t LL_USART_GetBaudRate(const USART_TypeDef *USARTx, uint32_t PeriphClk, uint32_t PrescalerValue,
uint32_t OverSampling)
{
uint32_t usartdiv;
uint32_t brrresult = 0x0U;
uint32_t periphclkpresc = (uint32_t)(PeriphClk / (USART_PRESCALER_TAB[(uint8_t)PrescalerValue]));
usartdiv = USARTx->BRR;
if (usartdiv == 0U)
{
/* Do not perform a division by 0 */
}
else if (OverSampling == LL_USART_OVERSAMPLING_8)
{
usartdiv = (uint16_t)((usartdiv & 0xFFF0U) | ((usartdiv & 0x0007U) << 1U)) ;
if (usartdiv != 0U)
{
brrresult = (periphclkpresc * 2U) / usartdiv;
}
}
else
{
if ((usartdiv & 0xFFFFU) != 0U)
{
brrresult = periphclkpresc / usartdiv;
}
}
return (brrresult);
}
/**
* @brief Set Receiver Time Out Value (expressed in nb of bits duration)
* @rmtoll RTOR RTO LL_USART_SetRxTimeout
* @param USARTx USART Instance
* @param Timeout Value between Min_Data=0x00 and Max_Data=0x00FFFFFF
* @retval None
*/
__STATIC_INLINE void LL_USART_SetRxTimeout(USART_TypeDef *USARTx, uint32_t Timeout)
{
MODIFY_REG(USARTx->RTOR, USART_RTOR_RTO, Timeout);
}
/**
* @brief Get Receiver Time Out Value (expressed in nb of bits duration)
* @rmtoll RTOR RTO LL_USART_GetRxTimeout
* @param USARTx USART Instance
* @retval Value between Min_Data=0x00 and Max_Data=0x00FFFFFF
*/
__STATIC_INLINE uint32_t LL_USART_GetRxTimeout(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->RTOR, USART_RTOR_RTO));
}
/**
* @brief Set Block Length value in reception
* @rmtoll RTOR BLEN LL_USART_SetBlockLength
* @param USARTx USART Instance
* @param BlockLength Value between Min_Data=0x00 and Max_Data=0xFF
* @retval None
*/
__STATIC_INLINE void LL_USART_SetBlockLength(USART_TypeDef *USARTx, uint32_t BlockLength)
{
MODIFY_REG(USARTx->RTOR, USART_RTOR_BLEN, BlockLength << USART_RTOR_BLEN_Pos);
}
/**
* @brief Get Block Length value in reception
* @rmtoll RTOR BLEN LL_USART_GetBlockLength
* @param USARTx USART Instance
* @retval Value between Min_Data=0x00 and Max_Data=0xFF
*/
__STATIC_INLINE uint32_t LL_USART_GetBlockLength(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->RTOR, USART_RTOR_BLEN) >> USART_RTOR_BLEN_Pos);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Configuration_IRDA Configuration functions related to Irda feature
* @{
*/
/**
* @brief Enable IrDA mode
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @rmtoll CR3 IREN LL_USART_EnableIrda
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIrda(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_IREN);
}
/**
* @brief Disable IrDA mode
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @rmtoll CR3 IREN LL_USART_DisableIrda
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIrda(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_IREN);
}
/**
* @brief Indicate if IrDA mode is enabled
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @rmtoll CR3 IREN LL_USART_IsEnabledIrda
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIrda(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_IREN) == (USART_CR3_IREN)) ? 1UL : 0UL);
}
/**
* @brief Configure IrDA Power Mode (Normal or Low Power)
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @rmtoll CR3 IRLP LL_USART_SetIrdaPowerMode
* @param USARTx USART Instance
* @param PowerMode This parameter can be one of the following values:
* @arg @ref LL_USART_IRDA_POWER_NORMAL
* @arg @ref LL_USART_IRDA_POWER_LOW
* @retval None
*/
__STATIC_INLINE void LL_USART_SetIrdaPowerMode(USART_TypeDef *USARTx, uint32_t PowerMode)
{
MODIFY_REG(USARTx->CR3, USART_CR3_IRLP, PowerMode);
}
/**
* @brief Retrieve IrDA Power Mode configuration (Normal or Low Power)
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @rmtoll CR3 IRLP LL_USART_GetIrdaPowerMode
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_IRDA_POWER_NORMAL
* @arg @ref LL_USART_PHASE_2EDGE
*/
__STATIC_INLINE uint32_t LL_USART_GetIrdaPowerMode(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR3, USART_CR3_IRLP));
}
/**
* @brief Set Irda prescaler value, used for dividing the USART clock source
* to achieve the Irda Low Power frequency (8 bits value)
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @rmtoll GTPR PSC LL_USART_SetIrdaPrescaler
* @param USARTx USART Instance
* @param PrescalerValue Value between Min_Data=0x00 and Max_Data=0xFF
* @retval None
*/
__STATIC_INLINE void LL_USART_SetIrdaPrescaler(USART_TypeDef *USARTx, uint32_t PrescalerValue)
{
MODIFY_REG(USARTx->GTPR, USART_GTPR_PSC, (uint16_t)PrescalerValue);
}
/**
* @brief Return Irda prescaler value, used for dividing the USART clock source
* to achieve the Irda Low Power frequency (8 bits value)
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @rmtoll GTPR PSC LL_USART_GetIrdaPrescaler
* @param USARTx USART Instance
* @retval Irda prescaler value (Value between Min_Data=0x00 and Max_Data=0xFF)
*/
__STATIC_INLINE uint32_t LL_USART_GetIrdaPrescaler(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->GTPR, USART_GTPR_PSC));
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Configuration_Smartcard Configuration functions related to Smartcard feature
* @{
*/
/**
* @brief Enable Smartcard NACK transmission
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 NACK LL_USART_EnableSmartcardNACK
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableSmartcardNACK(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_NACK);
}
/**
* @brief Disable Smartcard NACK transmission
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 NACK LL_USART_DisableSmartcardNACK
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableSmartcardNACK(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_NACK);
}
/**
* @brief Indicate if Smartcard NACK transmission is enabled
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 NACK LL_USART_IsEnabledSmartcardNACK
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledSmartcardNACK(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_NACK) == (USART_CR3_NACK)) ? 1UL : 0UL);
}
/**
* @brief Enable Smartcard mode
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 SCEN LL_USART_EnableSmartcard
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableSmartcard(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_SCEN);
}
/**
* @brief Disable Smartcard mode
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 SCEN LL_USART_DisableSmartcard
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableSmartcard(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_SCEN);
}
/**
* @brief Indicate if Smartcard mode is enabled
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 SCEN LL_USART_IsEnabledSmartcard
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledSmartcard(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_SCEN) == (USART_CR3_SCEN)) ? 1UL : 0UL);
}
/**
* @brief Set Smartcard Auto-Retry Count value (SCARCNT[2:0] bits)
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @note This bit-field specifies the number of retries in transmit and receive, in Smartcard mode.
* In transmission mode, it specifies the number of automatic retransmission retries, before
* generating a transmission error (FE bit set).
* In reception mode, it specifies the number or erroneous reception trials, before generating a
* reception error (RXNE and PE bits set)
* @rmtoll CR3 SCARCNT LL_USART_SetSmartcardAutoRetryCount
* @param USARTx USART Instance
* @param AutoRetryCount Value between Min_Data=0 and Max_Data=7
* @retval None
*/
__STATIC_INLINE void LL_USART_SetSmartcardAutoRetryCount(USART_TypeDef *USARTx, uint32_t AutoRetryCount)
{
MODIFY_REG(USARTx->CR3, USART_CR3_SCARCNT, AutoRetryCount << USART_CR3_SCARCNT_Pos);
}
/**
* @brief Return Smartcard Auto-Retry Count value (SCARCNT[2:0] bits)
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 SCARCNT LL_USART_GetSmartcardAutoRetryCount
* @param USARTx USART Instance
* @retval Smartcard Auto-Retry Count value (Value between Min_Data=0 and Max_Data=7)
*/
__STATIC_INLINE uint32_t LL_USART_GetSmartcardAutoRetryCount(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR3, USART_CR3_SCARCNT) >> USART_CR3_SCARCNT_Pos);
}
/**
* @brief Set Smartcard prescaler value, used for dividing the USART clock
* source to provide the SMARTCARD Clock (5 bits value)
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll GTPR PSC LL_USART_SetSmartcardPrescaler
* @param USARTx USART Instance
* @param PrescalerValue Value between Min_Data=0 and Max_Data=31
* @retval None
*/
__STATIC_INLINE void LL_USART_SetSmartcardPrescaler(USART_TypeDef *USARTx, uint32_t PrescalerValue)
{
MODIFY_REG(USARTx->GTPR, USART_GTPR_PSC, (uint16_t)PrescalerValue);
}
/**
* @brief Return Smartcard prescaler value, used for dividing the USART clock
* source to provide the SMARTCARD Clock (5 bits value)
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll GTPR PSC LL_USART_GetSmartcardPrescaler
* @param USARTx USART Instance
* @retval Smartcard prescaler value (Value between Min_Data=0 and Max_Data=31)
*/
__STATIC_INLINE uint32_t LL_USART_GetSmartcardPrescaler(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->GTPR, USART_GTPR_PSC));
}
/**
* @brief Set Smartcard Guard time value, expressed in nb of baud clocks periods
* (GT[7:0] bits : Guard time value)
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll GTPR GT LL_USART_SetSmartcardGuardTime
* @param USARTx USART Instance
* @param GuardTime Value between Min_Data=0x00 and Max_Data=0xFF
* @retval None
*/
__STATIC_INLINE void LL_USART_SetSmartcardGuardTime(USART_TypeDef *USARTx, uint32_t GuardTime)
{
MODIFY_REG(USARTx->GTPR, USART_GTPR_GT, (uint16_t)(GuardTime << USART_GTPR_GT_Pos));
}
/**
* @brief Return Smartcard Guard time value, expressed in nb of baud clocks periods
* (GT[7:0] bits : Guard time value)
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll GTPR GT LL_USART_GetSmartcardGuardTime
* @param USARTx USART Instance
* @retval Smartcard Guard time value (Value between Min_Data=0x00 and Max_Data=0xFF)
*/
__STATIC_INLINE uint32_t LL_USART_GetSmartcardGuardTime(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->GTPR, USART_GTPR_GT) >> USART_GTPR_GT_Pos);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Configuration_HalfDuplex Configuration functions related to Half Duplex feature
* @{
*/
/**
* @brief Enable Single Wire Half-Duplex mode
* @note Macro IS_UART_HALFDUPLEX_INSTANCE(USARTx) can be used to check whether or not
* Half-Duplex mode is supported by the USARTx instance.
* @rmtoll CR3 HDSEL LL_USART_EnableHalfDuplex
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableHalfDuplex(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_HDSEL);
}
/**
* @brief Disable Single Wire Half-Duplex mode
* @note Macro IS_UART_HALFDUPLEX_INSTANCE(USARTx) can be used to check whether or not
* Half-Duplex mode is supported by the USARTx instance.
* @rmtoll CR3 HDSEL LL_USART_DisableHalfDuplex
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableHalfDuplex(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_HDSEL);
}
/**
* @brief Indicate if Single Wire Half-Duplex mode is enabled
* @note Macro IS_UART_HALFDUPLEX_INSTANCE(USARTx) can be used to check whether or not
* Half-Duplex mode is supported by the USARTx instance.
* @rmtoll CR3 HDSEL LL_USART_IsEnabledHalfDuplex
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledHalfDuplex(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_HDSEL) == (USART_CR3_HDSEL)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Configuration_SPI_SLAVE Configuration functions related to SPI Slave feature
* @{
*/
/**
* @brief Enable SPI Synchronous Slave mode
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @rmtoll CR2 SLVEN LL_USART_EnableSPISlave
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableSPISlave(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR2, USART_CR2_SLVEN);
}
/**
* @brief Disable SPI Synchronous Slave mode
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @rmtoll CR2 SLVEN LL_USART_DisableSPISlave
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableSPISlave(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR2, USART_CR2_SLVEN);
}
/**
* @brief Indicate if SPI Synchronous Slave mode is enabled
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @rmtoll CR2 SLVEN LL_USART_IsEnabledSPISlave
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledSPISlave(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR2, USART_CR2_SLVEN) == (USART_CR2_SLVEN)) ? 1UL : 0UL);
}
/**
* @brief Enable SPI Slave Selection using NSS input pin
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @note SPI Slave Selection depends on NSS input pin
* (The slave is selected when NSS is low and deselected when NSS is high).
* @rmtoll CR2 DIS_NSS LL_USART_EnableSPISlaveSelect
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableSPISlaveSelect(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR2, USART_CR2_DIS_NSS);
}
/**
* @brief Disable SPI Slave Selection using NSS input pin
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @note SPI Slave will be always selected and NSS input pin will be ignored.
* @rmtoll CR2 DIS_NSS LL_USART_DisableSPISlaveSelect
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableSPISlaveSelect(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR2, USART_CR2_DIS_NSS);
}
/**
* @brief Indicate if SPI Slave Selection depends on NSS input pin
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @rmtoll CR2 DIS_NSS LL_USART_IsEnabledSPISlaveSelect
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledSPISlaveSelect(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR2, USART_CR2_DIS_NSS) != (USART_CR2_DIS_NSS)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Configuration_LIN Configuration functions related to LIN feature
* @{
*/
/**
* @brief Set LIN Break Detection Length
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LBDL LL_USART_SetLINBrkDetectionLen
* @param USARTx USART Instance
* @param LINBDLength This parameter can be one of the following values:
* @arg @ref LL_USART_LINBREAK_DETECT_10B
* @arg @ref LL_USART_LINBREAK_DETECT_11B
* @retval None
*/
__STATIC_INLINE void LL_USART_SetLINBrkDetectionLen(USART_TypeDef *USARTx, uint32_t LINBDLength)
{
MODIFY_REG(USARTx->CR2, USART_CR2_LBDL, LINBDLength);
}
/**
* @brief Return LIN Break Detection Length
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LBDL LL_USART_GetLINBrkDetectionLen
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_LINBREAK_DETECT_10B
* @arg @ref LL_USART_LINBREAK_DETECT_11B
*/
__STATIC_INLINE uint32_t LL_USART_GetLINBrkDetectionLen(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR2, USART_CR2_LBDL));
}
/**
* @brief Enable LIN mode
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LINEN LL_USART_EnableLIN
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableLIN(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR2, USART_CR2_LINEN);
}
/**
* @brief Disable LIN mode
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LINEN LL_USART_DisableLIN
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableLIN(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR2, USART_CR2_LINEN);
}
/**
* @brief Indicate if LIN mode is enabled
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LINEN LL_USART_IsEnabledLIN
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledLIN(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR2, USART_CR2_LINEN) == (USART_CR2_LINEN)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Configuration_DE Configuration functions related to Driver Enable feature
* @{
*/
/**
* @brief Set DEDT (Driver Enable De-Assertion Time), Time value expressed on 5 bits ([4:0] bits).
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR1 DEDT LL_USART_SetDEDeassertionTime
* @param USARTx USART Instance
* @param Time Value between Min_Data=0 and Max_Data=31
* @retval None
*/
__STATIC_INLINE void LL_USART_SetDEDeassertionTime(USART_TypeDef *USARTx, uint32_t Time)
{
MODIFY_REG(USARTx->CR1, USART_CR1_DEDT, Time << USART_CR1_DEDT_Pos);
}
/**
* @brief Return DEDT (Driver Enable De-Assertion Time)
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR1 DEDT LL_USART_GetDEDeassertionTime
* @param USARTx USART Instance
* @retval Time value expressed on 5 bits ([4:0] bits) : Value between Min_Data=0 and Max_Data=31
*/
__STATIC_INLINE uint32_t LL_USART_GetDEDeassertionTime(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR1, USART_CR1_DEDT) >> USART_CR1_DEDT_Pos);
}
/**
* @brief Set DEAT (Driver Enable Assertion Time), Time value expressed on 5 bits ([4:0] bits).
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR1 DEAT LL_USART_SetDEAssertionTime
* @param USARTx USART Instance
* @param Time Value between Min_Data=0 and Max_Data=31
* @retval None
*/
__STATIC_INLINE void LL_USART_SetDEAssertionTime(USART_TypeDef *USARTx, uint32_t Time)
{
MODIFY_REG(USARTx->CR1, USART_CR1_DEAT, Time << USART_CR1_DEAT_Pos);
}
/**
* @brief Return DEAT (Driver Enable Assertion Time)
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR1 DEAT LL_USART_GetDEAssertionTime
* @param USARTx USART Instance
* @retval Time value expressed on 5 bits ([4:0] bits) : Value between Min_Data=0 and Max_Data=31
*/
__STATIC_INLINE uint32_t LL_USART_GetDEAssertionTime(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR1, USART_CR1_DEAT) >> USART_CR1_DEAT_Pos);
}
/**
* @brief Enable Driver Enable (DE) Mode
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR3 DEM LL_USART_EnableDEMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableDEMode(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_DEM);
}
/**
* @brief Disable Driver Enable (DE) Mode
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR3 DEM LL_USART_DisableDEMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableDEMode(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_DEM);
}
/**
* @brief Indicate if Driver Enable (DE) Mode is enabled
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR3 DEM LL_USART_IsEnabledDEMode
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledDEMode(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_DEM) == (USART_CR3_DEM)) ? 1UL : 0UL);
}
/**
* @brief Select Driver Enable Polarity
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR3 DEP LL_USART_SetDESignalPolarity
* @param USARTx USART Instance
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_USART_DE_POLARITY_HIGH
* @arg @ref LL_USART_DE_POLARITY_LOW
* @retval None
*/
__STATIC_INLINE void LL_USART_SetDESignalPolarity(USART_TypeDef *USARTx, uint32_t Polarity)
{
MODIFY_REG(USARTx->CR3, USART_CR3_DEP, Polarity);
}
/**
* @brief Return Driver Enable Polarity
* @note Macro IS_UART_DRIVER_ENABLE_INSTANCE(USARTx) can be used to check whether or not
* Driver Enable feature is supported by the USARTx instance.
* @rmtoll CR3 DEP LL_USART_GetDESignalPolarity
* @param USARTx USART Instance
* @retval Returned value can be one of the following values:
* @arg @ref LL_USART_DE_POLARITY_HIGH
* @arg @ref LL_USART_DE_POLARITY_LOW
*/
__STATIC_INLINE uint32_t LL_USART_GetDESignalPolarity(const USART_TypeDef *USARTx)
{
return (uint32_t)(READ_BIT(USARTx->CR3, USART_CR3_DEP));
}
/**
* @}
*/
/** @defgroup USART_LL_EF_AdvancedConfiguration Advanced Configurations services
* @{
*/
/**
* @brief Perform basic configuration of USART for enabling use in Asynchronous Mode (UART)
* @note In UART mode, the following bits must be kept cleared:
* - LINEN bit in the USART_CR2 register,
* - CLKEN bit in the USART_CR2 register,
* - SCEN bit in the USART_CR3 register,
* - IREN bit in the USART_CR3 register,
* - HDSEL bit in the USART_CR3 register.
* @note Call of this function is equivalent to following function call sequence :
* - Clear LINEN in CR2 using @ref LL_USART_DisableLIN() function
* - Clear CLKEN in CR2 using @ref LL_USART_DisableSCLKOutput() function
* - Clear SCEN in CR3 using @ref LL_USART_DisableSmartcard() function
* - Clear IREN in CR3 using @ref LL_USART_DisableIrda() function
* - Clear HDSEL in CR3 using @ref LL_USART_DisableHalfDuplex() function
* @note Other remaining configurations items related to Asynchronous Mode
* (as Baud Rate, Word length, Parity, ...) should be set using
* dedicated functions
* @rmtoll CR2 LINEN LL_USART_ConfigAsyncMode\n
* CR2 CLKEN LL_USART_ConfigAsyncMode\n
* CR3 SCEN LL_USART_ConfigAsyncMode\n
* CR3 IREN LL_USART_ConfigAsyncMode\n
* CR3 HDSEL LL_USART_ConfigAsyncMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigAsyncMode(USART_TypeDef *USARTx)
{
/* In Asynchronous mode, the following bits must be kept cleared:
- LINEN, CLKEN bits in the USART_CR2 register,
- SCEN, IREN and HDSEL bits in the USART_CR3 register.
*/
CLEAR_BIT(USARTx->CR2, (USART_CR2_LINEN | USART_CR2_CLKEN));
CLEAR_BIT(USARTx->CR3, (USART_CR3_SCEN | USART_CR3_IREN | USART_CR3_HDSEL));
}
/**
* @brief Perform basic configuration of USART for enabling use in Synchronous Mode
* @note In Synchronous mode, the following bits must be kept cleared:
* - LINEN bit in the USART_CR2 register,
* - SCEN bit in the USART_CR3 register,
* - IREN bit in the USART_CR3 register,
* - HDSEL bit in the USART_CR3 register.
* This function also sets the USART in Synchronous mode.
* @note Macro IS_USART_INSTANCE(USARTx) can be used to check whether or not
* Synchronous mode is supported by the USARTx instance.
* @note Call of this function is equivalent to following function call sequence :
* - Clear LINEN in CR2 using @ref LL_USART_DisableLIN() function
* - Clear IREN in CR3 using @ref LL_USART_DisableIrda() function
* - Clear SCEN in CR3 using @ref LL_USART_DisableSmartcard() function
* - Clear HDSEL in CR3 using @ref LL_USART_DisableHalfDuplex() function
* - Set CLKEN in CR2 using @ref LL_USART_EnableSCLKOutput() function
* @note Other remaining configurations items related to Synchronous Mode
* (as Baud Rate, Word length, Parity, Clock Polarity, ...) should be set using
* dedicated functions
* @rmtoll CR2 LINEN LL_USART_ConfigSyncMode\n
* CR2 CLKEN LL_USART_ConfigSyncMode\n
* CR3 SCEN LL_USART_ConfigSyncMode\n
* CR3 IREN LL_USART_ConfigSyncMode\n
* CR3 HDSEL LL_USART_ConfigSyncMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigSyncMode(USART_TypeDef *USARTx)
{
/* In Synchronous mode, the following bits must be kept cleared:
- LINEN bit in the USART_CR2 register,
- SCEN, IREN and HDSEL bits in the USART_CR3 register.
*/
CLEAR_BIT(USARTx->CR2, (USART_CR2_LINEN));
CLEAR_BIT(USARTx->CR3, (USART_CR3_SCEN | USART_CR3_IREN | USART_CR3_HDSEL));
/* set the UART/USART in Synchronous mode */
SET_BIT(USARTx->CR2, USART_CR2_CLKEN);
}
/**
* @brief Perform basic configuration of USART for enabling use in LIN Mode
* @note In LIN mode, the following bits must be kept cleared:
* - STOP and CLKEN bits in the USART_CR2 register,
* - SCEN bit in the USART_CR3 register,
* - IREN bit in the USART_CR3 register,
* - HDSEL bit in the USART_CR3 register.
* This function also set the UART/USART in LIN mode.
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @note Call of this function is equivalent to following function call sequence :
* - Clear CLKEN in CR2 using @ref LL_USART_DisableSCLKOutput() function
* - Clear STOP in CR2 using @ref LL_USART_SetStopBitsLength() function
* - Clear SCEN in CR3 using @ref LL_USART_DisableSmartcard() function
* - Clear IREN in CR3 using @ref LL_USART_DisableIrda() function
* - Clear HDSEL in CR3 using @ref LL_USART_DisableHalfDuplex() function
* - Set LINEN in CR2 using @ref LL_USART_EnableLIN() function
* @note Other remaining configurations items related to LIN Mode
* (as Baud Rate, Word length, LIN Break Detection Length, ...) should be set using
* dedicated functions
* @rmtoll CR2 CLKEN LL_USART_ConfigLINMode\n
* CR2 STOP LL_USART_ConfigLINMode\n
* CR2 LINEN LL_USART_ConfigLINMode\n
* CR3 IREN LL_USART_ConfigLINMode\n
* CR3 SCEN LL_USART_ConfigLINMode\n
* CR3 HDSEL LL_USART_ConfigLINMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigLINMode(USART_TypeDef *USARTx)
{
/* In LIN mode, the following bits must be kept cleared:
- STOP and CLKEN bits in the USART_CR2 register,
- IREN, SCEN and HDSEL bits in the USART_CR3 register.
*/
CLEAR_BIT(USARTx->CR2, (USART_CR2_CLKEN | USART_CR2_STOP));
CLEAR_BIT(USARTx->CR3, (USART_CR3_IREN | USART_CR3_SCEN | USART_CR3_HDSEL));
/* Set the UART/USART in LIN mode */
SET_BIT(USARTx->CR2, USART_CR2_LINEN);
}
/**
* @brief Perform basic configuration of USART for enabling use in Half Duplex Mode
* @note In Half Duplex mode, the following bits must be kept cleared:
* - LINEN bit in the USART_CR2 register,
* - CLKEN bit in the USART_CR2 register,
* - SCEN bit in the USART_CR3 register,
* - IREN bit in the USART_CR3 register,
* This function also sets the UART/USART in Half Duplex mode.
* @note Macro IS_UART_HALFDUPLEX_INSTANCE(USARTx) can be used to check whether or not
* Half-Duplex mode is supported by the USARTx instance.
* @note Call of this function is equivalent to following function call sequence :
* - Clear LINEN in CR2 using @ref LL_USART_DisableLIN() function
* - Clear CLKEN in CR2 using @ref LL_USART_DisableSCLKOutput() function
* - Clear SCEN in CR3 using @ref LL_USART_DisableSmartcard() function
* - Clear IREN in CR3 using @ref LL_USART_DisableIrda() function
* - Set HDSEL in CR3 using @ref LL_USART_EnableHalfDuplex() function
* @note Other remaining configurations items related to Half Duplex Mode
* (as Baud Rate, Word length, Parity, ...) should be set using
* dedicated functions
* @rmtoll CR2 LINEN LL_USART_ConfigHalfDuplexMode\n
* CR2 CLKEN LL_USART_ConfigHalfDuplexMode\n
* CR3 HDSEL LL_USART_ConfigHalfDuplexMode\n
* CR3 SCEN LL_USART_ConfigHalfDuplexMode\n
* CR3 IREN LL_USART_ConfigHalfDuplexMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigHalfDuplexMode(USART_TypeDef *USARTx)
{
/* In Half Duplex mode, the following bits must be kept cleared:
- LINEN and CLKEN bits in the USART_CR2 register,
- SCEN and IREN bits in the USART_CR3 register.
*/
CLEAR_BIT(USARTx->CR2, (USART_CR2_LINEN | USART_CR2_CLKEN));
CLEAR_BIT(USARTx->CR3, (USART_CR3_SCEN | USART_CR3_IREN));
/* set the UART/USART in Half Duplex mode */
SET_BIT(USARTx->CR3, USART_CR3_HDSEL);
}
/**
* @brief Perform basic configuration of USART for enabling use in Smartcard Mode
* @note In Smartcard mode, the following bits must be kept cleared:
* - LINEN bit in the USART_CR2 register,
* - IREN bit in the USART_CR3 register,
* - HDSEL bit in the USART_CR3 register.
* This function also configures Stop bits to 1.5 bits and
* sets the USART in Smartcard mode (SCEN bit).
* Clock Output is also enabled (CLKEN).
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @note Call of this function is equivalent to following function call sequence :
* - Clear LINEN in CR2 using @ref LL_USART_DisableLIN() function
* - Clear IREN in CR3 using @ref LL_USART_DisableIrda() function
* - Clear HDSEL in CR3 using @ref LL_USART_DisableHalfDuplex() function
* - Configure STOP in CR2 using @ref LL_USART_SetStopBitsLength() function
* - Set CLKEN in CR2 using @ref LL_USART_EnableSCLKOutput() function
* - Set SCEN in CR3 using @ref LL_USART_EnableSmartcard() function
* @note Other remaining configurations items related to Smartcard Mode
* (as Baud Rate, Word length, Parity, ...) should be set using
* dedicated functions
* @rmtoll CR2 LINEN LL_USART_ConfigSmartcardMode\n
* CR2 STOP LL_USART_ConfigSmartcardMode\n
* CR2 CLKEN LL_USART_ConfigSmartcardMode\n
* CR3 HDSEL LL_USART_ConfigSmartcardMode\n
* CR3 SCEN LL_USART_ConfigSmartcardMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigSmartcardMode(USART_TypeDef *USARTx)
{
/* In Smartcard mode, the following bits must be kept cleared:
- LINEN bit in the USART_CR2 register,
- IREN and HDSEL bits in the USART_CR3 register.
*/
CLEAR_BIT(USARTx->CR2, (USART_CR2_LINEN));
CLEAR_BIT(USARTx->CR3, (USART_CR3_IREN | USART_CR3_HDSEL));
/* Configure Stop bits to 1.5 bits */
/* Synchronous mode is activated by default */
SET_BIT(USARTx->CR2, (USART_CR2_STOP_0 | USART_CR2_STOP_1 | USART_CR2_CLKEN));
/* set the UART/USART in Smartcard mode */
SET_BIT(USARTx->CR3, USART_CR3_SCEN);
}
/**
* @brief Perform basic configuration of USART for enabling use in Irda Mode
* @note In IRDA mode, the following bits must be kept cleared:
* - LINEN bit in the USART_CR2 register,
* - STOP and CLKEN bits in the USART_CR2 register,
* - SCEN bit in the USART_CR3 register,
* - HDSEL bit in the USART_CR3 register.
* This function also sets the UART/USART in IRDA mode (IREN bit).
* @note Macro IS_IRDA_INSTANCE(USARTx) can be used to check whether or not
* IrDA feature is supported by the USARTx instance.
* @note Call of this function is equivalent to following function call sequence :
* - Clear LINEN in CR2 using @ref LL_USART_DisableLIN() function
* - Clear CLKEN in CR2 using @ref LL_USART_DisableSCLKOutput() function
* - Clear SCEN in CR3 using @ref LL_USART_DisableSmartcard() function
* - Clear HDSEL in CR3 using @ref LL_USART_DisableHalfDuplex() function
* - Configure STOP in CR2 using @ref LL_USART_SetStopBitsLength() function
* - Set IREN in CR3 using @ref LL_USART_EnableIrda() function
* @note Other remaining configurations items related to Irda Mode
* (as Baud Rate, Word length, Power mode, ...) should be set using
* dedicated functions
* @rmtoll CR2 LINEN LL_USART_ConfigIrdaMode\n
* CR2 CLKEN LL_USART_ConfigIrdaMode\n
* CR2 STOP LL_USART_ConfigIrdaMode\n
* CR3 SCEN LL_USART_ConfigIrdaMode\n
* CR3 HDSEL LL_USART_ConfigIrdaMode\n
* CR3 IREN LL_USART_ConfigIrdaMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigIrdaMode(USART_TypeDef *USARTx)
{
/* In IRDA mode, the following bits must be kept cleared:
- LINEN, STOP and CLKEN bits in the USART_CR2 register,
- SCEN and HDSEL bits in the USART_CR3 register.
*/
CLEAR_BIT(USARTx->CR2, (USART_CR2_LINEN | USART_CR2_CLKEN | USART_CR2_STOP));
CLEAR_BIT(USARTx->CR3, (USART_CR3_SCEN | USART_CR3_HDSEL));
/* set the UART/USART in IRDA mode */
SET_BIT(USARTx->CR3, USART_CR3_IREN);
}
/**
* @brief Perform basic configuration of USART for enabling use in Multi processor Mode
* (several USARTs connected in a network, one of the USARTs can be the master,
* its TX output connected to the RX inputs of the other slaves USARTs).
* @note In MultiProcessor mode, the following bits must be kept cleared:
* - LINEN bit in the USART_CR2 register,
* - CLKEN bit in the USART_CR2 register,
* - SCEN bit in the USART_CR3 register,
* - IREN bit in the USART_CR3 register,
* - HDSEL bit in the USART_CR3 register.
* @note Call of this function is equivalent to following function call sequence :
* - Clear LINEN in CR2 using @ref LL_USART_DisableLIN() function
* - Clear CLKEN in CR2 using @ref LL_USART_DisableSCLKOutput() function
* - Clear SCEN in CR3 using @ref LL_USART_DisableSmartcard() function
* - Clear IREN in CR3 using @ref LL_USART_DisableIrda() function
* - Clear HDSEL in CR3 using @ref LL_USART_DisableHalfDuplex() function
* @note Other remaining configurations items related to Multi processor Mode
* (as Baud Rate, Wake Up Method, Node address, ...) should be set using
* dedicated functions
* @rmtoll CR2 LINEN LL_USART_ConfigMultiProcessMode\n
* CR2 CLKEN LL_USART_ConfigMultiProcessMode\n
* CR3 SCEN LL_USART_ConfigMultiProcessMode\n
* CR3 HDSEL LL_USART_ConfigMultiProcessMode\n
* CR3 IREN LL_USART_ConfigMultiProcessMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ConfigMultiProcessMode(USART_TypeDef *USARTx)
{
/* In Multi Processor mode, the following bits must be kept cleared:
- LINEN and CLKEN bits in the USART_CR2 register,
- IREN, SCEN and HDSEL bits in the USART_CR3 register.
*/
CLEAR_BIT(USARTx->CR2, (USART_CR2_LINEN | USART_CR2_CLKEN));
CLEAR_BIT(USARTx->CR3, (USART_CR3_SCEN | USART_CR3_HDSEL | USART_CR3_IREN));
}
/**
* @}
*/
/** @defgroup USART_LL_EF_FLAG_Management FLAG_Management
* @{
*/
/**
* @brief Check if the USART Parity Error Flag is set or not
* @rmtoll ISR PE LL_USART_IsActiveFlag_PE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_PE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_PE) == (USART_ISR_PE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Framing Error Flag is set or not
* @rmtoll ISR FE LL_USART_IsActiveFlag_FE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_FE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_FE) == (USART_ISR_FE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Noise error detected Flag is set or not
* @rmtoll ISR NE LL_USART_IsActiveFlag_NE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_NE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_NE) == (USART_ISR_NE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART OverRun Error Flag is set or not
* @rmtoll ISR ORE LL_USART_IsActiveFlag_ORE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_ORE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_ORE) == (USART_ISR_ORE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART IDLE line detected Flag is set or not
* @rmtoll ISR IDLE LL_USART_IsActiveFlag_IDLE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_IDLE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_IDLE) == (USART_ISR_IDLE)) ? 1UL : 0UL);
}
#define LL_USART_IsActiveFlag_RXNE LL_USART_IsActiveFlag_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Check if the USART Read Data Register or USART RX FIFO Not Empty Flag is set or not
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll ISR RXNE_RXFNE LL_USART_IsActiveFlag_RXNE_RXFNE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_RXNE_RXFNE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_RXNE_RXFNE) == (USART_ISR_RXNE_RXFNE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Transmission Complete Flag is set or not
* @rmtoll ISR TC LL_USART_IsActiveFlag_TC
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_TC(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_TC) == (USART_ISR_TC)) ? 1UL : 0UL);
}
#define LL_USART_IsActiveFlag_TXE LL_USART_IsActiveFlag_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Check if the USART Transmit Data Register Empty or USART TX FIFO Not Full Flag is set or not
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll ISR TXE_TXFNF LL_USART_IsActiveFlag_TXE_TXFNF
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_TXE_TXFNF(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_TXE_TXFNF) == (USART_ISR_TXE_TXFNF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART LIN Break Detection Flag is set or not
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll ISR LBDF LL_USART_IsActiveFlag_LBD
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_LBD(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_LBDF) == (USART_ISR_LBDF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART CTS interrupt Flag is set or not
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll ISR CTSIF LL_USART_IsActiveFlag_nCTS
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_nCTS(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_CTSIF) == (USART_ISR_CTSIF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART CTS Flag is set or not
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll ISR CTS LL_USART_IsActiveFlag_CTS
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_CTS(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_CTS) == (USART_ISR_CTS)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Receiver Time Out Flag is set or not
* @rmtoll ISR RTOF LL_USART_IsActiveFlag_RTO
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_RTO(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_RTOF) == (USART_ISR_RTOF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART End Of Block Flag is set or not
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll ISR EOBF LL_USART_IsActiveFlag_EOB
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_EOB(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_EOBF) == (USART_ISR_EOBF)) ? 1UL : 0UL);
}
/**
* @brief Check if the SPI Slave Underrun error flag is set or not
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @rmtoll ISR UDR LL_USART_IsActiveFlag_UDR
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_UDR(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_UDR) == (USART_ISR_UDR)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Auto-Baud Rate Error Flag is set or not
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll ISR ABRE LL_USART_IsActiveFlag_ABRE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_ABRE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_ABRE) == (USART_ISR_ABRE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Auto-Baud Rate Flag is set or not
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll ISR ABRF LL_USART_IsActiveFlag_ABR
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_ABR(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_ABRF) == (USART_ISR_ABRF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Busy Flag is set or not
* @rmtoll ISR BUSY LL_USART_IsActiveFlag_BUSY
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_BUSY(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_BUSY) == (USART_ISR_BUSY)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Character Match Flag is set or not
* @rmtoll ISR CMF LL_USART_IsActiveFlag_CM
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_CM(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_CMF) == (USART_ISR_CMF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Send Break Flag is set or not
* @rmtoll ISR SBKF LL_USART_IsActiveFlag_SBK
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_SBK(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_SBKF) == (USART_ISR_SBKF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Receive Wake Up from mute mode Flag is set or not
* @rmtoll ISR RWU LL_USART_IsActiveFlag_RWU
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_RWU(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_RWU) == (USART_ISR_RWU)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Wake Up from stop mode Flag is set or not
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll ISR WUF LL_USART_IsActiveFlag_WKUP
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_WKUP(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_WUF) == (USART_ISR_WUF)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Transmit Enable Acknowledge Flag is set or not
* @rmtoll ISR TEACK LL_USART_IsActiveFlag_TEACK
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_TEACK(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_TEACK) == (USART_ISR_TEACK)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Receive Enable Acknowledge Flag is set or not
* @rmtoll ISR REACK LL_USART_IsActiveFlag_REACK
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_REACK(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_REACK) == (USART_ISR_REACK)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART TX FIFO Empty Flag is set or not
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll ISR TXFE LL_USART_IsActiveFlag_TXFE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_TXFE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_TXFE) == (USART_ISR_TXFE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART RX FIFO Full Flag is set or not
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll ISR RXFF LL_USART_IsActiveFlag_RXFF
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_RXFF(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_RXFF) == (USART_ISR_RXFF)) ? 1UL : 0UL);
}
/**
* @brief Check if the Smartcard Transmission Complete Before Guard Time Flag is set or not
* @rmtoll ISR TCBGT LL_USART_IsActiveFlag_TCBGT
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_TCBGT(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_TCBGT) == (USART_ISR_TCBGT)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART TX FIFO Threshold Flag is set or not
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll ISR TXFT LL_USART_IsActiveFlag_TXFT
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_TXFT(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_TXFT) == (USART_ISR_TXFT)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART RX FIFO Threshold Flag is set or not
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll ISR RXFT LL_USART_IsActiveFlag_RXFT
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsActiveFlag_RXFT(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->ISR, USART_ISR_RXFT) == (USART_ISR_RXFT)) ? 1UL : 0UL);
}
/**
* @brief Clear Parity Error Flag
* @rmtoll ICR PECF LL_USART_ClearFlag_PE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_PE(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_PECF);
}
/**
* @brief Clear Framing Error Flag
* @rmtoll ICR FECF LL_USART_ClearFlag_FE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_FE(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_FECF);
}
/**
* @brief Clear Noise Error detected Flag
* @rmtoll ICR NECF LL_USART_ClearFlag_NE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_NE(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_NECF);
}
/**
* @brief Clear OverRun Error Flag
* @rmtoll ICR ORECF LL_USART_ClearFlag_ORE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_ORE(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_ORECF);
}
/**
* @brief Clear IDLE line detected Flag
* @rmtoll ICR IDLECF LL_USART_ClearFlag_IDLE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_IDLE(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_IDLECF);
}
/**
* @brief Clear TX FIFO Empty Flag
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll ICR TXFECF LL_USART_ClearFlag_TXFE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_TXFE(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_TXFECF);
}
/**
* @brief Clear Transmission Complete Flag
* @rmtoll ICR TCCF LL_USART_ClearFlag_TC
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_TC(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_TCCF);
}
/**
* @brief Clear Smartcard Transmission Complete Before Guard Time Flag
* @rmtoll ICR TCBGTCF LL_USART_ClearFlag_TCBGT
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_TCBGT(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_TCBGTCF);
}
/**
* @brief Clear LIN Break Detection Flag
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll ICR LBDCF LL_USART_ClearFlag_LBD
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_LBD(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_LBDCF);
}
/**
* @brief Clear CTS Interrupt Flag
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll ICR CTSCF LL_USART_ClearFlag_nCTS
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_nCTS(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_CTSCF);
}
/**
* @brief Clear Receiver Time Out Flag
* @rmtoll ICR RTOCF LL_USART_ClearFlag_RTO
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_RTO(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_RTOCF);
}
/**
* @brief Clear End Of Block Flag
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll ICR EOBCF LL_USART_ClearFlag_EOB
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_EOB(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_EOBCF);
}
/**
* @brief Clear SPI Slave Underrun Flag
* @note Macro IS_UART_SPI_SLAVE_INSTANCE(USARTx) can be used to check whether or not
* SPI Slave mode feature is supported by the USARTx instance.
* @rmtoll ICR UDRCF LL_USART_ClearFlag_UDR
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_UDR(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_UDRCF);
}
/**
* @brief Clear Character Match Flag
* @rmtoll ICR CMCF LL_USART_ClearFlag_CM
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_CM(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_CMCF);
}
/**
* @brief Clear Wake Up from stop mode Flag
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll ICR WUCF LL_USART_ClearFlag_WKUP
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_ClearFlag_WKUP(USART_TypeDef *USARTx)
{
WRITE_REG(USARTx->ICR, USART_ICR_WUCF);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_IT_Management IT_Management
* @{
*/
/**
* @brief Enable IDLE Interrupt
* @rmtoll CR1 IDLEIE LL_USART_EnableIT_IDLE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_IDLE(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_IDLEIE);
}
#define LL_USART_EnableIT_RXNE LL_USART_EnableIT_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Enable RX Not Empty and RX FIFO Not Empty Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 RXNEIE_RXFNEIE LL_USART_EnableIT_RXNE_RXFNE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_RXNE_RXFNE(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_RXNEIE_RXFNEIE);
}
/**
* @brief Enable Transmission Complete Interrupt
* @rmtoll CR1 TCIE LL_USART_EnableIT_TC
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_TC(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_TCIE);
}
#define LL_USART_EnableIT_TXE LL_USART_EnableIT_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Enable TX Empty and TX FIFO Not Full Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 TXEIE_TXFNFIE LL_USART_EnableIT_TXE_TXFNF
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_TXE_TXFNF(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_TXEIE_TXFNFIE);
}
/**
* @brief Enable Parity Error Interrupt
* @rmtoll CR1 PEIE LL_USART_EnableIT_PE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_PE(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_PEIE);
}
/**
* @brief Enable Character Match Interrupt
* @rmtoll CR1 CMIE LL_USART_EnableIT_CM
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_CM(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_CMIE);
}
/**
* @brief Enable Receiver Timeout Interrupt
* @rmtoll CR1 RTOIE LL_USART_EnableIT_RTO
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_RTO(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_RTOIE);
}
/**
* @brief Enable End Of Block Interrupt
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR1 EOBIE LL_USART_EnableIT_EOB
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_EOB(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_EOBIE);
}
/**
* @brief Enable TX FIFO Empty Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 TXFEIE LL_USART_EnableIT_TXFE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_TXFE(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_TXFEIE);
}
/**
* @brief Enable RX FIFO Full Interrupt
* @rmtoll CR1 RXFFIE LL_USART_EnableIT_RXFF
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_RXFF(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR1, USART_CR1_RXFFIE);
}
/**
* @brief Enable LIN Break Detection Interrupt
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LBDIE LL_USART_EnableIT_LBD
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_LBD(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR2, USART_CR2_LBDIE);
}
/**
* @brief Enable Error Interrupt
* @note When set, Error Interrupt Enable Bit is enabling interrupt generation in case of a framing
* error, overrun error or noise flag (FE=1 or ORE=1 or NF=1 in the USARTx_ISR register).
* 0: Interrupt is inhibited
* 1: An interrupt is generated when FE=1 or ORE=1 or NF=1 in the USARTx_ISR register.
* @rmtoll CR3 EIE LL_USART_EnableIT_ERROR
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_ERROR(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_EIE);
}
/**
* @brief Enable CTS Interrupt
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 CTSIE LL_USART_EnableIT_CTS
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_CTS(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_CTSIE);
}
/**
* @brief Enable Wake Up from Stop Mode Interrupt
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR3 WUFIE LL_USART_EnableIT_WKUP
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_WKUP(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_WUFIE);
}
/**
* @brief Enable TX FIFO Threshold Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 TXFTIE LL_USART_EnableIT_TXFT
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_TXFT(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_TXFTIE);
}
/**
* @brief Enable Smartcard Transmission Complete Before Guard Time Interrupt
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 TCBGTIE LL_USART_EnableIT_TCBGT
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_TCBGT(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_TCBGTIE);
}
/**
* @brief Enable RX FIFO Threshold Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 RXFTIE LL_USART_EnableIT_RXFT
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableIT_RXFT(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_RXFTIE);
}
/**
* @brief Disable IDLE Interrupt
* @rmtoll CR1 IDLEIE LL_USART_DisableIT_IDLE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_IDLE(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_IDLEIE);
}
#define LL_USART_DisableIT_RXNE LL_USART_DisableIT_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Disable RX Not Empty and RX FIFO Not Empty Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 RXNEIE_RXFNEIE LL_USART_DisableIT_RXNE_RXFNE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_RXNE_RXFNE(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_RXNEIE_RXFNEIE);
}
/**
* @brief Disable Transmission Complete Interrupt
* @rmtoll CR1 TCIE LL_USART_DisableIT_TC
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_TC(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_TCIE);
}
#define LL_USART_DisableIT_TXE LL_USART_DisableIT_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Disable TX Empty and TX FIFO Not Full Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 TXEIE_TXFNFIE LL_USART_DisableIT_TXE_TXFNF
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_TXE_TXFNF(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_TXEIE_TXFNFIE);
}
/**
* @brief Disable Parity Error Interrupt
* @rmtoll CR1 PEIE LL_USART_DisableIT_PE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_PE(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_PEIE);
}
/**
* @brief Disable Character Match Interrupt
* @rmtoll CR1 CMIE LL_USART_DisableIT_CM
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_CM(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_CMIE);
}
/**
* @brief Disable Receiver Timeout Interrupt
* @rmtoll CR1 RTOIE LL_USART_DisableIT_RTO
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_RTO(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_RTOIE);
}
/**
* @brief Disable End Of Block Interrupt
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR1 EOBIE LL_USART_DisableIT_EOB
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_EOB(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_EOBIE);
}
/**
* @brief Disable TX FIFO Empty Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 TXFEIE LL_USART_DisableIT_TXFE
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_TXFE(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_TXFEIE);
}
/**
* @brief Disable RX FIFO Full Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 RXFFIE LL_USART_DisableIT_RXFF
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_RXFF(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR1, USART_CR1_RXFFIE);
}
/**
* @brief Disable LIN Break Detection Interrupt
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LBDIE LL_USART_DisableIT_LBD
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_LBD(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR2, USART_CR2_LBDIE);
}
/**
* @brief Disable Error Interrupt
* @note When set, Error Interrupt Enable Bit is enabling interrupt generation in case of a framing
* error, overrun error or noise flag (FE=1 or ORE=1 or NF=1 in the USARTx_ISR register).
* 0: Interrupt is inhibited
* 1: An interrupt is generated when FE=1 or ORE=1 or NF=1 in the USARTx_ISR register.
* @rmtoll CR3 EIE LL_USART_DisableIT_ERROR
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_ERROR(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_EIE);
}
/**
* @brief Disable CTS Interrupt
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 CTSIE LL_USART_DisableIT_CTS
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_CTS(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_CTSIE);
}
/**
* @brief Disable Wake Up from Stop Mode Interrupt
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR3 WUFIE LL_USART_DisableIT_WKUP
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_WKUP(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_WUFIE);
}
/**
* @brief Disable TX FIFO Threshold Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 TXFTIE LL_USART_DisableIT_TXFT
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_TXFT(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_TXFTIE);
}
/**
* @brief Disable Smartcard Transmission Complete Before Guard Time Interrupt
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 TCBGTIE LL_USART_DisableIT_TCBGT
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_TCBGT(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_TCBGTIE);
}
/**
* @brief Disable RX FIFO Threshold Interrupt
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 RXFTIE LL_USART_DisableIT_RXFT
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableIT_RXFT(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_RXFTIE);
}
/**
* @brief Check if the USART IDLE Interrupt source is enabled or disabled.
* @rmtoll CR1 IDLEIE LL_USART_IsEnabledIT_IDLE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_IDLE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_IDLEIE) == (USART_CR1_IDLEIE)) ? 1UL : 0UL);
}
#define LL_USART_IsEnabledIT_RXNE LL_USART_IsEnabledIT_RXNE_RXFNE /* Redefinition for legacy purpose */
/**
* @brief Check if the USART RX Not Empty and USART RX FIFO Not Empty Interrupt is enabled or disabled.
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 RXNEIE_RXFNEIE LL_USART_IsEnabledIT_RXNE_RXFNE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_RXNE_RXFNE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_RXNEIE_RXFNEIE) == (USART_CR1_RXNEIE_RXFNEIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Transmission Complete Interrupt is enabled or disabled.
* @rmtoll CR1 TCIE LL_USART_IsEnabledIT_TC
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_TC(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_TCIE) == (USART_CR1_TCIE)) ? 1UL : 0UL);
}
#define LL_USART_IsEnabledIT_TXE LL_USART_IsEnabledIT_TXE_TXFNF /* Redefinition for legacy purpose */
/**
* @brief Check if the USART TX Empty and USART TX FIFO Not Full Interrupt is enabled or disabled
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 TXEIE_TXFNFIE LL_USART_IsEnabledIT_TXE_TXFNF
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_TXE_TXFNF(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_TXEIE_TXFNFIE) == (USART_CR1_TXEIE_TXFNFIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Parity Error Interrupt is enabled or disabled.
* @rmtoll CR1 PEIE LL_USART_IsEnabledIT_PE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_PE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_PEIE) == (USART_CR1_PEIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Character Match Interrupt is enabled or disabled.
* @rmtoll CR1 CMIE LL_USART_IsEnabledIT_CM
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_CM(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_CMIE) == (USART_CR1_CMIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Receiver Timeout Interrupt is enabled or disabled.
* @rmtoll CR1 RTOIE LL_USART_IsEnabledIT_RTO
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_RTO(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_RTOIE) == (USART_CR1_RTOIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART End Of Block Interrupt is enabled or disabled.
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR1 EOBIE LL_USART_IsEnabledIT_EOB
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_EOB(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_EOBIE) == (USART_CR1_EOBIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART TX FIFO Empty Interrupt is enabled or disabled
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 TXFEIE LL_USART_IsEnabledIT_TXFE
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_TXFE(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_TXFEIE) == (USART_CR1_TXFEIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART RX FIFO Full Interrupt is enabled or disabled
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR1 RXFFIE LL_USART_IsEnabledIT_RXFF
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_RXFF(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR1, USART_CR1_RXFFIE) == (USART_CR1_RXFFIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART LIN Break Detection Interrupt is enabled or disabled.
* @note Macro IS_UART_LIN_INSTANCE(USARTx) can be used to check whether or not
* LIN feature is supported by the USARTx instance.
* @rmtoll CR2 LBDIE LL_USART_IsEnabledIT_LBD
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_LBD(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR2, USART_CR2_LBDIE) == (USART_CR2_LBDIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Error Interrupt is enabled or disabled.
* @rmtoll CR3 EIE LL_USART_IsEnabledIT_ERROR
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_ERROR(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_EIE) == (USART_CR3_EIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART CTS Interrupt is enabled or disabled.
* @note Macro IS_UART_HWFLOW_INSTANCE(USARTx) can be used to check whether or not
* Hardware Flow control feature is supported by the USARTx instance.
* @rmtoll CR3 CTSIE LL_USART_IsEnabledIT_CTS
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_CTS(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_CTSIE) == (USART_CR3_CTSIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the USART Wake Up from Stop Mode Interrupt is enabled or disabled.
* @note Macro IS_UART_WAKEUP_FROMSTOP_INSTANCE(USARTx) can be used to check whether or not
* Wake-up from Stop mode feature is supported by the USARTx instance.
* @rmtoll CR3 WUFIE LL_USART_IsEnabledIT_WKUP
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_WKUP(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_WUFIE) == (USART_CR3_WUFIE)) ? 1UL : 0UL);
}
/**
* @brief Check if USART TX FIFO Threshold Interrupt is enabled or disabled
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 TXFTIE LL_USART_IsEnabledIT_TXFT
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_TXFT(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_TXFTIE) == (USART_CR3_TXFTIE)) ? 1UL : 0UL);
}
/**
* @brief Check if the Smartcard Transmission Complete Before Guard Time Interrupt is enabled or disabled.
* @note Macro IS_SMARTCARD_INSTANCE(USARTx) can be used to check whether or not
* Smartcard feature is supported by the USARTx instance.
* @rmtoll CR3 TCBGTIE LL_USART_IsEnabledIT_TCBGT
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_TCBGT(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_TCBGTIE) == (USART_CR3_TCBGTIE)) ? 1UL : 0UL);
}
/**
* @brief Check if USART RX FIFO Threshold Interrupt is enabled or disabled
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll CR3 RXFTIE LL_USART_IsEnabledIT_RXFT
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledIT_RXFT(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_RXFTIE) == (USART_CR3_RXFTIE)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_DMA_Management DMA_Management
* @{
*/
/**
* @brief Enable DMA Mode for reception
* @rmtoll CR3 DMAR LL_USART_EnableDMAReq_RX
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableDMAReq_RX(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_DMAR);
}
/**
* @brief Disable DMA Mode for reception
* @rmtoll CR3 DMAR LL_USART_DisableDMAReq_RX
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableDMAReq_RX(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_DMAR);
}
/**
* @brief Check if DMA Mode is enabled for reception
* @rmtoll CR3 DMAR LL_USART_IsEnabledDMAReq_RX
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledDMAReq_RX(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_DMAR) == (USART_CR3_DMAR)) ? 1UL : 0UL);
}
/**
* @brief Enable DMA Mode for transmission
* @rmtoll CR3 DMAT LL_USART_EnableDMAReq_TX
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableDMAReq_TX(USART_TypeDef *USARTx)
{
ATOMIC_SET_BIT(USARTx->CR3, USART_CR3_DMAT);
}
/**
* @brief Disable DMA Mode for transmission
* @rmtoll CR3 DMAT LL_USART_DisableDMAReq_TX
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableDMAReq_TX(USART_TypeDef *USARTx)
{
ATOMIC_CLEAR_BIT(USARTx->CR3, USART_CR3_DMAT);
}
/**
* @brief Check if DMA Mode is enabled for transmission
* @rmtoll CR3 DMAT LL_USART_IsEnabledDMAReq_TX
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledDMAReq_TX(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_DMAT) == (USART_CR3_DMAT)) ? 1UL : 0UL);
}
/**
* @brief Enable DMA Disabling on Reception Error
* @rmtoll CR3 DDRE LL_USART_EnableDMADeactOnRxErr
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_EnableDMADeactOnRxErr(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->CR3, USART_CR3_DDRE);
}
/**
* @brief Disable DMA Disabling on Reception Error
* @rmtoll CR3 DDRE LL_USART_DisableDMADeactOnRxErr
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_DisableDMADeactOnRxErr(USART_TypeDef *USARTx)
{
CLEAR_BIT(USARTx->CR3, USART_CR3_DDRE);
}
/**
* @brief Indicate if DMA Disabling on Reception Error is disabled
* @rmtoll CR3 DDRE LL_USART_IsEnabledDMADeactOnRxErr
* @param USARTx USART Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_USART_IsEnabledDMADeactOnRxErr(const USART_TypeDef *USARTx)
{
return ((READ_BIT(USARTx->CR3, USART_CR3_DDRE) == (USART_CR3_DDRE)) ? 1UL : 0UL);
}
/**
* @brief Get the data register address used for DMA transfer
* @rmtoll RDR RDR LL_USART_DMA_GetRegAddr\n
* @rmtoll TDR TDR LL_USART_DMA_GetRegAddr
* @param USARTx USART Instance
* @param Direction This parameter can be one of the following values:
* @arg @ref LL_USART_DMA_REG_DATA_TRANSMIT
* @arg @ref LL_USART_DMA_REG_DATA_RECEIVE
* @retval Address of data register
*/
__STATIC_INLINE uint32_t LL_USART_DMA_GetRegAddr(const USART_TypeDef *USARTx, uint32_t Direction)
{
uint32_t data_reg_addr;
if (Direction == LL_USART_DMA_REG_DATA_TRANSMIT)
{
/* return address of TDR register */
data_reg_addr = (uint32_t) &(USARTx->TDR);
}
else
{
/* return address of RDR register */
data_reg_addr = (uint32_t) &(USARTx->RDR);
}
return data_reg_addr;
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Data_Management Data_Management
* @{
*/
/**
* @brief Read Receiver Data register (Receive Data value, 8 bits)
* @rmtoll RDR RDR LL_USART_ReceiveData8
* @param USARTx USART Instance
* @retval Value between Min_Data=0x00 and Max_Data=0xFF
*/
__STATIC_INLINE uint8_t LL_USART_ReceiveData8(const USART_TypeDef *USARTx)
{
return (uint8_t)(READ_BIT(USARTx->RDR, USART_RDR_RDR) & 0xFFU);
}
/**
* @brief Read Receiver Data register (Receive Data value, 9 bits)
* @rmtoll RDR RDR LL_USART_ReceiveData9
* @param USARTx USART Instance
* @retval Value between Min_Data=0x00 and Max_Data=0x1FF
*/
__STATIC_INLINE uint16_t LL_USART_ReceiveData9(const USART_TypeDef *USARTx)
{
return (uint16_t)(READ_BIT(USARTx->RDR, USART_RDR_RDR));
}
/**
* @brief Write in Transmitter Data Register (Transmit Data value, 8 bits)
* @rmtoll TDR TDR LL_USART_TransmitData8
* @param USARTx USART Instance
* @param Value between Min_Data=0x00 and Max_Data=0xFF
* @retval None
*/
__STATIC_INLINE void LL_USART_TransmitData8(USART_TypeDef *USARTx, uint8_t Value)
{
USARTx->TDR = Value;
}
/**
* @brief Write in Transmitter Data Register (Transmit Data value, 9 bits)
* @rmtoll TDR TDR LL_USART_TransmitData9
* @param USARTx USART Instance
* @param Value between Min_Data=0x00 and Max_Data=0x1FF
* @retval None
*/
__STATIC_INLINE void LL_USART_TransmitData9(USART_TypeDef *USARTx, uint16_t Value)
{
USARTx->TDR = (uint16_t)(Value & 0x1FFUL);
}
/**
* @}
*/
/** @defgroup USART_LL_EF_Execution Execution
* @{
*/
/**
* @brief Request an Automatic Baud Rate measurement on next received data frame
* @note Macro IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(USARTx) can be used to check whether or not
* Auto Baud Rate detection feature is supported by the USARTx instance.
* @rmtoll RQR ABRRQ LL_USART_RequestAutoBaudRate
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_RequestAutoBaudRate(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->RQR, (uint16_t)USART_RQR_ABRRQ);
}
/**
* @brief Request Break sending
* @rmtoll RQR SBKRQ LL_USART_RequestBreakSending
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_RequestBreakSending(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->RQR, (uint16_t)USART_RQR_SBKRQ);
}
/**
* @brief Put USART in mute mode and set the RWU flag
* @rmtoll RQR MMRQ LL_USART_RequestEnterMuteMode
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_RequestEnterMuteMode(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->RQR, (uint16_t)USART_RQR_MMRQ);
}
/**
* @brief Request a Receive Data and FIFO flush
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @note Allows to discard the received data without reading them, and avoid an overrun
* condition.
* @rmtoll RQR RXFRQ LL_USART_RequestRxDataFlush
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_RequestRxDataFlush(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->RQR, (uint16_t)USART_RQR_RXFRQ);
}
/**
* @brief Request a Transmit data and FIFO flush
* @note Macro IS_UART_FIFO_INSTANCE(USARTx) can be used to check whether or not
* FIFO mode feature is supported by the USARTx instance.
* @rmtoll RQR TXFRQ LL_USART_RequestTxDataFlush
* @param USARTx USART Instance
* @retval None
*/
__STATIC_INLINE void LL_USART_RequestTxDataFlush(USART_TypeDef *USARTx)
{
SET_BIT(USARTx->RQR, (uint16_t)USART_RQR_TXFRQ);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup USART_LL_EF_Init Initialization and de-initialization functions
* @{
*/
ErrorStatus LL_USART_DeInit(const USART_TypeDef *USARTx);
ErrorStatus LL_USART_Init(USART_TypeDef *USARTx, const LL_USART_InitTypeDef *USART_InitStruct);
void LL_USART_StructInit(LL_USART_InitTypeDef *USART_InitStruct);
ErrorStatus LL_USART_ClockInit(USART_TypeDef *USARTx, const LL_USART_ClockInitTypeDef *USART_ClockInitStruct);
void LL_USART_ClockStructInit(LL_USART_ClockInitTypeDef *USART_ClockInitStruct);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* USART1 || USART2 || USART3 || UART4 || UART5 */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_USART_H */
| 175,063 | C | 38.787273 | 214 | 0.640215 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_gpio.h | /**
******************************************************************************
* @file stm32g4xx_ll_gpio.h
* @author MCD Application Team
* @brief Header file of GPIO LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_GPIO_H
#define STM32G4xx_LL_GPIO_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined (GPIOA) || defined (GPIOB) || defined (GPIOC) || defined (GPIOD) || defined (GPIOE) || defined (GPIOF) || defined (GPIOG)
/** @defgroup GPIO_LL GPIO
* @{
*/
/** MISRA C:2012 deviation rule has been granted for following rules:
* Rule-18.1_d - Medium: Array pointer `GPIOx' is accessed with index [..,..]
* which may be out of array bounds [..,UNKNOWN] in following APIs:
* LL_GPIO_GetAFPin_0_7
* LL_GPIO_SetAFPin_0_7
* LL_GPIO_SetAFPin_8_15
* LL_GPIO_GetAFPin_8_15
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup GPIO_LL_Private_Macros GPIO Private Macros
* @{
*/
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported types ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup GPIO_LL_ES_INIT GPIO Exported Init structures
* @{
*/
/**
* @brief LL GPIO Init Structure definition
*/
typedef struct
{
uint32_t Pin; /*!< Specifies the GPIO pins to be configured.
This parameter can be any value of @ref GPIO_LL_EC_PIN */
uint32_t Mode; /*!< Specifies the operating mode for the selected pins.
This parameter can be a value of @ref GPIO_LL_EC_MODE.
GPIO HW configuration can be modified afterwards using unitary function @ref LL_GPIO_SetPinMode().*/
uint32_t Speed; /*!< Specifies the speed for the selected pins.
This parameter can be a value of @ref GPIO_LL_EC_SPEED.
GPIO HW configuration can be modified afterwards using unitary function @ref LL_GPIO_SetPinSpeed().*/
uint32_t OutputType; /*!< Specifies the operating output type for the selected pins.
This parameter can be a value of @ref GPIO_LL_EC_OUTPUT.
GPIO HW configuration can be modified afterwards using unitary function @ref LL_GPIO_SetPinOutputType().*/
uint32_t Pull; /*!< Specifies the operating Pull-up/Pull down for the selected pins.
This parameter can be a value of @ref GPIO_LL_EC_PULL.
GPIO HW configuration can be modified afterwards using unitary function @ref LL_GPIO_SetPinPull().*/
uint32_t Alternate; /*!< Specifies the Peripheral to be connected to the selected pins.
This parameter can be a value of @ref GPIO_LL_EC_AF.
GPIO HW configuration can be modified afterwards using unitary function @ref LL_GPIO_SetAFPin_0_7() and LL_GPIO_SetAFPin_8_15().*/
} LL_GPIO_InitTypeDef;
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/* Exported constants --------------------------------------------------------*/
/** @defgroup GPIO_LL_Exported_Constants GPIO Exported Constants
* @{
*/
/** @defgroup GPIO_LL_EC_PIN PIN
* @{
*/
#define LL_GPIO_PIN_0 GPIO_BSRR_BS0 /*!< Select pin 0 */
#define LL_GPIO_PIN_1 GPIO_BSRR_BS1 /*!< Select pin 1 */
#define LL_GPIO_PIN_2 GPIO_BSRR_BS2 /*!< Select pin 2 */
#define LL_GPIO_PIN_3 GPIO_BSRR_BS3 /*!< Select pin 3 */
#define LL_GPIO_PIN_4 GPIO_BSRR_BS4 /*!< Select pin 4 */
#define LL_GPIO_PIN_5 GPIO_BSRR_BS5 /*!< Select pin 5 */
#define LL_GPIO_PIN_6 GPIO_BSRR_BS6 /*!< Select pin 6 */
#define LL_GPIO_PIN_7 GPIO_BSRR_BS7 /*!< Select pin 7 */
#define LL_GPIO_PIN_8 GPIO_BSRR_BS8 /*!< Select pin 8 */
#define LL_GPIO_PIN_9 GPIO_BSRR_BS9 /*!< Select pin 9 */
#define LL_GPIO_PIN_10 GPIO_BSRR_BS10 /*!< Select pin 10 */
#define LL_GPIO_PIN_11 GPIO_BSRR_BS11 /*!< Select pin 11 */
#define LL_GPIO_PIN_12 GPIO_BSRR_BS12 /*!< Select pin 12 */
#define LL_GPIO_PIN_13 GPIO_BSRR_BS13 /*!< Select pin 13 */
#define LL_GPIO_PIN_14 GPIO_BSRR_BS14 /*!< Select pin 14 */
#define LL_GPIO_PIN_15 GPIO_BSRR_BS15 /*!< Select pin 15 */
#define LL_GPIO_PIN_ALL (GPIO_BSRR_BS0 | GPIO_BSRR_BS1 | GPIO_BSRR_BS2 | \
GPIO_BSRR_BS3 | GPIO_BSRR_BS4 | GPIO_BSRR_BS5 | \
GPIO_BSRR_BS6 | GPIO_BSRR_BS7 | GPIO_BSRR_BS8 | \
GPIO_BSRR_BS9 | GPIO_BSRR_BS10 | GPIO_BSRR_BS11 | \
GPIO_BSRR_BS12 | GPIO_BSRR_BS13 | GPIO_BSRR_BS14 | \
GPIO_BSRR_BS15) /*!< Select all pins */
/**
* @}
*/
/** @defgroup GPIO_LL_EC_MODE Mode
* @{
*/
#define LL_GPIO_MODE_INPUT (0x00000000U) /*!< Select input mode */
#define LL_GPIO_MODE_OUTPUT GPIO_MODER_MODE0_0 /*!< Select output mode */
#define LL_GPIO_MODE_ALTERNATE GPIO_MODER_MODE0_1 /*!< Select alternate function mode */
#define LL_GPIO_MODE_ANALOG GPIO_MODER_MODE0 /*!< Select analog mode */
/**
* @}
*/
/** @defgroup GPIO_LL_EC_OUTPUT Output Type
* @{
*/
#define LL_GPIO_OUTPUT_PUSHPULL (0x00000000U) /*!< Select push-pull as output type */
#define LL_GPIO_OUTPUT_OPENDRAIN GPIO_OTYPER_OT0 /*!< Select open-drain as output type */
/**
* @}
*/
/** @defgroup GPIO_LL_EC_SPEED Output Speed
* @{
*/
#define LL_GPIO_SPEED_FREQ_LOW (0x00000000U) /*!< Select I/O low output speed */
#define LL_GPIO_SPEED_FREQ_MEDIUM GPIO_OSPEEDR_OSPEED0_0 /*!< Select I/O medium output speed */
#define LL_GPIO_SPEED_FREQ_HIGH GPIO_OSPEEDR_OSPEED0_1 /*!< Select I/O fast output speed */
#define LL_GPIO_SPEED_FREQ_VERY_HIGH GPIO_OSPEEDR_OSPEED0 /*!< Select I/O high output speed */
/**
* @}
*/
#define LL_GPIO_SPEED_LOW LL_GPIO_SPEED_FREQ_LOW
#define LL_GPIO_SPEED_MEDIUM LL_GPIO_SPEED_FREQ_MEDIUM
#define LL_GPIO_SPEED_FAST LL_GPIO_SPEED_FREQ_HIGH
#define LL_GPIO_SPEED_HIGH LL_GPIO_SPEED_FREQ_VERY_HIGH
/** @defgroup GPIO_LL_EC_PULL Pull Up Pull Down
* @{
*/
#define LL_GPIO_PULL_NO (0x00000000U) /*!< Select I/O no pull */
#define LL_GPIO_PULL_UP GPIO_PUPDR_PUPD0_0 /*!< Select I/O pull up */
#define LL_GPIO_PULL_DOWN GPIO_PUPDR_PUPD0_1 /*!< Select I/O pull down */
/**
* @}
*/
/** @defgroup GPIO_LL_EC_AF Alternate Function
* @{
*/
#define LL_GPIO_AF_0 (0x0000000U) /*!< Select alternate function 0 */
#define LL_GPIO_AF_1 (0x0000001U) /*!< Select alternate function 1 */
#define LL_GPIO_AF_2 (0x0000002U) /*!< Select alternate function 2 */
#define LL_GPIO_AF_3 (0x0000003U) /*!< Select alternate function 3 */
#define LL_GPIO_AF_4 (0x0000004U) /*!< Select alternate function 4 */
#define LL_GPIO_AF_5 (0x0000005U) /*!< Select alternate function 5 */
#define LL_GPIO_AF_6 (0x0000006U) /*!< Select alternate function 6 */
#define LL_GPIO_AF_7 (0x0000007U) /*!< Select alternate function 7 */
#define LL_GPIO_AF_8 (0x0000008U) /*!< Select alternate function 8 */
#define LL_GPIO_AF_9 (0x0000009U) /*!< Select alternate function 9 */
#define LL_GPIO_AF_10 (0x000000AU) /*!< Select alternate function 10 */
#define LL_GPIO_AF_11 (0x000000BU) /*!< Select alternate function 11 */
#define LL_GPIO_AF_12 (0x000000CU) /*!< Select alternate function 12 */
#define LL_GPIO_AF_13 (0x000000DU) /*!< Select alternate function 13 */
#define LL_GPIO_AF_14 (0x000000EU) /*!< Select alternate function 14 */
#define LL_GPIO_AF_15 (0x000000FU) /*!< Select alternate function 15 */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup GPIO_LL_Exported_Macros GPIO Exported Macros
* @{
*/
/** @defgroup GPIO_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in GPIO register
* @param __INSTANCE__ GPIO Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_GPIO_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG(__INSTANCE__->__REG__, (__VALUE__))
/**
* @brief Read a value in GPIO register
* @param __INSTANCE__ GPIO Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_GPIO_ReadReg(__INSTANCE__, __REG__) READ_REG(__INSTANCE__->__REG__)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup GPIO_LL_Exported_Functions GPIO Exported Functions
* @{
*/
/** @defgroup GPIO_LL_EF_Port_Configuration Port Configuration
* @{
*/
/**
* @brief Configure gpio mode for a dedicated pin on dedicated port.
* @note I/O mode can be Input mode, General purpose output, Alternate function mode or Analog.
* @note Warning: only one pin can be passed as parameter.
* @rmtoll MODER MODEy LL_GPIO_SetPinMode
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @param Mode This parameter can be one of the following values:
* @arg @ref LL_GPIO_MODE_INPUT
* @arg @ref LL_GPIO_MODE_OUTPUT
* @arg @ref LL_GPIO_MODE_ALTERNATE
* @arg @ref LL_GPIO_MODE_ANALOG
* @retval None
*/
__STATIC_INLINE void LL_GPIO_SetPinMode(GPIO_TypeDef *GPIOx, uint32_t Pin, uint32_t Mode)
{
MODIFY_REG(GPIOx->MODER, (GPIO_MODER_MODE0 << (POSITION_VAL(Pin) * 2U)), (Mode << (POSITION_VAL(Pin) * 2U)));
}
/**
* @brief Return gpio mode for a dedicated pin on dedicated port.
* @note I/O mode can be Input mode, General purpose output, Alternate function mode or Analog.
* @note Warning: only one pin can be passed as parameter.
* @rmtoll MODER MODEy LL_GPIO_GetPinMode
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @retval Returned value can be one of the following values:
* @arg @ref LL_GPIO_MODE_INPUT
* @arg @ref LL_GPIO_MODE_OUTPUT
* @arg @ref LL_GPIO_MODE_ALTERNATE
* @arg @ref LL_GPIO_MODE_ANALOG
*/
__STATIC_INLINE uint32_t LL_GPIO_GetPinMode(GPIO_TypeDef *GPIOx, uint32_t Pin)
{
return (uint32_t)(READ_BIT(GPIOx->MODER,
(GPIO_MODER_MODE0 << (POSITION_VAL(Pin) * 2U))) >> (POSITION_VAL(Pin) * 2U));
}
/**
* @brief Configure gpio output type for several pins on dedicated port.
* @note Output type as to be set when gpio pin is in output or
* alternate modes. Possible type are Push-pull or Open-drain.
* @rmtoll OTYPER OTy LL_GPIO_SetPinOutputType
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @param OutputType This parameter can be one of the following values:
* @arg @ref LL_GPIO_OUTPUT_PUSHPULL
* @arg @ref LL_GPIO_OUTPUT_OPENDRAIN
* @retval None
*/
__STATIC_INLINE void LL_GPIO_SetPinOutputType(GPIO_TypeDef *GPIOx, uint32_t PinMask, uint32_t OutputType)
{
MODIFY_REG(GPIOx->OTYPER, PinMask, (PinMask * OutputType));
}
/**
* @brief Return gpio output type for several pins on dedicated port.
* @note Output type as to be set when gpio pin is in output or
* alternate modes. Possible type are Push-pull or Open-drain.
* @note Warning: only one pin can be passed as parameter.
* @rmtoll OTYPER OTy LL_GPIO_GetPinOutputType
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval Returned value can be one of the following values:
* @arg @ref LL_GPIO_OUTPUT_PUSHPULL
* @arg @ref LL_GPIO_OUTPUT_OPENDRAIN
*/
__STATIC_INLINE uint32_t LL_GPIO_GetPinOutputType(GPIO_TypeDef *GPIOx, uint32_t Pin)
{
return (uint32_t)(READ_BIT(GPIOx->OTYPER, Pin) >> POSITION_VAL(Pin));
}
/**
* @brief Configure gpio speed for a dedicated pin on dedicated port.
* @note I/O speed can be Low, Medium, Fast or High speed.
* @note Warning: only one pin can be passed as parameter.
* @note Refer to datasheet for frequency specifications and the power
* supply and load conditions for each speed.
* @rmtoll OSPEEDR OSPEEDy LL_GPIO_SetPinSpeed
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @param Speed This parameter can be one of the following values:
* @arg @ref LL_GPIO_SPEED_FREQ_LOW
* @arg @ref LL_GPIO_SPEED_FREQ_MEDIUM
* @arg @ref LL_GPIO_SPEED_FREQ_HIGH
* @arg @ref LL_GPIO_SPEED_FREQ_VERY_HIGH
* @retval None
*/
__STATIC_INLINE void LL_GPIO_SetPinSpeed(GPIO_TypeDef *GPIOx, uint32_t Pin, uint32_t Speed)
{
MODIFY_REG(GPIOx->OSPEEDR, (GPIO_OSPEEDR_OSPEED0 << (POSITION_VAL(Pin) * 2U)),
(Speed << (POSITION_VAL(Pin) * 2U)));
}
/**
* @brief Return gpio speed for a dedicated pin on dedicated port.
* @note I/O speed can be Low, Medium, Fast or High speed.
* @note Warning: only one pin can be passed as parameter.
* @note Refer to datasheet for frequency specifications and the power
* supply and load conditions for each speed.
* @rmtoll OSPEEDR OSPEEDy LL_GPIO_GetPinSpeed
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @retval Returned value can be one of the following values:
* @arg @ref LL_GPIO_SPEED_FREQ_LOW
* @arg @ref LL_GPIO_SPEED_FREQ_MEDIUM
* @arg @ref LL_GPIO_SPEED_FREQ_HIGH
* @arg @ref LL_GPIO_SPEED_FREQ_VERY_HIGH
*/
__STATIC_INLINE uint32_t LL_GPIO_GetPinSpeed(GPIO_TypeDef *GPIOx, uint32_t Pin)
{
return (uint32_t)(READ_BIT(GPIOx->OSPEEDR,
(GPIO_OSPEEDR_OSPEED0 << (POSITION_VAL(Pin) * 2U))) >> (POSITION_VAL(Pin) * 2U));
}
/**
* @brief Configure gpio pull-up or pull-down for a dedicated pin on a dedicated port.
* @note Warning: only one pin can be passed as parameter.
* @rmtoll PUPDR PUPDy LL_GPIO_SetPinPull
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @param Pull This parameter can be one of the following values:
* @arg @ref LL_GPIO_PULL_NO
* @arg @ref LL_GPIO_PULL_UP
* @arg @ref LL_GPIO_PULL_DOWN
* @retval None
*/
__STATIC_INLINE void LL_GPIO_SetPinPull(GPIO_TypeDef *GPIOx, uint32_t Pin, uint32_t Pull)
{
MODIFY_REG(GPIOx->PUPDR, (GPIO_PUPDR_PUPD0 << (POSITION_VAL(Pin) * 2U)), (Pull << (POSITION_VAL(Pin) * 2U)));
}
/**
* @brief Return gpio pull-up or pull-down for a dedicated pin on a dedicated port
* @note Warning: only one pin can be passed as parameter.
* @rmtoll PUPDR PUPDy LL_GPIO_GetPinPull
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @retval Returned value can be one of the following values:
* @arg @ref LL_GPIO_PULL_NO
* @arg @ref LL_GPIO_PULL_UP
* @arg @ref LL_GPIO_PULL_DOWN
*/
__STATIC_INLINE uint32_t LL_GPIO_GetPinPull(GPIO_TypeDef *GPIOx, uint32_t Pin)
{
return (uint32_t)(READ_BIT(GPIOx->PUPDR,
(GPIO_PUPDR_PUPD0 << (POSITION_VAL(Pin) * 2U))) >> (POSITION_VAL(Pin) * 2U));
}
/**
* @brief Configure gpio alternate function of a dedicated pin from 0 to 7 for a dedicated port.
* @note Possible values are from AF0 to AF15 depending on target.
* @note Warning: only one pin can be passed as parameter.
* @rmtoll AFRL AFSELy LL_GPIO_SetAFPin_0_7
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @param Alternate This parameter can be one of the following values:
* @arg @ref LL_GPIO_AF_0
* @arg @ref LL_GPIO_AF_1
* @arg @ref LL_GPIO_AF_2
* @arg @ref LL_GPIO_AF_3
* @arg @ref LL_GPIO_AF_4
* @arg @ref LL_GPIO_AF_5
* @arg @ref LL_GPIO_AF_6
* @arg @ref LL_GPIO_AF_7
* @arg @ref LL_GPIO_AF_8
* @arg @ref LL_GPIO_AF_9
* @arg @ref LL_GPIO_AF_10
* @arg @ref LL_GPIO_AF_11
* @arg @ref LL_GPIO_AF_12
* @arg @ref LL_GPIO_AF_13
* @arg @ref LL_GPIO_AF_14
* @arg @ref LL_GPIO_AF_15
* @retval None
*/
__STATIC_INLINE void LL_GPIO_SetAFPin_0_7(GPIO_TypeDef *GPIOx, uint32_t Pin, uint32_t Alternate)
{
MODIFY_REG(GPIOx->AFR[0], (GPIO_AFRL_AFSEL0 << (POSITION_VAL(Pin) * 4U)),
(Alternate << (POSITION_VAL(Pin) * 4U)));
}
/**
* @brief Return gpio alternate function of a dedicated pin from 0 to 7 for a dedicated port.
* @rmtoll AFRL AFSELy LL_GPIO_GetAFPin_0_7
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @retval Returned value can be one of the following values:
* @arg @ref LL_GPIO_AF_0
* @arg @ref LL_GPIO_AF_1
* @arg @ref LL_GPIO_AF_2
* @arg @ref LL_GPIO_AF_3
* @arg @ref LL_GPIO_AF_4
* @arg @ref LL_GPIO_AF_5
* @arg @ref LL_GPIO_AF_6
* @arg @ref LL_GPIO_AF_7
* @arg @ref LL_GPIO_AF_8
* @arg @ref LL_GPIO_AF_9
* @arg @ref LL_GPIO_AF_10
* @arg @ref LL_GPIO_AF_11
* @arg @ref LL_GPIO_AF_12
* @arg @ref LL_GPIO_AF_13
* @arg @ref LL_GPIO_AF_14
* @arg @ref LL_GPIO_AF_15
*/
__STATIC_INLINE uint32_t LL_GPIO_GetAFPin_0_7(GPIO_TypeDef *GPIOx, uint32_t Pin)
{
return (uint32_t)(READ_BIT(GPIOx->AFR[0],
(GPIO_AFRL_AFSEL0 << (POSITION_VAL(Pin) * 4U))) >> (POSITION_VAL(Pin) * 4U));
}
/**
* @brief Configure gpio alternate function of a dedicated pin from 8 to 15 for a dedicated port.
* @note Possible values are from AF0 to AF15 depending on target.
* @note Warning: only one pin can be passed as parameter.
* @rmtoll AFRH AFSELy LL_GPIO_SetAFPin_8_15
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @param Alternate This parameter can be one of the following values:
* @arg @ref LL_GPIO_AF_0
* @arg @ref LL_GPIO_AF_1
* @arg @ref LL_GPIO_AF_2
* @arg @ref LL_GPIO_AF_3
* @arg @ref LL_GPIO_AF_4
* @arg @ref LL_GPIO_AF_5
* @arg @ref LL_GPIO_AF_6
* @arg @ref LL_GPIO_AF_7
* @arg @ref LL_GPIO_AF_8
* @arg @ref LL_GPIO_AF_9
* @arg @ref LL_GPIO_AF_10
* @arg @ref LL_GPIO_AF_11
* @arg @ref LL_GPIO_AF_12
* @arg @ref LL_GPIO_AF_13
* @arg @ref LL_GPIO_AF_14
* @arg @ref LL_GPIO_AF_15
* @retval None
*/
__STATIC_INLINE void LL_GPIO_SetAFPin_8_15(GPIO_TypeDef *GPIOx, uint32_t Pin, uint32_t Alternate)
{
MODIFY_REG(GPIOx->AFR[1], (GPIO_AFRH_AFSEL8 << (POSITION_VAL(Pin >> 8U) * 4U)),
(Alternate << (POSITION_VAL(Pin >> 8U) * 4U)));
}
/**
* @brief Return gpio alternate function of a dedicated pin from 8 to 15 for a dedicated port.
* @note Possible values are from AF0 to AF15 depending on target.
* @rmtoll AFRH AFSELy LL_GPIO_GetAFPin_8_15
* @param GPIOx GPIO Port
* @param Pin This parameter can be one of the following values:
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @retval Returned value can be one of the following values:
* @arg @ref LL_GPIO_AF_0
* @arg @ref LL_GPIO_AF_1
* @arg @ref LL_GPIO_AF_2
* @arg @ref LL_GPIO_AF_3
* @arg @ref LL_GPIO_AF_4
* @arg @ref LL_GPIO_AF_5
* @arg @ref LL_GPIO_AF_6
* @arg @ref LL_GPIO_AF_7
* @arg @ref LL_GPIO_AF_8
* @arg @ref LL_GPIO_AF_9
* @arg @ref LL_GPIO_AF_10
* @arg @ref LL_GPIO_AF_11
* @arg @ref LL_GPIO_AF_12
* @arg @ref LL_GPIO_AF_13
* @arg @ref LL_GPIO_AF_14
* @arg @ref LL_GPIO_AF_15
*/
__STATIC_INLINE uint32_t LL_GPIO_GetAFPin_8_15(GPIO_TypeDef *GPIOx, uint32_t Pin)
{
return (uint32_t)(READ_BIT(GPIOx->AFR[1],
(GPIO_AFRH_AFSEL8 << (POSITION_VAL(Pin >> 8U) * 4U))) >> (POSITION_VAL(Pin >> 8U) * 4U));
}
/**
* @brief Lock configuration of several pins for a dedicated port.
* @note When the lock sequence has been applied on a port bit, the
* value of this port bit can no longer be modified until the
* next reset.
* @note Each lock bit freezes a specific configuration register
* (control and alternate function registers).
* @rmtoll LCKR LCKK LL_GPIO_LockPin
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval None
*/
__STATIC_INLINE void LL_GPIO_LockPin(GPIO_TypeDef *GPIOx, uint32_t PinMask)
{
__IO uint32_t temp;
WRITE_REG(GPIOx->LCKR, GPIO_LCKR_LCKK | PinMask);
WRITE_REG(GPIOx->LCKR, PinMask);
WRITE_REG(GPIOx->LCKR, GPIO_LCKR_LCKK | PinMask);
/* Read LCKR register. This read is mandatory to complete key lock sequence */
temp = READ_REG(GPIOx->LCKR);
(void) temp;
}
/**
* @brief Return 1 if all pins passed as parameter, of a dedicated port, are locked. else Return 0.
* @rmtoll LCKR LCKy LL_GPIO_IsPinLocked
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_GPIO_IsPinLocked(GPIO_TypeDef *GPIOx, uint32_t PinMask)
{
return ((READ_BIT(GPIOx->LCKR, PinMask) == (PinMask)) ? 1UL : 0UL);
}
/**
* @brief Return 1 if one of the pin of a dedicated port is locked. else return 0.
* @rmtoll LCKR LCKK LL_GPIO_IsAnyPinLocked
* @param GPIOx GPIO Port
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_GPIO_IsAnyPinLocked(GPIO_TypeDef *GPIOx)
{
return ((READ_BIT(GPIOx->LCKR, GPIO_LCKR_LCKK) == (GPIO_LCKR_LCKK)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup GPIO_LL_EF_Data_Access Data Access
* @{
*/
/**
* @brief Return full input data register value for a dedicated port.
* @rmtoll IDR IDy LL_GPIO_ReadInputPort
* @param GPIOx GPIO Port
* @retval Input data register value of port
*/
__STATIC_INLINE uint32_t LL_GPIO_ReadInputPort(GPIO_TypeDef *GPIOx)
{
return (uint32_t)(READ_REG(GPIOx->IDR));
}
/**
* @brief Return if input data level for several pins of dedicated port is high or low.
* @rmtoll IDR IDy LL_GPIO_IsInputPinSet
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_GPIO_IsInputPinSet(GPIO_TypeDef *GPIOx, uint32_t PinMask)
{
return ((READ_BIT(GPIOx->IDR, PinMask) == (PinMask)) ? 1UL : 0UL);
}
/**
* @brief Write output data register for the port.
* @rmtoll ODR ODy LL_GPIO_WriteOutputPort
* @param GPIOx GPIO Port
* @param PortValue Level value for each pin of the port
* @retval None
*/
__STATIC_INLINE void LL_GPIO_WriteOutputPort(GPIO_TypeDef *GPIOx, uint32_t PortValue)
{
WRITE_REG(GPIOx->ODR, PortValue);
}
/**
* @brief Return full output data register value for a dedicated port.
* @rmtoll ODR ODy LL_GPIO_ReadOutputPort
* @param GPIOx GPIO Port
* @retval Output data register value of port
*/
__STATIC_INLINE uint32_t LL_GPIO_ReadOutputPort(GPIO_TypeDef *GPIOx)
{
return (uint32_t)(READ_REG(GPIOx->ODR));
}
/**
* @brief Return if input data level for several pins of dedicated port is high or low.
* @rmtoll ODR ODy LL_GPIO_IsOutputPinSet
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_GPIO_IsOutputPinSet(GPIO_TypeDef *GPIOx, uint32_t PinMask)
{
return ((READ_BIT(GPIOx->ODR, PinMask) == (PinMask)) ? 1UL : 0UL);
}
/**
* @brief Set several pins to high level on dedicated gpio port.
* @rmtoll BSRR BSy LL_GPIO_SetOutputPin
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval None
*/
__STATIC_INLINE void LL_GPIO_SetOutputPin(GPIO_TypeDef *GPIOx, uint32_t PinMask)
{
WRITE_REG(GPIOx->BSRR, PinMask);
}
/**
* @brief Set several pins to low level on dedicated gpio port.
* @rmtoll BRR BRy LL_GPIO_ResetOutputPin
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval None
*/
__STATIC_INLINE void LL_GPIO_ResetOutputPin(GPIO_TypeDef *GPIOx, uint32_t PinMask)
{
WRITE_REG(GPIOx->BRR, PinMask);
}
/**
* @brief Toggle data value for several pin of dedicated port.
* @rmtoll ODR ODy LL_GPIO_TogglePin
* @param GPIOx GPIO Port
* @param PinMask This parameter can be a combination of the following values:
* @arg @ref LL_GPIO_PIN_0
* @arg @ref LL_GPIO_PIN_1
* @arg @ref LL_GPIO_PIN_2
* @arg @ref LL_GPIO_PIN_3
* @arg @ref LL_GPIO_PIN_4
* @arg @ref LL_GPIO_PIN_5
* @arg @ref LL_GPIO_PIN_6
* @arg @ref LL_GPIO_PIN_7
* @arg @ref LL_GPIO_PIN_8
* @arg @ref LL_GPIO_PIN_9
* @arg @ref LL_GPIO_PIN_10
* @arg @ref LL_GPIO_PIN_11
* @arg @ref LL_GPIO_PIN_12
* @arg @ref LL_GPIO_PIN_13
* @arg @ref LL_GPIO_PIN_14
* @arg @ref LL_GPIO_PIN_15
* @arg @ref LL_GPIO_PIN_ALL
* @retval None
*/
__STATIC_INLINE void LL_GPIO_TogglePin(GPIO_TypeDef *GPIOx, uint32_t PinMask)
{
uint32_t odr = READ_REG(GPIOx->ODR);
WRITE_REG(GPIOx->BSRR, ((odr & PinMask) << 16u) | (~odr & PinMask));
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup GPIO_LL_EF_Init Initialization and de-initialization functions
* @{
*/
ErrorStatus LL_GPIO_DeInit(GPIO_TypeDef *GPIOx);
ErrorStatus LL_GPIO_Init(GPIO_TypeDef *GPIOx, LL_GPIO_InitTypeDef *GPIO_InitStruct);
void LL_GPIO_StructInit(LL_GPIO_InitTypeDef *GPIO_InitStruct);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* defined (GPIOA) || defined (GPIOB) || defined (GPIOC) || defined (GPIOD) || defined (GPIOE) || defined (GPIOF) || defined (GPIOG) */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_GPIO_H */
| 37,962 | C | 37.153769 | 160 | 0.547732 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_pwr.h | /**
******************************************************************************
* @file stm32g4xx_ll_pwr.h
* @author MCD Application Team
* @brief Header file of PWR LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_PWR_H
#define STM32G4xx_LL_PWR_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined(PWR)
/** @defgroup PWR_LL PWR
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup PWR_LL_Exported_Constants PWR Exported Constants
* @{
*/
/** @defgroup PWR_LL_EC_CLEAR_FLAG Clear Flags Defines
* @brief Flags defines which can be used with LL_PWR_WriteReg function
* @{
*/
#define LL_PWR_SCR_CSBF PWR_SCR_CSBF
#define LL_PWR_SCR_CWUF PWR_SCR_CWUF
#define LL_PWR_SCR_CWUF5 PWR_SCR_CWUF5
#define LL_PWR_SCR_CWUF4 PWR_SCR_CWUF4
#define LL_PWR_SCR_CWUF3 PWR_SCR_CWUF3
#define LL_PWR_SCR_CWUF2 PWR_SCR_CWUF2
#define LL_PWR_SCR_CWUF1 PWR_SCR_CWUF1
/**
* @}
*/
/** @defgroup PWR_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_PWR_ReadReg function
* @{
*/
#define LL_PWR_SR1_WUFI PWR_SR1_WUFI
#define LL_PWR_SR1_SBF PWR_SR1_SBF
#define LL_PWR_SR1_WUF5 PWR_SR1_WUF5
#define LL_PWR_SR1_WUF4 PWR_SR1_WUF4
#define LL_PWR_SR1_WUF3 PWR_SR1_WUF3
#define LL_PWR_SR1_WUF2 PWR_SR1_WUF2
#define LL_PWR_SR1_WUF1 PWR_SR1_WUF1
#if defined(PWR_SR2_PVMO4)
#define LL_PWR_SR2_PVMO4 PWR_SR2_PVMO4
#endif /* PWR_SR2_PVMO4 */
#if defined(PWR_SR2_PVMO3)
#define LL_PWR_SR2_PVMO3 PWR_SR2_PVMO3
#endif /* PWR_SR2_PVMO3 */
#if defined(PWR_SR2_PVMO2)
#define LL_PWR_SR2_PVMO2 PWR_SR2_PVMO2
#endif /* PWR_SR2_PVMO2 */
#if defined(PWR_SR2_PVMO1)
#define LL_PWR_SR2_PVMO1 PWR_SR2_PVMO1
#endif /* PWR_SR2_PVMO1 */
#define LL_PWR_SR2_PVDO PWR_SR2_PVDO
#define LL_PWR_SR2_VOSF PWR_SR2_VOSF
#define LL_PWR_SR2_REGLPF PWR_SR2_REGLPF
#define LL_PWR_SR2_REGLPS PWR_SR2_REGLPS
/**
* @}
*/
/** @defgroup PWR_LL_EC_REGU_VOLTAGE REGU VOLTAGE
* @{
*/
#define LL_PWR_REGU_VOLTAGE_SCALE1 (PWR_CR1_VOS_0)
#define LL_PWR_REGU_VOLTAGE_SCALE2 (PWR_CR1_VOS_1)
/**
* @}
*/
/** @defgroup PWR_LL_EC_MODE_PWR MODE PWR
* @{
*/
#define LL_PWR_MODE_STOP0 (PWR_CR1_LPMS_STOP0)
#define LL_PWR_MODE_STOP1 (PWR_CR1_LPMS_STOP1)
#define LL_PWR_MODE_STANDBY (PWR_CR1_LPMS_STANDBY)
#define LL_PWR_MODE_SHUTDOWN (PWR_CR1_LPMS_SHUTDOWN)
/**
* @}
*/
/** @defgroup PWR_LL_EC_PVM_VDDUSB_1 Peripheral voltage monitoring
* @{
*/
#if defined(PWR_CR2_PVME1)
#define LL_PWR_PVM_VDDA_COMP (PWR_CR2_PVME1) /* Monitoring VDDA vs. x.xV */
#endif
#if defined(PWR_CR2_PVME2)
#define LL_PWR_PVM_VDDA_FASTDAC (PWR_CR2_PVME2) /* Monitoring VDDA vs. x.xV */
#endif
#if defined(PWR_CR2_PVME3)
#define LL_PWR_PVM_VDDA_ADC (PWR_CR2_PVME3) /* Monitoring VDDA vs. 1.62V */
#endif
#if defined(PWR_CR2_PVME4)
#define LL_PWR_PVM_VDDA_OPAMP_DAC (PWR_CR2_PVME4) /* Monitoring VDDA vs. 1x.xV */
#endif
/**
* @}
*/
/** @defgroup PWR_LL_EC_PVDLEVEL PVDLEVEL
* @{
*/
#define LL_PWR_PVDLEVEL_0 (PWR_CR2_PLS_LEV0) /* VPVD0 around 2.0 V */
#define LL_PWR_PVDLEVEL_1 (PWR_CR2_PLS_LEV1) /* VPVD1 around 2.2 V */
#define LL_PWR_PVDLEVEL_2 (PWR_CR2_PLS_LEV2) /* VPVD2 around 2.4 V */
#define LL_PWR_PVDLEVEL_3 (PWR_CR2_PLS_LEV3) /* VPVD3 around 2.5 V */
#define LL_PWR_PVDLEVEL_4 (PWR_CR2_PLS_LEV4) /* VPVD4 around 2.6 V */
#define LL_PWR_PVDLEVEL_5 (PWR_CR2_PLS_LEV5) /* VPVD5 around 2.8 V */
#define LL_PWR_PVDLEVEL_6 (PWR_CR2_PLS_LEV6) /* VPVD6 around 2.9 V */
#define LL_PWR_PVDLEVEL_7 (PWR_CR2_PLS_LEV7) /* External input analog voltage (Compare internally to VREFINT) */
/**
* @}
*/
/** @defgroup PWR_LL_EC_WAKEUP WAKEUP
* @{
*/
#define LL_PWR_WAKEUP_PIN1 (PWR_CR3_EWUP1)
#define LL_PWR_WAKEUP_PIN2 (PWR_CR3_EWUP2)
#define LL_PWR_WAKEUP_PIN3 (PWR_CR3_EWUP3)
#define LL_PWR_WAKEUP_PIN4 (PWR_CR3_EWUP4)
#define LL_PWR_WAKEUP_PIN5 (PWR_CR3_EWUP5)
/**
* @}
*/
/** @defgroup PWR_LL_EC_BATT_CHARG_RESISTOR BATT CHARG RESISTOR
* @{
*/
#define LL_PWR_BATT_CHARG_RESISTOR_5K ((uint32_t)0x00000000)
#define LL_PWR_BATT_CHARGRESISTOR_1_5K (PWR_CR4_VBRS)
/**
* @}
*/
/** @defgroup PWR_LL_EC_GPIO GPIO
* @{
*/
#define LL_PWR_GPIO_A ((uint32_t)(&(PWR->PUCRA)))
#define LL_PWR_GPIO_B ((uint32_t)(&(PWR->PUCRB)))
#define LL_PWR_GPIO_C ((uint32_t)(&(PWR->PUCRC)))
#define LL_PWR_GPIO_D ((uint32_t)(&(PWR->PUCRD)))
#define LL_PWR_GPIO_E ((uint32_t)(&(PWR->PUCRE)))
#define LL_PWR_GPIO_F ((uint32_t)(&(PWR->PUCRF)))
#define LL_PWR_GPIO_G ((uint32_t)(&(PWR->PUCRG)))
/**
* @}
*/
/** @defgroup PWR_LL_EC_GPIO_BIT GPIO BIT
* @{
*/
#define LL_PWR_GPIO_BIT_0 ((uint32_t)0x00000001)
#define LL_PWR_GPIO_BIT_1 ((uint32_t)0x00000002)
#define LL_PWR_GPIO_BIT_2 ((uint32_t)0x00000004)
#define LL_PWR_GPIO_BIT_3 ((uint32_t)0x00000008)
#define LL_PWR_GPIO_BIT_4 ((uint32_t)0x00000010)
#define LL_PWR_GPIO_BIT_5 ((uint32_t)0x00000020)
#define LL_PWR_GPIO_BIT_6 ((uint32_t)0x00000040)
#define LL_PWR_GPIO_BIT_7 ((uint32_t)0x00000080)
#define LL_PWR_GPIO_BIT_8 ((uint32_t)0x00000100)
#define LL_PWR_GPIO_BIT_9 ((uint32_t)0x00000200)
#define LL_PWR_GPIO_BIT_10 ((uint32_t)0x00000400)
#define LL_PWR_GPIO_BIT_11 ((uint32_t)0x00000800)
#define LL_PWR_GPIO_BIT_12 ((uint32_t)0x00001000)
#define LL_PWR_GPIO_BIT_13 ((uint32_t)0x00002000)
#define LL_PWR_GPIO_BIT_14 ((uint32_t)0x00004000)
#define LL_PWR_GPIO_BIT_15 ((uint32_t)0x00008000)
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup PWR_LL_Exported_Macros PWR Exported Macros
* @{
*/
/** @defgroup PWR_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in PWR register
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_PWR_WriteReg(__REG__, __VALUE__) WRITE_REG(PWR->__REG__, (__VALUE__))
/**
* @brief Read a value in PWR register
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_PWR_ReadReg(__REG__) READ_REG(PWR->__REG__)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup PWR_LL_Exported_Functions PWR Exported Functions
* @{
*/
/** @defgroup PWR_LL_EF_Configuration Configuration
* @{
*/
/**
* @brief Switch the regulator from main mode to low-power mode
* @rmtoll CR1 LPR LL_PWR_EnableLowPowerRunMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableLowPowerRunMode(void)
{
SET_BIT(PWR->CR1, PWR_CR1_LPR);
}
/**
* @brief Switch the regulator from low-power mode to main mode
* @rmtoll CR1 LPR LL_PWR_DisableLowPowerRunMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableLowPowerRunMode(void)
{
CLEAR_BIT(PWR->CR1, PWR_CR1_LPR);
}
/**
* @brief Check if the regulator is in low-power mode
* @rmtoll CR1 LPR LL_PWR_IsEnabledLowPowerRunMode
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledLowPowerRunMode(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR1, PWR_CR1_LPR);
return ((temp == (PWR_CR1_LPR))?1U:0U);
}
/**
* @brief Switch from run main mode to run low-power mode.
* @rmtoll CR1 LPR LL_PWR_EnterLowPowerRunMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnterLowPowerRunMode(void)
{
LL_PWR_EnableLowPowerRunMode();
}
/**
* @brief Switch from run main mode to low-power mode.
* @rmtoll CR1 LPR LL_PWR_ExitLowPowerRunMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_ExitLowPowerRunMode(void)
{
LL_PWR_DisableLowPowerRunMode();
}
/**
* @brief Set the main internal regulator output voltage
* @rmtoll CR1 VOS LL_PWR_SetRegulVoltageScaling
* @param VoltageScaling This parameter can be one of the following values:
* @arg @ref LL_PWR_REGU_VOLTAGE_SCALE1
* @arg @ref LL_PWR_REGU_VOLTAGE_SCALE2
* @retval None
*/
__STATIC_INLINE void LL_PWR_SetRegulVoltageScaling(uint32_t VoltageScaling)
{
MODIFY_REG(PWR->CR1, PWR_CR1_VOS, VoltageScaling);
}
/**
* @brief Get the main internal regulator output voltage
* @rmtoll CR1 VOS LL_PWR_GetRegulVoltageScaling
* @retval Returned value can be one of the following values:
* @arg @ref LL_PWR_REGU_VOLTAGE_SCALE1
* @arg @ref LL_PWR_REGU_VOLTAGE_SCALE2
*/
__STATIC_INLINE uint32_t LL_PWR_GetRegulVoltageScaling(void)
{
return (uint32_t)(READ_BIT(PWR->CR1, PWR_CR1_VOS));
}
#if defined(PWR_CR5_R1MODE)
/**
* @brief Enable main regulator voltage range 1 boost mode
* @rmtoll CR5 R1MODE LL_PWR_EnableRange1BoostMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableRange1BoostMode(void)
{
CLEAR_BIT(PWR->CR5, PWR_CR5_R1MODE);
}
/**
* @brief Disable main regulator voltage range 1 boost mode
* @rmtoll CR5 R1MODE LL_PWR_DisableRange1BoostMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableRange1BoostMode(void)
{
SET_BIT(PWR->CR5, PWR_CR5_R1MODE);
}
/**
* @brief Check if the main regulator voltage range 1 boost mode is enabled
* @rmtoll CR5 R1MODE LL_PWR_IsEnabledRange1BoostMode
* @retval Inverted state of bit (0 or 1).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledRange1BoostMode(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR5, PWR_CR5_R1MODE);
return ((temp == (0U))?1U:0U);
}
#endif /* PWR_CR5_R1MODE */
/**
* @brief Enable access to the backup domain
* @rmtoll CR1 DBP LL_PWR_EnableBkUpAccess
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableBkUpAccess(void)
{
SET_BIT(PWR->CR1, PWR_CR1_DBP);
}
/**
* @brief Disable access to the backup domain
* @rmtoll CR1 DBP LL_PWR_DisableBkUpAccess
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableBkUpAccess(void)
{
CLEAR_BIT(PWR->CR1, PWR_CR1_DBP);
}
/**
* @brief Check if the backup domain is enabled
* @rmtoll CR1 DBP LL_PWR_IsEnabledBkUpAccess
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledBkUpAccess(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR1, PWR_CR1_DBP);
return ((temp == (PWR_CR1_DBP))?1U:0U);
}
/**
* @brief Set Low-Power mode
* @rmtoll CR1 LPMS LL_PWR_SetPowerMode
* @param LowPowerMode This parameter can be one of the following values:
* @arg @ref LL_PWR_MODE_STOP0
* @arg @ref LL_PWR_MODE_STOP1
* @arg @ref LL_PWR_MODE_STANDBY
* @arg @ref LL_PWR_MODE_SHUTDOWN
* @retval None
*/
__STATIC_INLINE void LL_PWR_SetPowerMode(uint32_t LowPowerMode)
{
MODIFY_REG(PWR->CR1, PWR_CR1_LPMS, LowPowerMode);
}
/**
* @brief Get Low-Power mode
* @rmtoll CR1 LPMS LL_PWR_GetPowerMode
* @retval Returned value can be one of the following values:
* @arg @ref LL_PWR_MODE_STOP0
* @arg @ref LL_PWR_MODE_STOP1
* @arg @ref LL_PWR_MODE_STANDBY
* @arg @ref LL_PWR_MODE_SHUTDOWN
*/
__STATIC_INLINE uint32_t LL_PWR_GetPowerMode(void)
{
return (uint32_t)(READ_BIT(PWR->CR1, PWR_CR1_LPMS));
}
#if defined(PWR_CR3_UCPD_STDBY)
/**
* @brief Enable the USB Type-C and Power Delivery memorization in Standby mode.
* @note This function must be called just before entering Standby mode.
* @rmtoll CR3 UCPD_STDBY LL_PWR_EnableUCPDStandbyMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableUCPDStandbyMode(void)
{
SET_BIT(PWR->CR3, PWR_CR3_UCPD_STDBY);
}
/**
* @brief Disable the USB Type-C and Power Delivery memorization in Standby mode.
* @note This function must be called after exiting Standby mode and before any
* UCPD configuration update.
* @rmtoll CR3 UCPD_STDBY LL_PWR_DisableUCPDStandbyMode
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableUCPDStandbyMode(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_UCPD_STDBY);
}
/**
* @brief Check the USB Type-C and Power Delivery Standby mode memorization state.
* @rmtoll CR3 UCPD_STDBY LL_PWR_IsEnabledUCPDStandbyMode
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledUCPDStandbyMode(void)
{
return ((READ_BIT(PWR->CR3, PWR_CR3_UCPD_STDBY) == (PWR_CR3_UCPD_STDBY)) ? 1UL : 0UL);
}
#endif /* PWR_CR3_UCPD_STDBY */
#if defined(PWR_CR3_UCPD_DBDIS)
/**
* @brief Enable the USB Type-C and power delivery dead battery pull-down behavior
* on UCPD CC1 and CC2 pins.
* @note After exiting reset, the USB Type-C dead battery behavior is enabled,
* which may have a pull-down effect on CC1 and CC2 pins. It is recommended
* to disable it in all cases, either to stop this pull-down or to hand over
* control to the UCPD (which should therefore be initialized before doing the disable).
* @rmtoll CR3 UCPD_DBDIS LL_PWR_EnableUCPDDeadBattery
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableUCPDDeadBattery(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_UCPD_DBDIS);
}
/**
* @brief Disable the USB Type-C and power delivery dead battery pull-down behavior
* on UCPD CC1 and CC2 pins.
* @note After exiting reset, the USB Type-C dead battery behavior is enabled,
* which may have a pull-down effect on CC1 and CC2 pins. It is recommended
* to disable it in all cases, either to stop this pull-down or to hand over
* control to the UCPD (which should therefore be initialized before doing the disable).
* @rmtoll CR3 UCPD_DBDIS LL_PWR_DisableUCPDDeadBattery
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableUCPDDeadBattery(void)
{
SET_BIT(PWR->CR3, PWR_CR3_UCPD_DBDIS);
}
/**
* @brief Check the USB Type-C and power delivery dead battery pull-down behavior
* on UCPD CC1 and CC2 pins.
* @note After exiting reset, the USB Type-C dead battery behavior is enabled,
* which may have a pull-down effect on CC1 and CC2 pins. It is recommended
* to disable it in all cases, either to stop this pull-down or to hand over
* control to the UCPD (which should therefore be initialized before doing the disable).
* @rmtoll CR3 UCPD_DBDIS LL_PWR_IsEnabledUCPDDeadBattery
* @retval State of feature (1 : enabled; 0 : disabled).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledUCPDDeadBattery(void)
{
return ((READ_BIT(PWR->CR3, PWR_CR3_UCPD_DBDIS) == (PWR_CR3_UCPD_DBDIS)) ? 0UL : 1UL);
}
#endif /* PWR_CR3_UCPD_DBDIS */
#if defined(PWR_CR2_USV)
/**
* @brief Enable VDDUSB supply
* @rmtoll CR2 USV LL_PWR_EnableVddUSB
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableVddUSB(void)
{
SET_BIT(PWR->CR2, PWR_CR2_USV);
}
/**
* @brief Disable VDDUSB supply
* @rmtoll CR2 USV LL_PWR_DisableVddUSB
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableVddUSB(void)
{
CLEAR_BIT(PWR->CR2, PWR_CR2_USV);
}
/**
* @brief Check if VDDUSB supply is enabled
* @rmtoll CR2 USV LL_PWR_IsEnabledVddUSB
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledVddUSB(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR2, PWR_CR2_USV);
return ((temp == (PWR_CR2_USV))?1U:0U);
}
#endif
#if defined(PWR_CR2_IOSV)
/**
* @brief Enable VDDIO2 supply
* @rmtoll CR2 IOSV LL_PWR_EnableVddIO2
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableVddIO2(void)
{
SET_BIT(PWR->CR2, PWR_CR2_IOSV);
}
/**
* @brief Disable VDDIO2 supply
* @rmtoll CR2 IOSV LL_PWR_DisableVddIO2
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableVddIO2(void)
{
CLEAR_BIT(PWR->CR2, PWR_CR2_IOSV);
}
/**
* @brief Check if VDDIO2 supply is enabled
* @rmtoll CR2 IOSV LL_PWR_IsEnabledVddIO2
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledVddIO2(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR2, PWR_CR2_IOSV);
return ((temp == (PWR_CR2_IOSV))?1U:0U);
}
#endif
/**
* @brief Enable the Power Voltage Monitoring on a peripheral
* @rmtoll CR2 PVME1 LL_PWR_EnablePVM\n
* CR2 PVME2 LL_PWR_EnablePVM\n
* CR2 PVME3 LL_PWR_EnablePVM\n
* CR2 PVME4 LL_PWR_EnablePVM
* @param PeriphVoltage This parameter can be one of the following values:
* @arg @ref LL_PWR_PVM_VDDA_COMP (*)
* @arg @ref LL_PWR_PVM_VDDA_FASTDAC (*)
* @arg @ref LL_PWR_PVM_VDDA_ADC
* @arg @ref LL_PWR_PVM_VDDA_OPAMP_DAC
*
* (*) value not defined in all devices
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnablePVM(uint32_t PeriphVoltage)
{
SET_BIT(PWR->CR2, PeriphVoltage);
}
/**
* @brief Disable the Power Voltage Monitoring on a peripheral
* @rmtoll CR2 PVME1 LL_PWR_DisablePVM\n
* CR2 PVME2 LL_PWR_DisablePVM\n
* CR2 PVME3 LL_PWR_DisablePVM\n
* CR2 PVME4 LL_PWR_DisablePVM
* @param PeriphVoltage This parameter can be one of the following values:
* @arg @ref LL_PWR_PVM_VDDA_COMP (*)
* @arg @ref LL_PWR_PVM_VDDA_FASTDAC (*)
* @arg @ref LL_PWR_PVM_VDDA_ADC
* @arg @ref LL_PWR_PVM_VDDA_OPAMP_DAC
*
* (*) value not defined in all devices
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisablePVM(uint32_t PeriphVoltage)
{
CLEAR_BIT(PWR->CR2, PeriphVoltage);
}
/**
* @brief Check if Power Voltage Monitoring is enabled on a peripheral
* @rmtoll CR2 PVME1 LL_PWR_IsEnabledPVM\n
* CR2 PVME2 LL_PWR_IsEnabledPVM\n
* CR2 PVME3 LL_PWR_IsEnabledPVM\n
* CR2 PVME4 LL_PWR_IsEnabledPVM
* @param PeriphVoltage This parameter can be one of the following values:
* @arg @ref LL_PWR_PVM_VDDA_COMP (*)
* @arg @ref LL_PWR_PVM_VDDA_FASTDAC (*)
* @arg @ref LL_PWR_PVM_VDDA_ADC
* @arg @ref LL_PWR_PVM_VDDA_OPAMP_DAC
*
* (*) value not defined in all devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledPVM(uint32_t PeriphVoltage)
{
uint32_t temp;
temp = READ_BIT(PWR->CR2, PeriphVoltage);
return ((temp == (PeriphVoltage))?1U:0U);
}
/**
* @brief Configure the voltage threshold detected by the Power Voltage Detector
* @rmtoll CR2 PLS LL_PWR_SetPVDLevel
* @param PVDLevel This parameter can be one of the following values:
* @arg @ref LL_PWR_PVDLEVEL_0
* @arg @ref LL_PWR_PVDLEVEL_1
* @arg @ref LL_PWR_PVDLEVEL_2
* @arg @ref LL_PWR_PVDLEVEL_3
* @arg @ref LL_PWR_PVDLEVEL_4
* @arg @ref LL_PWR_PVDLEVEL_5
* @arg @ref LL_PWR_PVDLEVEL_6
* @arg @ref LL_PWR_PVDLEVEL_7
* @retval None
*/
__STATIC_INLINE void LL_PWR_SetPVDLevel(uint32_t PVDLevel)
{
MODIFY_REG(PWR->CR2, PWR_CR2_PLS, PVDLevel);
}
/**
* @brief Get the voltage threshold detection
* @rmtoll CR2 PLS LL_PWR_GetPVDLevel
* @retval Returned value can be one of the following values:
* @arg @ref LL_PWR_PVDLEVEL_0
* @arg @ref LL_PWR_PVDLEVEL_1
* @arg @ref LL_PWR_PVDLEVEL_2
* @arg @ref LL_PWR_PVDLEVEL_3
* @arg @ref LL_PWR_PVDLEVEL_4
* @arg @ref LL_PWR_PVDLEVEL_5
* @arg @ref LL_PWR_PVDLEVEL_6
* @arg @ref LL_PWR_PVDLEVEL_7
*/
__STATIC_INLINE uint32_t LL_PWR_GetPVDLevel(void)
{
return (uint32_t)(READ_BIT(PWR->CR2, PWR_CR2_PLS));
}
/**
* @brief Enable Power Voltage Detector
* @rmtoll CR2 PVDE LL_PWR_EnablePVD
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnablePVD(void)
{
SET_BIT(PWR->CR2, PWR_CR2_PVDE);
}
/**
* @brief Disable Power Voltage Detector
* @rmtoll CR2 PVDE LL_PWR_DisablePVD
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisablePVD(void)
{
CLEAR_BIT(PWR->CR2, PWR_CR2_PVDE);
}
/**
* @brief Check if Power Voltage Detector is enabled
* @rmtoll CR2 PVDE LL_PWR_IsEnabledPVD
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledPVD(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR2, PWR_CR2_PVDE);
return ((temp == (PWR_CR2_PVDE))?1U:0U);
}
/**
* @brief Enable Internal Wake-up line
* @rmtoll CR3 EIWF LL_PWR_EnableInternWU
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableInternWU(void)
{
SET_BIT(PWR->CR3, PWR_CR3_EIWF);
}
/**
* @brief Disable Internal Wake-up line
* @rmtoll CR3 EIWF LL_PWR_DisableInternWU
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableInternWU(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_EIWF);
}
/**
* @brief Check if Internal Wake-up line is enabled
* @rmtoll CR3 EIWF LL_PWR_IsEnabledInternWU
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledInternWU(void)
{
return ((READ_BIT(PWR->CR3, PWR_CR3_EIWF) == (PWR_CR3_EIWF))?1UL:0UL);
}
/**
* @brief Enable pull-up and pull-down configuration
* @rmtoll CR3 APC LL_PWR_EnablePUPDCfg
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnablePUPDCfg(void)
{
SET_BIT(PWR->CR3, PWR_CR3_APC);
}
/**
* @brief Disable pull-up and pull-down configuration
* @rmtoll CR3 APC LL_PWR_DisablePUPDCfg
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisablePUPDCfg(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_APC);
}
/**
* @brief Check if pull-up and pull-down configuration is enabled
* @rmtoll CR3 APC LL_PWR_IsEnabledPUPDCfg
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledPUPDCfg(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR3, PWR_CR3_APC);
return ((temp == (PWR_CR3_APC))?1U:0U);
}
/**
* @brief Enable SRAM2 content retention in Standby mode
* @rmtoll CR3 RRS LL_PWR_EnableSRAM2Retention
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableSRAM2Retention(void)
{
SET_BIT(PWR->CR3, PWR_CR3_RRS);
}
/**
* @brief Disable SRAM2 content retention in Standby mode
* @rmtoll CR3 RRS LL_PWR_DisableSRAM2Retention
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableSRAM2Retention(void)
{
CLEAR_BIT(PWR->CR3, PWR_CR3_RRS);
}
/**
* @brief Check if SRAM2 content retention in Standby mode is enabled
* @rmtoll CR3 RRS LL_PWR_IsEnabledSRAM2Retention
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledSRAM2Retention(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR3, PWR_CR3_RRS);
return ((temp == (PWR_CR3_RRS))?1U:0U);
}
/**
* @brief Enable the WakeUp PINx functionality
* @rmtoll CR3 EWUP1 LL_PWR_EnableWakeUpPin\n
* CR3 EWUP2 LL_PWR_EnableWakeUpPin\n
* CR3 EWUP3 LL_PWR_EnableWakeUpPin\n
* CR3 EWUP4 LL_PWR_EnableWakeUpPin\n
* CR3 EWUP5 LL_PWR_EnableWakeUpPin\n
* @param WakeUpPin This parameter can be one of the following values:
* @arg @ref LL_PWR_WAKEUP_PIN1
* @arg @ref LL_PWR_WAKEUP_PIN2
* @arg @ref LL_PWR_WAKEUP_PIN3
* @arg @ref LL_PWR_WAKEUP_PIN4
* @arg @ref LL_PWR_WAKEUP_PIN5
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableWakeUpPin(uint32_t WakeUpPin)
{
SET_BIT(PWR->CR3, WakeUpPin);
}
/**
* @brief Disable the WakeUp PINx functionality
* @rmtoll CR3 EWUP1 LL_PWR_DisableWakeUpPin\n
* CR3 EWUP2 LL_PWR_DisableWakeUpPin\n
* CR3 EWUP3 LL_PWR_DisableWakeUpPin\n
* CR3 EWUP4 LL_PWR_DisableWakeUpPin\n
* CR3 EWUP5 LL_PWR_DisableWakeUpPin\n
* @param WakeUpPin This parameter can be one of the following values:
* @arg @ref LL_PWR_WAKEUP_PIN1
* @arg @ref LL_PWR_WAKEUP_PIN2
* @arg @ref LL_PWR_WAKEUP_PIN3
* @arg @ref LL_PWR_WAKEUP_PIN4
* @arg @ref LL_PWR_WAKEUP_PIN5
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableWakeUpPin(uint32_t WakeUpPin)
{
CLEAR_BIT(PWR->CR3, WakeUpPin);
}
/**
* @brief Check if the WakeUp PINx functionality is enabled
* @rmtoll CR3 EWUP1 LL_PWR_IsEnabledWakeUpPin\n
* CR3 EWUP2 LL_PWR_IsEnabledWakeUpPin\n
* CR3 EWUP3 LL_PWR_IsEnabledWakeUpPin\n
* CR3 EWUP4 LL_PWR_IsEnabledWakeUpPin\n
* CR3 EWUP5 LL_PWR_IsEnabledWakeUpPin\n
* @param WakeUpPin This parameter can be one of the following values:
* @arg @ref LL_PWR_WAKEUP_PIN1
* @arg @ref LL_PWR_WAKEUP_PIN2
* @arg @ref LL_PWR_WAKEUP_PIN3
* @arg @ref LL_PWR_WAKEUP_PIN4
* @arg @ref LL_PWR_WAKEUP_PIN5
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledWakeUpPin(uint32_t WakeUpPin)
{
uint32_t temp;
temp = READ_BIT(PWR->CR3, WakeUpPin);
return ((temp == (WakeUpPin))?1U:0U);
}
/**
* @brief Set the resistor impedance
* @rmtoll CR4 VBRS LL_PWR_SetBattChargResistor
* @param Resistor This parameter can be one of the following values:
* @arg @ref LL_PWR_BATT_CHARG_RESISTOR_5K
* @arg @ref LL_PWR_BATT_CHARGRESISTOR_1_5K
* @retval None
*/
__STATIC_INLINE void LL_PWR_SetBattChargResistor(uint32_t Resistor)
{
MODIFY_REG(PWR->CR4, PWR_CR4_VBRS, Resistor);
}
/**
* @brief Get the resistor impedance
* @rmtoll CR4 VBRS LL_PWR_GetBattChargResistor
* @retval Returned value can be one of the following values:
* @arg @ref LL_PWR_BATT_CHARG_RESISTOR_5K
* @arg @ref LL_PWR_BATT_CHARGRESISTOR_1_5K
*/
__STATIC_INLINE uint32_t LL_PWR_GetBattChargResistor(void)
{
return (uint32_t)(READ_BIT(PWR->CR4, PWR_CR4_VBRS));
}
/**
* @brief Enable battery charging
* @rmtoll CR4 VBE LL_PWR_EnableBatteryCharging
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableBatteryCharging(void)
{
SET_BIT(PWR->CR4, PWR_CR4_VBE);
}
/**
* @brief Disable battery charging
* @rmtoll CR4 VBE LL_PWR_DisableBatteryCharging
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableBatteryCharging(void)
{
CLEAR_BIT(PWR->CR4, PWR_CR4_VBE);
}
/**
* @brief Check if battery charging is enabled
* @rmtoll CR4 VBE LL_PWR_IsEnabledBatteryCharging
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledBatteryCharging(void)
{
uint32_t temp;
temp = READ_BIT(PWR->CR4, PWR_CR4_VBE);
return ((temp == (PWR_CR4_VBE))?1U:0U);
}
/**
* @brief Set the Wake-Up pin polarity low for the event detection
* @rmtoll CR4 WP1 LL_PWR_SetWakeUpPinPolarityLow\n
* CR4 WP2 LL_PWR_SetWakeUpPinPolarityLow\n
* CR4 WP3 LL_PWR_SetWakeUpPinPolarityLow\n
* CR4 WP4 LL_PWR_SetWakeUpPinPolarityLow\n
* CR4 WP5 LL_PWR_SetWakeUpPinPolarityLow
* @param WakeUpPin This parameter can be one of the following values:
* @arg @ref LL_PWR_WAKEUP_PIN1
* @arg @ref LL_PWR_WAKEUP_PIN2
* @arg @ref LL_PWR_WAKEUP_PIN3
* @arg @ref LL_PWR_WAKEUP_PIN4
* @arg @ref LL_PWR_WAKEUP_PIN5
* @retval None
*/
__STATIC_INLINE void LL_PWR_SetWakeUpPinPolarityLow(uint32_t WakeUpPin)
{
SET_BIT(PWR->CR4, WakeUpPin);
}
/**
* @brief Set the Wake-Up pin polarity high for the event detection
* @rmtoll CR4 WP1 LL_PWR_SetWakeUpPinPolarityHigh\n
* CR4 WP2 LL_PWR_SetWakeUpPinPolarityHigh\n
* CR4 WP3 LL_PWR_SetWakeUpPinPolarityHigh\n
* CR4 WP4 LL_PWR_SetWakeUpPinPolarityHigh\n
* CR4 WP5 LL_PWR_SetWakeUpPinPolarityHigh
* @param WakeUpPin This parameter can be one of the following values:
* @arg @ref LL_PWR_WAKEUP_PIN1
* @arg @ref LL_PWR_WAKEUP_PIN2
* @arg @ref LL_PWR_WAKEUP_PIN3
* @arg @ref LL_PWR_WAKEUP_PIN4
* @arg @ref LL_PWR_WAKEUP_PIN5
* @retval None
*/
__STATIC_INLINE void LL_PWR_SetWakeUpPinPolarityHigh(uint32_t WakeUpPin)
{
CLEAR_BIT(PWR->CR4, WakeUpPin);
}
/**
* @brief Get the Wake-Up pin polarity for the event detection
* @rmtoll CR4 WP1 LL_PWR_IsWakeUpPinPolarityLow\n
* CR4 WP2 LL_PWR_IsWakeUpPinPolarityLow\n
* CR4 WP3 LL_PWR_IsWakeUpPinPolarityLow\n
* CR4 WP4 LL_PWR_IsWakeUpPinPolarityLow\n
* CR4 WP5 LL_PWR_IsWakeUpPinPolarityLow
* @param WakeUpPin This parameter can be one of the following values:
* @arg @ref LL_PWR_WAKEUP_PIN1
* @arg @ref LL_PWR_WAKEUP_PIN2
* @arg @ref LL_PWR_WAKEUP_PIN3
* @arg @ref LL_PWR_WAKEUP_PIN4
* @arg @ref LL_PWR_WAKEUP_PIN5
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsWakeUpPinPolarityLow(uint32_t WakeUpPin)
{
uint32_t temp;
temp = READ_BIT(PWR->CR4, WakeUpPin);
return ((temp == (WakeUpPin))?1U:0U);
}
/**
* @brief Enable GPIO pull-up state in Standby and Shutdown modes
* @rmtoll PUCRA PU0-15 LL_PWR_EnableGPIOPullUp\n
* PUCRB PU0-15 LL_PWR_EnableGPIOPullUp\n
* PUCRC PU0-15 LL_PWR_EnableGPIOPullUp\n
* PUCRD PU0-15 LL_PWR_EnableGPIOPullUp\n
* PUCRE PU0-15 LL_PWR_EnableGPIOPullUp\n
* PUCRF PU0-15 LL_PWR_EnableGPIOPullUp\n
* PUCRG PU0-15 LL_PWR_EnableGPIOPullUp\n
* @param GPIO This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_A
* @arg @ref LL_PWR_GPIO_B
* @arg @ref LL_PWR_GPIO_C
* @arg @ref LL_PWR_GPIO_D
* @arg @ref LL_PWR_GPIO_E
* @arg @ref LL_PWR_GPIO_F
* @arg @ref LL_PWR_GPIO_G
*
* (*) value not defined in all devices
* @param GPIONumber This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_BIT_0
* @arg @ref LL_PWR_GPIO_BIT_1
* @arg @ref LL_PWR_GPIO_BIT_2
* @arg @ref LL_PWR_GPIO_BIT_3
* @arg @ref LL_PWR_GPIO_BIT_4
* @arg @ref LL_PWR_GPIO_BIT_5
* @arg @ref LL_PWR_GPIO_BIT_6
* @arg @ref LL_PWR_GPIO_BIT_7
* @arg @ref LL_PWR_GPIO_BIT_8
* @arg @ref LL_PWR_GPIO_BIT_9
* @arg @ref LL_PWR_GPIO_BIT_10
* @arg @ref LL_PWR_GPIO_BIT_11
* @arg @ref LL_PWR_GPIO_BIT_12
* @arg @ref LL_PWR_GPIO_BIT_13
* @arg @ref LL_PWR_GPIO_BIT_14
* @arg @ref LL_PWR_GPIO_BIT_15
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableGPIOPullUp(uint32_t GPIO, uint32_t GPIONumber)
{
SET_BIT(*((__IO uint32_t *)GPIO), GPIONumber);
}
/**
* @brief Disable GPIO pull-up state in Standby and Shutdown modes
* @rmtoll PUCRA PU0-15 LL_PWR_DisableGPIOPullUp\n
* PUCRB PU0-15 LL_PWR_DisableGPIOPullUp\n
* PUCRC PU0-15 LL_PWR_DisableGPIOPullUp\n
* PUCRD PU0-15 LL_PWR_DisableGPIOPullUp\n
* PUCRE PU0-15 LL_PWR_DisableGPIOPullUp\n
* PUCRF PU0-15 LL_PWR_DisableGPIOPullUp\n
* PUCRG PU0-15 LL_PWR_DisableGPIOPullUp\n
* @param GPIO This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_A
* @arg @ref LL_PWR_GPIO_B
* @arg @ref LL_PWR_GPIO_C
* @arg @ref LL_PWR_GPIO_D
* @arg @ref LL_PWR_GPIO_E
* @arg @ref LL_PWR_GPIO_F
* @arg @ref LL_PWR_GPIO_G
*
* (*) value not defined in all devices
* @param GPIONumber This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_BIT_0
* @arg @ref LL_PWR_GPIO_BIT_1
* @arg @ref LL_PWR_GPIO_BIT_2
* @arg @ref LL_PWR_GPIO_BIT_3
* @arg @ref LL_PWR_GPIO_BIT_4
* @arg @ref LL_PWR_GPIO_BIT_5
* @arg @ref LL_PWR_GPIO_BIT_6
* @arg @ref LL_PWR_GPIO_BIT_7
* @arg @ref LL_PWR_GPIO_BIT_8
* @arg @ref LL_PWR_GPIO_BIT_9
* @arg @ref LL_PWR_GPIO_BIT_10
* @arg @ref LL_PWR_GPIO_BIT_11
* @arg @ref LL_PWR_GPIO_BIT_12
* @arg @ref LL_PWR_GPIO_BIT_13
* @arg @ref LL_PWR_GPIO_BIT_14
* @arg @ref LL_PWR_GPIO_BIT_15
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableGPIOPullUp(uint32_t GPIO, uint32_t GPIONumber)
{
CLEAR_BIT(*((__IO uint32_t *)GPIO), GPIONumber);
}
/**
* @brief Check if GPIO pull-up state is enabled
* @rmtoll PUCRA PU0-15 LL_PWR_IsEnabledGPIOPullUp\n
* PUCRB PU0-15 LL_PWR_IsEnabledGPIOPullUp\n
* PUCRC PU0-15 LL_PWR_IsEnabledGPIOPullUp\n
* PUCRD PU0-15 LL_PWR_IsEnabledGPIOPullUp\n
* PUCRE PU0-15 LL_PWR_IsEnabledGPIOPullUp\n
* PUCRF PU0-15 LL_PWR_IsEnabledGPIOPullUp\n
* PUCRG PU0-15 LL_PWR_IsEnabledGPIOPullUp\n
* @param GPIO This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_A
* @arg @ref LL_PWR_GPIO_B
* @arg @ref LL_PWR_GPIO_C
* @arg @ref LL_PWR_GPIO_D
* @arg @ref LL_PWR_GPIO_E
* @arg @ref LL_PWR_GPIO_F
* @arg @ref LL_PWR_GPIO_G
*
* (*) value not defined in all devices
* @param GPIONumber This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_BIT_0
* @arg @ref LL_PWR_GPIO_BIT_1
* @arg @ref LL_PWR_GPIO_BIT_2
* @arg @ref LL_PWR_GPIO_BIT_3
* @arg @ref LL_PWR_GPIO_BIT_4
* @arg @ref LL_PWR_GPIO_BIT_5
* @arg @ref LL_PWR_GPIO_BIT_6
* @arg @ref LL_PWR_GPIO_BIT_7
* @arg @ref LL_PWR_GPIO_BIT_8
* @arg @ref LL_PWR_GPIO_BIT_9
* @arg @ref LL_PWR_GPIO_BIT_10
* @arg @ref LL_PWR_GPIO_BIT_11
* @arg @ref LL_PWR_GPIO_BIT_12
* @arg @ref LL_PWR_GPIO_BIT_13
* @arg @ref LL_PWR_GPIO_BIT_14
* @arg @ref LL_PWR_GPIO_BIT_15
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledGPIOPullUp(uint32_t GPIO, uint32_t GPIONumber)
{
return ((READ_BIT(*((__IO uint32_t *)GPIO), GPIONumber) == (GPIONumber)) ? 1UL : 0UL);
}
/**
* @brief Enable GPIO pull-down state in Standby and Shutdown modes
* @rmtoll PDCRA PD0-15 LL_PWR_EnableGPIOPullDown\n
* PDCRB PD0-15 LL_PWR_EnableGPIOPullDown\n
* PDCRC PD0-15 LL_PWR_EnableGPIOPullDown\n
* PDCRD PD0-15 LL_PWR_EnableGPIOPullDown\n
* PDCRE PD0-15 LL_PWR_EnableGPIOPullDown\n
* PDCRF PD0-15 LL_PWR_EnableGPIOPullDown\n
* PDCRG PD0-15 LL_PWR_EnableGPIOPullDown\n
* @param GPIO This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_A
* @arg @ref LL_PWR_GPIO_B
* @arg @ref LL_PWR_GPIO_C
* @arg @ref LL_PWR_GPIO_D
* @arg @ref LL_PWR_GPIO_E
* @arg @ref LL_PWR_GPIO_F
* @arg @ref LL_PWR_GPIO_G
*
* (*) value not defined in all devices
* @param GPIONumber This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_BIT_0
* @arg @ref LL_PWR_GPIO_BIT_1
* @arg @ref LL_PWR_GPIO_BIT_2
* @arg @ref LL_PWR_GPIO_BIT_3
* @arg @ref LL_PWR_GPIO_BIT_4
* @arg @ref LL_PWR_GPIO_BIT_5
* @arg @ref LL_PWR_GPIO_BIT_6
* @arg @ref LL_PWR_GPIO_BIT_7
* @arg @ref LL_PWR_GPIO_BIT_8
* @arg @ref LL_PWR_GPIO_BIT_9
* @arg @ref LL_PWR_GPIO_BIT_10
* @arg @ref LL_PWR_GPIO_BIT_11
* @arg @ref LL_PWR_GPIO_BIT_12
* @arg @ref LL_PWR_GPIO_BIT_13
* @arg @ref LL_PWR_GPIO_BIT_14
* @arg @ref LL_PWR_GPIO_BIT_15
* @retval None
*/
__STATIC_INLINE void LL_PWR_EnableGPIOPullDown(uint32_t GPIO, uint32_t GPIONumber)
{
SET_BIT(*((__IO uint32_t *)(GPIO + 4U)), GPIONumber);
}
/**
* @brief Disable GPIO pull-down state in Standby and Shutdown modes
* @rmtoll PDCRA PD0-15 LL_PWR_DisableGPIOPullDown\n
* PDCRB PD0-15 LL_PWR_DisableGPIOPullDown\n
* PDCRC PD0-15 LL_PWR_DisableGPIOPullDown\n
* PDCRD PD0-15 LL_PWR_DisableGPIOPullDown\n
* PDCRE PD0-15 LL_PWR_DisableGPIOPullDown\n
* PDCRF PD0-15 LL_PWR_DisableGPIOPullDown\n
* PDCRG PD0-15 LL_PWR_DisableGPIOPullDown\n
* @param GPIO This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_A
* @arg @ref LL_PWR_GPIO_B
* @arg @ref LL_PWR_GPIO_C
* @arg @ref LL_PWR_GPIO_D
* @arg @ref LL_PWR_GPIO_E
* @arg @ref LL_PWR_GPIO_F
* @arg @ref LL_PWR_GPIO_G
*
* (*) value not defined in all devices
* @param GPIONumber This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_BIT_0
* @arg @ref LL_PWR_GPIO_BIT_1
* @arg @ref LL_PWR_GPIO_BIT_2
* @arg @ref LL_PWR_GPIO_BIT_3
* @arg @ref LL_PWR_GPIO_BIT_4
* @arg @ref LL_PWR_GPIO_BIT_5
* @arg @ref LL_PWR_GPIO_BIT_6
* @arg @ref LL_PWR_GPIO_BIT_7
* @arg @ref LL_PWR_GPIO_BIT_8
* @arg @ref LL_PWR_GPIO_BIT_9
* @arg @ref LL_PWR_GPIO_BIT_10
* @arg @ref LL_PWR_GPIO_BIT_11
* @arg @ref LL_PWR_GPIO_BIT_12
* @arg @ref LL_PWR_GPIO_BIT_13
* @arg @ref LL_PWR_GPIO_BIT_14
* @arg @ref LL_PWR_GPIO_BIT_15
* @retval None
*/
__STATIC_INLINE void LL_PWR_DisableGPIOPullDown(uint32_t GPIO, uint32_t GPIONumber)
{
CLEAR_BIT(*((__IO uint32_t *)(GPIO + 4U)), GPIONumber);
}
/**
* @brief Check if GPIO pull-down state is enabled
* @rmtoll PDCRA PD0-15 LL_PWR_IsEnabledGPIOPullDown\n
* PDCRB PD0-15 LL_PWR_IsEnabledGPIOPullDown\n
* PDCRC PD0-15 LL_PWR_IsEnabledGPIOPullDown\n
* PDCRD PD0-15 LL_PWR_IsEnabledGPIOPullDown\n
* PDCRE PD0-15 LL_PWR_IsEnabledGPIOPullDown\n
* PDCRF PD0-15 LL_PWR_IsEnabledGPIOPullDown\n
* PDCRG PD0-15 LL_PWR_IsEnabledGPIOPullDown\n
* @param GPIO This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_A
* @arg @ref LL_PWR_GPIO_B
* @arg @ref LL_PWR_GPIO_C
* @arg @ref LL_PWR_GPIO_D
* @arg @ref LL_PWR_GPIO_E
* @arg @ref LL_PWR_GPIO_F
* @arg @ref LL_PWR_GPIO_G
*
* (*) value not defined in all devices
* @param GPIONumber This parameter can be one of the following values:
* @arg @ref LL_PWR_GPIO_BIT_0
* @arg @ref LL_PWR_GPIO_BIT_1
* @arg @ref LL_PWR_GPIO_BIT_2
* @arg @ref LL_PWR_GPIO_BIT_3
* @arg @ref LL_PWR_GPIO_BIT_4
* @arg @ref LL_PWR_GPIO_BIT_5
* @arg @ref LL_PWR_GPIO_BIT_6
* @arg @ref LL_PWR_GPIO_BIT_7
* @arg @ref LL_PWR_GPIO_BIT_8
* @arg @ref LL_PWR_GPIO_BIT_9
* @arg @ref LL_PWR_GPIO_BIT_10
* @arg @ref LL_PWR_GPIO_BIT_11
* @arg @ref LL_PWR_GPIO_BIT_12
* @arg @ref LL_PWR_GPIO_BIT_13
* @arg @ref LL_PWR_GPIO_BIT_14
* @arg @ref LL_PWR_GPIO_BIT_15
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsEnabledGPIOPullDown(uint32_t GPIO, uint32_t GPIONumber)
{
return ((READ_BIT(*((__IO uint32_t *)(GPIO + 4U)), GPIONumber) == (GPIONumber)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup PWR_LL_EF_FLAG_Management FLAG_Management
* @{
*/
/**
* @brief Get Internal Wake-up line Flag
* @rmtoll SR1 WUFI LL_PWR_IsActiveFlag_InternWU
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_InternWU(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR1, PWR_SR1_WUFI);
return ((temp == (PWR_SR1_WUFI))?1U:0U);
}
/**
* @brief Get Stand-By Flag
* @rmtoll SR1 SBF LL_PWR_IsActiveFlag_SB
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_SB(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR1, PWR_SR1_SBF);
return ((temp == (PWR_SR1_SBF))?1U:0U);
}
/**
* @brief Get Wake-up Flag 5
* @rmtoll SR1 WUF5 LL_PWR_IsActiveFlag_WU5
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_WU5(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR1, PWR_SR1_WUF5);
return ((temp == (PWR_SR1_WUF5))?1U:0U);
}
/**
* @brief Get Wake-up Flag 4
* @rmtoll SR1 WUF4 LL_PWR_IsActiveFlag_WU4
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_WU4(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR1, PWR_SR1_WUF4);
return ((temp == (PWR_SR1_WUF4))?1U:0U);
}
/**
* @brief Get Wake-up Flag 3
* @rmtoll SR1 WUF3 LL_PWR_IsActiveFlag_WU3
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_WU3(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR1, PWR_SR1_WUF3);
return ((temp == (PWR_SR1_WUF3))?1U:0U);
}
/**
* @brief Get Wake-up Flag 2
* @rmtoll SR1 WUF2 LL_PWR_IsActiveFlag_WU2
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_WU2(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR1, PWR_SR1_WUF2);
return ((temp == (PWR_SR1_WUF2))?1U:0U);
}
/**
* @brief Get Wake-up Flag 1
* @rmtoll SR1 WUF1 LL_PWR_IsActiveFlag_WU1
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_WU1(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR1, PWR_SR1_WUF1);
return ((temp == (PWR_SR1_WUF1))?1U:0U);
}
/**
* @brief Clear Stand-By Flag
* @rmtoll SCR CSBF LL_PWR_ClearFlag_SB
* @retval None
*/
__STATIC_INLINE void LL_PWR_ClearFlag_SB(void)
{
WRITE_REG(PWR->SCR, PWR_SCR_CSBF);
}
/**
* @brief Clear Wake-up Flags
* @rmtoll SCR CWUF LL_PWR_ClearFlag_WU
* @retval None
*/
__STATIC_INLINE void LL_PWR_ClearFlag_WU(void)
{
WRITE_REG(PWR->SCR, PWR_SCR_CWUF);
}
/**
* @brief Clear Wake-up Flag 5
* @rmtoll SCR CWUF5 LL_PWR_ClearFlag_WU5
* @retval None
*/
__STATIC_INLINE void LL_PWR_ClearFlag_WU5(void)
{
WRITE_REG(PWR->SCR, PWR_SCR_CWUF5);
}
/**
* @brief Clear Wake-up Flag 4
* @rmtoll SCR CWUF4 LL_PWR_ClearFlag_WU4
* @retval None
*/
__STATIC_INLINE void LL_PWR_ClearFlag_WU4(void)
{
WRITE_REG(PWR->SCR, PWR_SCR_CWUF4);
}
/**
* @brief Clear Wake-up Flag 3
* @rmtoll SCR CWUF3 LL_PWR_ClearFlag_WU3
* @retval None
*/
__STATIC_INLINE void LL_PWR_ClearFlag_WU3(void)
{
WRITE_REG(PWR->SCR, PWR_SCR_CWUF3);
}
/**
* @brief Clear Wake-up Flag 2
* @rmtoll SCR CWUF2 LL_PWR_ClearFlag_WU2
* @retval None
*/
__STATIC_INLINE void LL_PWR_ClearFlag_WU2(void)
{
WRITE_REG(PWR->SCR, PWR_SCR_CWUF2);
}
/**
* @brief Clear Wake-up Flag 1
* @rmtoll SCR CWUF1 LL_PWR_ClearFlag_WU1
* @retval None
*/
__STATIC_INLINE void LL_PWR_ClearFlag_WU1(void)
{
WRITE_REG(PWR->SCR, PWR_SCR_CWUF1);
}
/**
* @brief Indicate whether VDDA voltage is below or above PVM4 threshold
* @rmtoll SR2 PVMO4 LL_PWR_IsActiveFlag_PVMO4
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_PVMO4(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_PVMO4);
return ((temp == (PWR_SR2_PVMO4))?1U:0U);
}
/**
* @brief Indicate whether VDDA voltage is below or above PVM3 threshold
* @rmtoll SR2 PVMO3 LL_PWR_IsActiveFlag_PVMO3
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_PVMO3(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_PVMO3);
return ((temp == (PWR_SR2_PVMO3))?1U:0U);
}
#if defined(PWR_SR2_PVMO2)
/**
* @brief Indicate whether VDDIO2 voltage is below or above PVM2 threshold
* @rmtoll SR2 PVMO2 LL_PWR_IsActiveFlag_PVMO2
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_PVMO2(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_PVMO2);
return ((temp == (PWR_SR2_PVMO2))?1U:0U);
}
#endif /* PWR_SR2_PVMO2 */
#if defined(PWR_SR2_PVMO1)
/**
* @brief Indicate whether VDDUSB voltage is below or above PVM1 threshold
* @rmtoll SR2 PVMO1 LL_PWR_IsActiveFlag_PVMO1
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_PVMO1(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_PVMO1);
return ((temp == (PWR_SR2_PVMO1))?1U:0U);
}
#endif /* PWR_SR2_PVMO1 */
/**
* @brief Indicate whether VDD voltage is below or above the selected PVD threshold
* @rmtoll SR2 PVDO LL_PWR_IsActiveFlag_PVDO
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_PVDO(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_PVDO);
return ((temp == (PWR_SR2_PVDO))?1U:0U);
}
/**
* @brief Indicate whether the regulator is ready in the selected voltage range or if its output voltage is still changing to the required voltage level
* @rmtoll SR2 VOSF LL_PWR_IsActiveFlag_VOS
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_VOS(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_VOSF);
return ((temp == (PWR_SR2_VOSF))?1U:0U);
}
/**
* @brief Indicate whether the regulator is ready in main mode or is in low-power mode
* @note: Take care, return value "0" means the regulator is ready. Return value "1" means the output voltage range is still changing.
* @rmtoll SR2 REGLPF LL_PWR_IsActiveFlag_REGLPF
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_REGLPF(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_REGLPF);
return ((temp == (PWR_SR2_REGLPF))?1U:0U);
}
/**
* @brief Indicate whether or not the low-power regulator is ready
* @rmtoll SR2 REGLPS LL_PWR_IsActiveFlag_REGLPS
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_PWR_IsActiveFlag_REGLPS(void)
{
uint32_t temp;
temp = READ_BIT(PWR->SR2, PWR_SR2_REGLPS);
return ((temp == (PWR_SR2_REGLPS))?1U:0U);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup PWR_LL_EF_Init De-initialization function
* @{
*/
ErrorStatus LL_PWR_DeInit(void);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/** @defgroup PWR_LL_EF_Legacy_Functions Legacy functions name
* @{
*/
/* Old functions name kept for legacy purpose, to be replaced by the */
/* current functions name. */
#define LL_PWR_IsActiveFlag_VOSF LL_PWR_IsActiveFlag_VOS
#define LL_PWR_EnableUSBDeadBattery LL_PWR_EnableUCPDDeadBattery
#define LL_PWR_DisableUSBDeadBattery LL_PWR_DisableUCPDDeadBattery
#define LL_PWR_IsEnabledUSBDeadBattery LL_PWR_IsEnabledUCPDDeadBattery
#define LL_PWR_EnableDeadBatteryPD LL_PWR_EnableUCPDDeadBattery
#define LL_PWR_DisableDeadBatteryPD LL_PWR_DisableUCPDDeadBattery
#define LL_PWR_EnableUSBStandByModePD LL_PWR_EnableUCPDStandbyMode
#define LL_PWR_EnableStandByModePD LL_PWR_EnableUCPDStandbyMode
#define LL_PWR_DisableUSBStandByModePD LL_PWR_DisableUCPDStandbyMode
#define LL_PWR_DisableStandByModePD LL_PWR_DisableUCPDStandbyMode
#define LL_PWR_IsEnabledUSBStandByModePD LL_PWR_IsEnabledUCPDStandbyMode
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* defined(PWR) */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_PWR_H */
| 50,932 | C | 30.77355 | 154 | 0.578909 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_flash_ramfunc.h | /**
******************************************************************************
* @file stm32g4xx_hal_flash_ramfunc.h
* @author MCD Application Team
* @brief Header file of FLASH RAMFUNC driver.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_FLASH_RAMFUNC_H
#define STM32G4xx_FLASH_RAMFUNC_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup FLASH_RAMFUNC
* @{
*/
/* Exported types ------------------------------------------------------------*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup FLASH_RAMFUNC_Exported_Functions
* @{
*/
/** @addtogroup FLASH_RAMFUNC_Exported_Functions_Group1
* @{
*/
/* Peripheral Control functions ************************************************/
__RAM_FUNC HAL_StatusTypeDef HAL_FLASHEx_EnableRunPowerDown(void);
__RAM_FUNC HAL_StatusTypeDef HAL_FLASHEx_DisableRunPowerDown(void);
#if defined (FLASH_OPTR_DBANK)
__RAM_FUNC HAL_StatusTypeDef HAL_FLASHEx_OB_DBankConfig(uint32_t DBankConfig);
#endif
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_FLASH_RAMFUNC_H */
| 1,917 | C | 24.573333 | 82 | 0.468962 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_flash.h | /**
******************************************************************************
* @file stm32g4xx_hal_flash.h
* @author MCD Application Team
* @brief Header file of FLASH HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_FLASH_H
#define STM32G4xx_HAL_FLASH_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup FLASH
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup FLASH_Exported_Types FLASH Exported Types
* @{
*/
/**
* @brief FLASH Erase structure definition
*/
typedef struct
{
uint32_t TypeErase; /*!< Mass erase or page erase.
This parameter can be a value of @ref FLASH_Type_Erase */
uint32_t Banks; /*!< Select bank to erase.
This parameter must be a value of @ref FLASH_Banks
(FLASH_BANK_BOTH should be used only for mass erase) */
uint32_t Page; /*!< Initial Flash page to erase when page erase is disabled.
This parameter must be a value between 0 and (max number of pages in the bank - 1)
(eg : 127 for 512KB dual bank) */
uint32_t NbPages; /*!< Number of pages to be erased.
This parameter must be a value between 1 and (max number of pages in the bank - value of initial page)*/
} FLASH_EraseInitTypeDef;
/**
* @brief FLASH Option Bytes Program structure definition
*/
typedef struct
{
uint32_t OptionType; /*!< Option byte to be configured.
This parameter can be a combination of the values of @ref FLASH_OB_Type */
uint32_t WRPArea; /*!< Write protection area to be programmed (used for OPTIONBYTE_WRP).
Only one WRP area could be programmed at the same time.
This parameter can be value of @ref FLASH_OB_WRP_Area */
uint32_t WRPStartOffset; /*!< Write protection start offset (used for OPTIONBYTE_WRP).
This parameter must be a value between 0 and (max number of pages in the bank - 1) */
uint32_t WRPEndOffset; /*!< Write protection end offset (used for OPTIONBYTE_WRP).
This parameter must be a value between WRPStartOffset and (max number of pages in the bank - 1) */
uint32_t RDPLevel; /*!< Set the read protection level.. (used for OPTIONBYTE_RDP).
This parameter can be a value of @ref FLASH_OB_Read_Protection */
uint32_t USERType; /*!< User option byte(s) to be configured (used for OPTIONBYTE_USER).
This parameter can be a combination of @ref FLASH_OB_USER_Type */
uint32_t USERConfig; /*!< Value of the user option byte (used for OPTIONBYTE_USER).
This parameter can be a combination of @ref FLASH_OB_USER_BOR_LEVEL,
@ref FLASH_OB_USER_nRST_STOP, @ref FLASH_OB_USER_nRST_STANDBY,
@ref FLASH_OB_USER_nRST_SHUTDOWN, @ref FLASH_OB_USER_IWDG_SW,
@ref FLASH_OB_USER_IWDG_STOP, @ref FLASH_OB_USER_IWDG_STANDBY,
@ref FLASH_OB_USER_WWDG_SW, @ref FLASH_OB_USER_BFB2 (*),
@ref FLASH_OB_USER_nBOOT1, @ref FLASH_OB_USER_SRAM_PE,
@ref FLASH_OB_USER_CCMSRAM_RST
@note (*) availability depends on devices */
uint32_t PCROPConfig; /*!< Configuration of the PCROP (used for OPTIONBYTE_PCROP).
This parameter must be a combination of @ref FLASH_Banks (except FLASH_BANK_BOTH)
and @ref FLASH_OB_PCROP_RDP */
uint32_t PCROPStartAddr; /*!< PCROP Start address (used for OPTIONBYTE_PCROP).
This parameter must be a value between begin and end of bank
=> Be careful of the bank swapping for the address */
uint32_t PCROPEndAddr; /*!< PCROP End address (used for OPTIONBYTE_PCROP).
This parameter must be a value between PCROP Start address and end of bank */
uint32_t BootEntryPoint; /*!< Set the Boot Lock (used for OPTIONBYTE_BOOT_LOCK).
This parameter can be a value of @ref FLASH_OB_Boot_Lock */
uint32_t SecBank; /*!< Bank of securable memory area to be programmed (used for OPTIONBYTE_SEC).
Only one securable memory area could be programmed at the same time.
This parameter can be one of the following values:
FLASH_BANK_1: Securable memory area to be programmed in bank 1
FLASH_BANK_2: Securable memory area to be programmed in bank 2 (*)
@note (*) availability depends on devices */
uint32_t SecSize; /*!< Size of securable memory area to be programmed (used for OPTIONBYTE_SEC),
in number of pages. Securable memory area is starting from first page of the bank.
Only one securable memory could be programmed at the same time.
This parameter must be a value between 0 and (max number of pages in the bank - 1) */
} FLASH_OBProgramInitTypeDef;
/**
* @brief FLASH Procedure structure definition
*/
typedef enum
{
FLASH_PROC_NONE = 0,
FLASH_PROC_PAGE_ERASE,
FLASH_PROC_MASS_ERASE,
FLASH_PROC_PROGRAM,
FLASH_PROC_PROGRAM_LAST
} FLASH_ProcedureTypeDef;
/**
* @brief FLASH Cache structure definition
*/
typedef enum
{
FLASH_CACHE_DISABLED = 0,
FLASH_CACHE_ICACHE_ENABLED,
FLASH_CACHE_DCACHE_ENABLED,
FLASH_CACHE_ICACHE_DCACHE_ENABLED
} FLASH_CacheTypeDef;
/**
* @brief FLASH handle Structure definition
*/
typedef struct
{
HAL_LockTypeDef Lock; /* FLASH locking object */
__IO uint32_t ErrorCode; /* FLASH error code */
__IO FLASH_ProcedureTypeDef ProcedureOnGoing; /* Internal variable to indicate which procedure is ongoing or not in IT context */
__IO uint32_t Address; /* Internal variable to save address selected for program in IT context */
__IO uint32_t Bank; /* Internal variable to save current bank selected during erase in IT context */
__IO uint32_t Page; /* Internal variable to define the current page which is erasing in IT context */
__IO uint32_t NbPagesToErase; /* Internal variable to save the remaining pages to erase in IT context */
__IO FLASH_CacheTypeDef CacheToReactivate; /* Internal variable to indicate which caches should be reactivated */
} FLASH_ProcessTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup FLASH_Exported_Constants FLASH Exported Constants
* @{
*/
/** @defgroup FLASH_Error FLASH Error
* @{
*/
#define HAL_FLASH_ERROR_NONE 0x00000000U
#define HAL_FLASH_ERROR_OP FLASH_FLAG_OPERR
#define HAL_FLASH_ERROR_PROG FLASH_FLAG_PROGERR
#define HAL_FLASH_ERROR_WRP FLASH_FLAG_WRPERR
#define HAL_FLASH_ERROR_PGA FLASH_FLAG_PGAERR
#define HAL_FLASH_ERROR_SIZ FLASH_FLAG_SIZERR
#define HAL_FLASH_ERROR_PGS FLASH_FLAG_PGSERR
#define HAL_FLASH_ERROR_MIS FLASH_FLAG_MISERR
#define HAL_FLASH_ERROR_FAST FLASH_FLAG_FASTERR
#define HAL_FLASH_ERROR_RD FLASH_FLAG_RDERR
#define HAL_FLASH_ERROR_OPTV FLASH_FLAG_OPTVERR
#define HAL_FLASH_ERROR_ECCC FLASH_FLAG_ECCC
#define HAL_FLASH_ERROR_ECCD FLASH_FLAG_ECCD
#if defined (FLASH_OPTR_DBANK)
#define HAL_FLASH_ERROR_ECCC2 FLASH_FLAG_ECCC2
#define HAL_FLASH_ERROR_ECCD2 FLASH_FLAG_ECCD2
#endif
/**
* @}
*/
/** @defgroup FLASH_Type_Erase FLASH Erase Type
* @{
*/
#define FLASH_TYPEERASE_PAGES 0x00U /*!<Pages erase only*/
#define FLASH_TYPEERASE_MASSERASE 0x01U /*!<Flash mass erase activation*/
/**
* @}
*/
/** @defgroup FLASH_Banks FLASH Banks
* @{
*/
#define FLASH_BANK_1 0x00000001U /*!< Bank 1 */
#if defined (FLASH_OPTR_DBANK)
#define FLASH_BANK_2 0x00000002U /*!< Bank 2 */
#define FLASH_BANK_BOTH (FLASH_BANK_1 | FLASH_BANK_2) /*!< Bank1 and Bank2 */
#else
#define FLASH_BANK_BOTH FLASH_BANK_1 /*!< Bank 1 */
#endif
/**
* @}
*/
/** @defgroup FLASH_Type_Program FLASH Program Type
* @{
*/
#define FLASH_TYPEPROGRAM_DOUBLEWORD 0x00U /*!< Program a double-word (64-bit) at a specified address.*/
#define FLASH_TYPEPROGRAM_FAST 0x01U /*!< Fast program a 32 row double-word (64-bit) at a specified address.
And another 32 row double-word (64-bit) will be programmed */
#define FLASH_TYPEPROGRAM_FAST_AND_LAST 0x02U /*!< Fast program a 32 row double-word (64-bit) at a specified address.
And this is the last 32 row double-word (64-bit) programmed */
/**
* @}
*/
/** @defgroup FLASH_OB_Type FLASH Option Bytes Type
* @{
*/
#define OPTIONBYTE_WRP 0x01U /*!< WRP option byte configuration */
#define OPTIONBYTE_RDP 0x02U /*!< RDP option byte configuration */
#define OPTIONBYTE_USER 0x04U /*!< USER option byte configuration */
#define OPTIONBYTE_PCROP 0x08U /*!< PCROP option byte configuration */
#define OPTIONBYTE_BOOT_LOCK 0x10U /*!< Boot lock option byte configuration */
#define OPTIONBYTE_SEC 0x20U /*!< Securable memory option byte configuration */
/**
* @}
*/
/** @defgroup FLASH_OB_WRP_Area FLASH WRP Area
* @{
*/
#define OB_WRPAREA_BANK1_AREAA 0x00U /*!< Flash Bank 1 Area A */
#define OB_WRPAREA_BANK1_AREAB 0x01U /*!< Flash Bank 1 Area B */
#if defined (FLASH_OPTR_DBANK)
#define OB_WRPAREA_BANK2_AREAA 0x02U /*!< Flash Bank 2 Area A */
#define OB_WRPAREA_BANK2_AREAB 0x04U /*!< Flash Bank 2 Area B */
#endif
/**
* @}
*/
/** @defgroup FLASH_OB_Boot_Lock FLASH Boot Lock
* @{
*/
#define OB_BOOT_LOCK_DISABLE 0x00000000U /*!< Boot Lock Disable */
#define OB_BOOT_LOCK_ENABLE FLASH_SEC1R_BOOT_LOCK /*!< Boot Lock Enable */
/**
* @}
*/
/** @defgroup FLASH_OB_Read_Protection FLASH Option Bytes Read Protection
* @{
*/
#define OB_RDP_LEVEL_0 0xAAU
#define OB_RDP_LEVEL_1 0xBBU
#define OB_RDP_LEVEL_2 0xCCU /*!< Warning: When enabling read protection level 2
it's no more possible to go back to level 1 or 0 */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_Type FLASH Option Bytes User Type
* @{
*/
#define OB_USER_BOR_LEV 0x00000001U /*!< BOR reset Level */
#define OB_USER_nRST_STOP 0x00000002U /*!< Reset generated when entering the stop mode */
#define OB_USER_nRST_STDBY 0x00000004U /*!< Reset generated when entering the standby mode */
#define OB_USER_IWDG_SW 0x00000008U /*!< Independent watchdog selection */
#define OB_USER_IWDG_STOP 0x00000010U /*!< Independent watchdog counter freeze in stop mode */
#define OB_USER_IWDG_STDBY 0x00000020U /*!< Independent watchdog counter freeze in standby mode */
#define OB_USER_WWDG_SW 0x00000040U /*!< Window watchdog selection */
#if defined (FLASH_OPTR_DBANK)
#define OB_USER_BFB2 0x00000080U /*!< Dual-bank boot */
#define OB_USER_DBANK 0x00000100U /*!< Single bank with 128-bits data or two banks with 64-bits data */
#endif
#if defined (FLASH_OPTR_PB4_PUPEN)
#define OB_USER_PB4_PUPEN 0x00000100U /*!< USB power delivery dead-battery/TDI pull-up */
#endif
#define OB_USER_nBOOT1 0x00000200U /*!< Boot configuration */
#define OB_USER_SRAM_PE 0x00000400U /*!< SRAM parity check enable (first 32kB of SRAM1 + CCM SRAM) */
#define OB_USER_CCMSRAM_RST 0x00000800U /*!< CCMSRAM Erase when system reset */
#define OB_USER_nRST_SHDW 0x00001000U /*!< Reset generated when entering the shutdown mode */
#define OB_USER_nSWBOOT0 0x00002000U /*!< Software BOOT0 */
#define OB_USER_nBOOT0 0x00004000U /*!< nBOOT0 option bit */
#define OB_USER_NRST_MODE 0x00008000U /*!< Reset pin configuration */
#define OB_USER_IRHEN 0x00010000U /*!< Internal Reset Holder enable */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_BOR_LEVEL FLASH Option Bytes User BOR Level
* @{
*/
#define OB_BOR_LEVEL_0 FLASH_OPTR_BOR_LEV_0 /*!< Reset level threshold is around 1.7V */
#define OB_BOR_LEVEL_1 FLASH_OPTR_BOR_LEV_1 /*!< Reset level threshold is around 2.0V */
#define OB_BOR_LEVEL_2 FLASH_OPTR_BOR_LEV_2 /*!< Reset level threshold is around 2.2V */
#define OB_BOR_LEVEL_3 FLASH_OPTR_BOR_LEV_3 /*!< Reset level threshold is around 2.5V */
#define OB_BOR_LEVEL_4 FLASH_OPTR_BOR_LEV_4 /*!< Reset level threshold is around 2.8V */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_nRST_STOP FLASH Option Bytes User Reset On Stop
* @{
*/
#define OB_STOP_RST 0x00000000U /*!< Reset generated when entering the stop mode */
#define OB_STOP_NORST FLASH_OPTR_nRST_STOP /*!< No reset generated when entering the stop mode */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_nRST_STANDBY FLASH Option Bytes User Reset On Standby
* @{
*/
#define OB_STANDBY_RST 0x00000000U /*!< Reset generated when entering the standby mode */
#define OB_STANDBY_NORST FLASH_OPTR_nRST_STDBY /*!< No reset generated when entering the standby mode */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_nRST_SHUTDOWN FLASH Option Bytes User Reset On Shutdown
* @{
*/
#define OB_SHUTDOWN_RST 0x00000000U /*!< Reset generated when entering the shutdown mode */
#define OB_SHUTDOWN_NORST FLASH_OPTR_nRST_SHDW /*!< No reset generated when entering the shutdown mode */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_IWDG_SW FLASH Option Bytes User IWDG Type
* @{
*/
#define OB_IWDG_HW 0x00000000U /*!< Hardware independent watchdog */
#define OB_IWDG_SW FLASH_OPTR_IWDG_SW /*!< Software independent watchdog */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_IWDG_STOP FLASH Option Bytes User IWDG Mode On Stop
* @{
*/
#define OB_IWDG_STOP_FREEZE 0x00000000U /*!< Independent watchdog counter is frozen in Stop mode */
#define OB_IWDG_STOP_RUN FLASH_OPTR_IWDG_STOP /*!< Independent watchdog counter is running in Stop mode */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_IWDG_STANDBY FLASH Option Bytes User IWDG Mode On Standby
* @{
*/
#define OB_IWDG_STDBY_FREEZE 0x00000000U /*!< Independent watchdog counter is frozen in Standby mode */
#define OB_IWDG_STDBY_RUN FLASH_OPTR_IWDG_STDBY /*!< Independent watchdog counter is running in Standby mode */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_WWDG_SW FLASH Option Bytes User WWDG Type
* @{
*/
#define OB_WWDG_HW 0x00000000U /*!< Hardware window watchdog */
#define OB_WWDG_SW FLASH_OPTR_WWDG_SW /*!< Software window watchdog */
/**
* @}
*/
#if defined (FLASH_OPTR_DBANK)
/** @defgroup FLASH_OB_USER_BFB2 FLASH Option Bytes User BFB2 Mode
* @{
*/
#define OB_BFB2_DISABLE 0x00000000U /*!< Dual-bank boot disable */
#define OB_BFB2_ENABLE FLASH_OPTR_BFB2 /*!< Dual-bank boot enable */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_DBANK FLASH Option Bytes User DBANK Type
* @{
*/
#define OB_DBANK_128_BITS 0x00000000U /*!< Single-bank with 128-bits data */
#define OB_DBANK_64_BITS FLASH_OPTR_DBANK /*!< Dual-bank with 64-bits data */
/**
* @}
*/
#endif
#if defined (FLASH_OPTR_PB4_PUPEN)
/** @defgroup FLASH_OB_USER_PB4_PUPEN FLASH Option Bytes User PB4 PUPEN bit
* @{
*/
#define OB_PB4_PUPEN_DISABLE 0x00000000U /*!< USB power delivery dead-battery enabled/ TDI pull-up deactivated */
#define OB_PB4_PUPEN_ENABLE FLASH_OPTR_PB4_PUPEN /*!< USB power delivery dead-battery disabled/ TDI pull-up activated */
/**
* @}
*/
#endif
/** @defgroup FLASH_OB_USER_nBOOT1 FLASH Option Bytes User BOOT1 Type
* @{
*/
#define OB_BOOT1_SRAM 0x00000000U /*!< Embedded SRAM1 is selected as boot space (if BOOT0=1) */
#define OB_BOOT1_SYSTEM FLASH_OPTR_nBOOT1 /*!< System memory is selected as boot space (if BOOT0=1) */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_SRAM_PE FLASH Option Bytes User SRAM Parity Check Type
* @{
*/
#define OB_SRAM_PARITY_ENABLE 0x00000000U /*!< SRAM parity check enable (first 32kB of SRAM1 + CCM SRAM) */
#define OB_SRAM_PARITY_DISABLE FLASH_OPTR_SRAM_PE /*!< SRAM parity check disable (first 32kB of SRAM1 + CCM SRAM) */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_CCMSRAM_RST FLASH Option Bytes User CCMSRAM Erase On Reset Type
* @{
*/
#define OB_CCMSRAM_RST_ERASE 0x00000000U /*!< CCMSRAM erased when a system reset occurs */
#define OB_CCMSRAM_RST_NOT_ERASE FLASH_OPTR_CCMSRAM_RST /*!< CCMSRAM is not erased when a system reset occurs */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_nSWBOOT0 FLASH Option Bytes User Software BOOT0
* @{
*/
#define OB_BOOT0_FROM_OB 0x00000000U /*!< BOOT0 taken from the option bit nBOOT0 */
#define OB_BOOT0_FROM_PIN FLASH_OPTR_nSWBOOT0 /*!< BOOT0 taken from PB8/BOOT0 pin */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_nBOOT0 FLASH Option Bytes User nBOOT0 option bit
* @{
*/
#define OB_nBOOT0_RESET 0x00000000U /*!< nBOOT0 = 0 */
#define OB_nBOOT0_SET FLASH_OPTR_nBOOT0 /*!< nBOOT0 = 1 */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_NRST_MODE FLASH Option Bytes User NRST mode bit
* @{
*/
#define OB_NRST_MODE_INPUT_ONLY FLASH_OPTR_NRST_MODE_0 /*!< Reset pin is in Reset input mode only */
#define OB_NRST_MODE_GPIO FLASH_OPTR_NRST_MODE_1 /*!< Reset pin is in GPIO mode only */
#define OB_NRST_MODE_INPUT_OUTPUT FLASH_OPTR_NRST_MODE /*!< Reset pin is in reset input and output mode */
/**
* @}
*/
/** @defgroup FLASH_OB_USER_INTERNAL_RESET_HOLDER FLASH Option Bytes User internal reset holder bit
* @{
*/
#define OB_IRH_DISABLE 0x00000000U /*!< Internal Reset holder disable */
#define OB_IRH_ENABLE FLASH_OPTR_IRHEN /*!< Internal Reset holder enable */
/**
* @}
*/
/** @defgroup FLASH_OB_PCROP_RDP FLASH Option Bytes PCROP On RDP Level Type
* @{
*/
#define OB_PCROP_RDP_NOT_ERASE 0x00000000U /*!< PCROP area is not erased when the RDP level
is decreased from Level 1 to Level 0 */
#define OB_PCROP_RDP_ERASE FLASH_PCROP1ER_PCROP_RDP /*!< PCROP area is erased when the RDP level is
decreased from Level 1 to Level 0 (full mass erase) */
/**
* @}
*/
/** @defgroup FLASH_Latency FLASH Latency
* @{
*/
#define FLASH_LATENCY_0 FLASH_ACR_LATENCY_0WS /*!< FLASH Zero wait state */
#define FLASH_LATENCY_1 FLASH_ACR_LATENCY_1WS /*!< FLASH One wait state */
#define FLASH_LATENCY_2 FLASH_ACR_LATENCY_2WS /*!< FLASH Two wait states */
#define FLASH_LATENCY_3 FLASH_ACR_LATENCY_3WS /*!< FLASH Three wait states */
#define FLASH_LATENCY_4 FLASH_ACR_LATENCY_4WS /*!< FLASH Four wait states */
#define FLASH_LATENCY_5 FLASH_ACR_LATENCY_5WS /*!< FLASH Five wait state */
#define FLASH_LATENCY_6 FLASH_ACR_LATENCY_6WS /*!< FLASH Six wait state */
#define FLASH_LATENCY_7 FLASH_ACR_LATENCY_7WS /*!< FLASH Seven wait states */
#define FLASH_LATENCY_8 FLASH_ACR_LATENCY_8WS /*!< FLASH Eight wait states */
#define FLASH_LATENCY_9 FLASH_ACR_LATENCY_9WS /*!< FLASH Nine wait states */
#define FLASH_LATENCY_10 FLASH_ACR_LATENCY_10WS /*!< FLASH Ten wait state */
#define FLASH_LATENCY_11 FLASH_ACR_LATENCY_11WS /*!< FLASH Eleven wait state */
#define FLASH_LATENCY_12 FLASH_ACR_LATENCY_12WS /*!< FLASH Twelve wait states */
#define FLASH_LATENCY_13 FLASH_ACR_LATENCY_13WS /*!< FLASH Thirteen wait states */
#define FLASH_LATENCY_14 FLASH_ACR_LATENCY_14WS /*!< FLASH Fourteen wait states */
#define FLASH_LATENCY_15 FLASH_ACR_LATENCY_15WS /*!< FLASH Fifteen wait states */
/**
* @}
*/
/** @defgroup FLASH_Keys FLASH Keys
* @{
*/
#define FLASH_KEY1 0x45670123U /*!< Flash key1 */
#define FLASH_KEY2 0xCDEF89ABU /*!< Flash key2: used with FLASH_KEY1
to unlock the FLASH registers access */
#define FLASH_PDKEY1 0x04152637U /*!< Flash power down key1 */
#define FLASH_PDKEY2 0xFAFBFCFDU /*!< Flash power down key2: used with FLASH_PDKEY1
to unlock the RUN_PD bit in FLASH_ACR */
#define FLASH_OPTKEY1 0x08192A3BU /*!< Flash option byte key1 */
#define FLASH_OPTKEY2 0x4C5D6E7FU /*!< Flash option byte key2: used with FLASH_OPTKEY1
to allow option bytes operations */
/**
* @}
*/
/** @defgroup FLASH_Flags FLASH Flags Definition
* @{
*/
#define FLASH_FLAG_EOP FLASH_SR_EOP /*!< FLASH End of operation flag */
#define FLASH_FLAG_OPERR FLASH_SR_OPERR /*!< FLASH Operation error flag */
#define FLASH_FLAG_PROGERR FLASH_SR_PROGERR /*!< FLASH Programming error flag */
#define FLASH_FLAG_WRPERR FLASH_SR_WRPERR /*!< FLASH Write protection error flag */
#define FLASH_FLAG_PGAERR FLASH_SR_PGAERR /*!< FLASH Programming alignment error flag */
#define FLASH_FLAG_SIZERR FLASH_SR_SIZERR /*!< FLASH Size error flag */
#define FLASH_FLAG_PGSERR FLASH_SR_PGSERR /*!< FLASH Programming sequence error flag */
#define FLASH_FLAG_MISERR FLASH_SR_MISERR /*!< FLASH Fast programming data miss error flag */
#define FLASH_FLAG_FASTERR FLASH_SR_FASTERR /*!< FLASH Fast programming error flag */
#define FLASH_FLAG_RDERR FLASH_SR_RDERR /*!< FLASH PCROP read error flag */
#define FLASH_FLAG_OPTVERR FLASH_SR_OPTVERR /*!< FLASH Option validity error flag */
#define FLASH_FLAG_BSY FLASH_SR_BSY /*!< FLASH Busy flag */
#define FLASH_FLAG_ECCC FLASH_ECCR_ECCC /*!< FLASH ECC correction in 64 LSB bits */
#define FLASH_FLAG_ECCD FLASH_ECCR_ECCD /*!< FLASH ECC detection in 64 LSB bits */
#if defined (FLASH_OPTR_DBANK)
#define FLASH_FLAG_ECCC2 FLASH_ECCR_ECCC2 /*!< FLASH ECC correction in 64 MSB bits (mode 128 bits only) */
#define FLASH_FLAG_ECCD2 FLASH_ECCR_ECCD2 /*!< FLASH ECC detection in 64 MSB bits (mode 128 bits only) */
#endif
#define FLASH_FLAG_SR_ERRORS (FLASH_FLAG_OPERR | FLASH_FLAG_PROGERR | FLASH_FLAG_WRPERR | \
FLASH_FLAG_PGAERR | FLASH_FLAG_SIZERR | FLASH_FLAG_PGSERR | \
FLASH_FLAG_MISERR | FLASH_FLAG_FASTERR | FLASH_FLAG_RDERR | \
FLASH_FLAG_OPTVERR)
#if defined (FLASH_OPTR_DBANK)
#define FLASH_FLAG_ECCR_ERRORS (FLASH_FLAG_ECCC | FLASH_FLAG_ECCD | FLASH_FLAG_ECCC2 | FLASH_FLAG_ECCD2)
#else
#define FLASH_FLAG_ECCR_ERRORS (FLASH_FLAG_ECCC | FLASH_FLAG_ECCD)
#endif
#define FLASH_FLAG_ALL_ERRORS (FLASH_FLAG_SR_ERRORS | FLASH_FLAG_ECCR_ERRORS)
/**
* @}
*/
/** @defgroup FLASH_Interrupt_definition FLASH Interrupts Definition
* @brief FLASH Interrupt definition
* @{
*/
#define FLASH_IT_EOP FLASH_CR_EOPIE /*!< End of FLASH Operation Interrupt source */
#define FLASH_IT_OPERR FLASH_CR_ERRIE /*!< Error Interrupt source */
#define FLASH_IT_RDERR FLASH_CR_RDERRIE /*!< PCROP Read Error Interrupt source*/
#define FLASH_IT_ECCC (FLASH_ECCR_ECCIE >> 24U) /*!< ECC Correction Interrupt source */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup FLASH_Exported_Macros FLASH Exported Macros
* @brief macros to control FLASH features
* @{
*/
/**
* @brief Set the FLASH Latency.
* @param __LATENCY__ FLASH Latency.
* This parameter can be one of the following values :
* @arg FLASH_LATENCY_0: FLASH Zero wait state
* @arg FLASH_LATENCY_1: FLASH One wait state
* @arg FLASH_LATENCY_2: FLASH Two wait states
* @arg FLASH_LATENCY_3: FLASH Three wait states
* @arg FLASH_LATENCY_4: FLASH Four wait states
* @arg FLASH_LATENCY_5: FLASH Five wait states
* @arg FLASH_LATENCY_6: FLASH Six wait states
* @arg FLASH_LATENCY_7: FLASH Seven wait states
* @arg FLASH_LATENCY_8: FLASH Eight wait states
* @arg FLASH_LATENCY_9: FLASH Nine wait states
* @arg FLASH_LATENCY_10: FLASH Ten wait state
* @arg FLASH_LATENCY_11: FLASH Eleven wait state
* @arg FLASH_LATENCY_12: FLASH Twelve wait states
* @arg FLASH_LATENCY_13: FLASH Thirteen wait states
* @arg FLASH_LATENCY_14: FLASH Fourteen wait states
* @arg FLASH_LATENCY_15: FLASH Fifteen wait states
* @retval None
*/
#define __HAL_FLASH_SET_LATENCY(__LATENCY__) MODIFY_REG(FLASH->ACR, FLASH_ACR_LATENCY, (__LATENCY__))
/**
* @brief Get the FLASH Latency.
* @retval FLASH_Latency.
* This parameter can be one of the following values :
* @arg FLASH_LATENCY_0: FLASH Zero wait state
* @arg FLASH_LATENCY_1: FLASH One wait state
* @arg FLASH_LATENCY_2: FLASH Two wait states
* @arg FLASH_LATENCY_3: FLASH Three wait states
* @arg FLASH_LATENCY_4: FLASH Four wait states
* @arg FLASH_LATENCY_5: FLASH Five wait states
* @arg FLASH_LATENCY_6: FLASH Six wait states
* @arg FLASH_LATENCY_7: FLASH Seven wait states
* @arg FLASH_LATENCY_8: FLASH Eight wait states
* @arg FLASH_LATENCY_9: FLASH Nine wait states
* @arg FLASH_LATENCY_10: FLASH Ten wait state
* @arg FLASH_LATENCY_11: FLASH Eleven wait state
* @arg FLASH_LATENCY_12: FLASH Twelve wait states
* @arg FLASH_LATENCY_13: FLASH Thirteen wait states
* @arg FLASH_LATENCY_14: FLASH Fourteen wait states
* @arg FLASH_LATENCY_15: FLASH Fifteen wait states
*/
#define __HAL_FLASH_GET_LATENCY() READ_BIT(FLASH->ACR, FLASH_ACR_LATENCY)
/**
* @brief Enable the FLASH prefetch buffer.
* @retval None
*/
#define __HAL_FLASH_PREFETCH_BUFFER_ENABLE() SET_BIT(FLASH->ACR, FLASH_ACR_PRFTEN)
/**
* @brief Disable the FLASH prefetch buffer.
* @retval None
*/
#define __HAL_FLASH_PREFETCH_BUFFER_DISABLE() CLEAR_BIT(FLASH->ACR, FLASH_ACR_PRFTEN)
/**
* @brief Enable the FLASH instruction cache.
* @retval none
*/
#define __HAL_FLASH_INSTRUCTION_CACHE_ENABLE() SET_BIT(FLASH->ACR, FLASH_ACR_ICEN)
/**
* @brief Disable the FLASH instruction cache.
* @retval none
*/
#define __HAL_FLASH_INSTRUCTION_CACHE_DISABLE() CLEAR_BIT(FLASH->ACR, FLASH_ACR_ICEN)
/**
* @brief Enable the FLASH data cache.
* @retval none
*/
#define __HAL_FLASH_DATA_CACHE_ENABLE() SET_BIT(FLASH->ACR, FLASH_ACR_DCEN)
/**
* @brief Disable the FLASH data cache.
* @retval none
*/
#define __HAL_FLASH_DATA_CACHE_DISABLE() CLEAR_BIT(FLASH->ACR, FLASH_ACR_DCEN)
/**
* @brief Reset the FLASH instruction Cache.
* @note This function must be used only when the Instruction Cache is disabled.
* @retval None
*/
#define __HAL_FLASH_INSTRUCTION_CACHE_RESET() do { SET_BIT(FLASH->ACR, FLASH_ACR_ICRST); \
CLEAR_BIT(FLASH->ACR, FLASH_ACR_ICRST); \
} while (0)
/**
* @brief Reset the FLASH data Cache.
* @note This function must be used only when the data Cache is disabled.
* @retval None
*/
#define __HAL_FLASH_DATA_CACHE_RESET() do { SET_BIT(FLASH->ACR, FLASH_ACR_DCRST); \
CLEAR_BIT(FLASH->ACR, FLASH_ACR_DCRST); \
} while (0)
/**
* @brief Enable the FLASH power down during Low-power run mode.
* @note Writing this bit to 1, automatically the keys are
* lost and a new unlock sequence is necessary to re-write it to 0.
*/
#define __HAL_FLASH_POWER_DOWN_ENABLE() do { WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY1); \
WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY2); \
SET_BIT(FLASH->ACR, FLASH_ACR_RUN_PD); \
} while (0)
/**
* @brief Disable the FLASH power down during Low-power run mode.
* @note Writing this bit to 0, automatically the keys are
* lost and a new unlock sequence is necessary to re-write it to 1.
*/
#define __HAL_FLASH_POWER_DOWN_DISABLE() do { WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY1); \
WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY2); \
CLEAR_BIT(FLASH->ACR, FLASH_ACR_RUN_PD); \
} while (0)
/**
* @brief Enable the FLASH power down during Low-Power sleep mode
* @retval none
*/
#define __HAL_FLASH_SLEEP_POWERDOWN_ENABLE() SET_BIT(FLASH->ACR, FLASH_ACR_SLEEP_PD)
/**
* @brief Disable the FLASH power down during Low-Power sleep mode
* @retval none
*/
#define __HAL_FLASH_SLEEP_POWERDOWN_DISABLE() CLEAR_BIT(FLASH->ACR, FLASH_ACR_SLEEP_PD)
/**
* @}
*/
/** @defgroup FLASH_Interrupt FLASH Interrupts Macros
* @brief macros to handle FLASH interrupts
* @{
*/
/**
* @brief Enable the specified FLASH interrupt.
* @param __INTERRUPT__ FLASH interrupt
* This parameter can be any combination of the following values:
* @arg FLASH_IT_EOP: End of FLASH Operation Interrupt
* @arg FLASH_IT_OPERR: Error Interrupt
* @arg FLASH_IT_RDERR: PCROP Read Error Interrupt
* @arg FLASH_IT_ECCC: ECC Correction Interrupt
* @retval none
*/
#define __HAL_FLASH_ENABLE_IT(__INTERRUPT__) do { if(((__INTERRUPT__) & FLASH_IT_ECCC) != 0U) { SET_BIT(FLASH->ECCR, FLASH_ECCR_ECCIE); }\
if(((__INTERRUPT__) & (~FLASH_IT_ECCC)) != 0U) { SET_BIT(FLASH->CR, ((__INTERRUPT__) & (~FLASH_IT_ECCC))); }\
} while (0)
/**
* @brief Disable the specified FLASH interrupt.
* @param __INTERRUPT__ FLASH interrupt
* This parameter can be any combination of the following values:
* @arg FLASH_IT_EOP: End of FLASH Operation Interrupt
* @arg FLASH_IT_OPERR: Error Interrupt
* @arg FLASH_IT_RDERR: PCROP Read Error Interrupt
* @arg FLASH_IT_ECCC: ECC Correction Interrupt
* @retval none
*/
#define __HAL_FLASH_DISABLE_IT(__INTERRUPT__) do { if(((__INTERRUPT__) & FLASH_IT_ECCC) != 0U) { CLEAR_BIT(FLASH->ECCR, FLASH_ECCR_ECCIE); }\
if(((__INTERRUPT__) & (~FLASH_IT_ECCC)) != 0U) { CLEAR_BIT(FLASH->CR, ((__INTERRUPT__) & (~FLASH_IT_ECCC))); }\
} while (0)
/**
* @brief Check whether the specified FLASH flag is set or not.
* @param __FLAG__ specifies the FLASH flag to check.
* This parameter can be one of the following values:
* @arg FLASH_FLAG_EOP: FLASH End of Operation flag
* @arg FLASH_FLAG_OPERR: FLASH Operation error flag
* @arg FLASH_FLAG_PROGERR: FLASH Programming error flag
* @arg FLASH_FLAG_WRPERR: FLASH Write protection error flag
* @arg FLASH_FLAG_PGAERR: FLASH Programming alignment error flag
* @arg FLASH_FLAG_SIZERR: FLASH Size error flag
* @arg FLASH_FLAG_PGSERR: FLASH Programming sequence error flag
* @arg FLASH_FLAG_MISERR: FLASH Fast programming data miss error flag
* @arg FLASH_FLAG_FASTERR: FLASH Fast programming error flag
* @arg FLASH_FLAG_RDERR: FLASH PCROP read error flag
* @arg FLASH_FLAG_OPTVERR: FLASH Option validity error flag
* @arg FLASH_FLAG_BSY: FLASH write/erase operations in progress flag
* @arg FLASH_FLAG_ECCC: FLASH one ECC error has been detected and corrected in 64 LSB bits
* @arg FLASH_FLAG_ECCD: FLASH two ECC errors have been detected in 64 LSB bits
* @arg FLASH_FLAG_ECCC2(*): FLASH one ECC error has been detected and corrected in 64 MSB bits (mode 128 bits only)
* @arg FLASH_FLAG_ECCD2(*): FLASH two ECC errors have been detected in 64 MSB bits (mode 128 bits only)
* @note (*) availability depends on devices
* @retval The new state of FLASH_FLAG (SET or RESET).
*/
#define __HAL_FLASH_GET_FLAG(__FLAG__) ((((__FLAG__) & FLASH_FLAG_ECCR_ERRORS) != 0U) ? \
(READ_BIT(FLASH->ECCR, (__FLAG__)) == (__FLAG__)) : \
(READ_BIT(FLASH->SR, (__FLAG__)) == (__FLAG__)))
/**
* @brief Clear the FLASH's pending flags.
* @param __FLAG__ specifies the FLASH flags to clear.
* This parameter can be any combination of the following values:
* @arg FLASH_FLAG_EOP: FLASH End of Operation flag
* @arg FLASH_FLAG_OPERR: FLASH Operation error flag
* @arg FLASH_FLAG_PROGERR: FLASH Programming error flag
* @arg FLASH_FLAG_WRPERR: FLASH Write protection error flag
* @arg FLASH_FLAG_PGAERR: FLASH Programming alignment error flag
* @arg FLASH_FLAG_SIZERR: FLASH Size error flag
* @arg FLASH_FLAG_PGSERR: FLASH Programming sequence error flag
* @arg FLASH_FLAG_MISERR: FLASH Fast programming data miss error flag
* @arg FLASH_FLAG_FASTERR: FLASH Fast programming error flag
* @arg FLASH_FLAG_RDERR: FLASH PCROP read error flag
* @arg FLASH_FLAG_OPTVERR: FLASH Option validity error flag
* @arg FLASH_FLAG_ECCC: FLASH one ECC error has been detected and corrected in 64 LSB bits
* @arg FLASH_FLAG_ECCD: FLASH two ECC errors have been detected in 64 LSB bits
* @arg FLASH_FLAG_ECCC2(*): FLASH one ECC error has been detected and corrected in 64 MSB bits (mode 128 bits only)
* @arg FLASH_FLAG_ECCD2(*): FLASH two ECC errors have been detected in 64 MSB bits (mode 128 bits only)
* @arg FLASH_FLAG_SR_ERRORS: FLASH All SR errors flags
* @arg FLASH_FLAG_ECCR_ERRORS: FLASH All ECCR errors flags
* @note (*) availability depends on devices
* @retval None
*/
#define __HAL_FLASH_CLEAR_FLAG(__FLAG__) do { if(((__FLAG__) & FLASH_FLAG_ECCR_ERRORS) != 0U) { SET_BIT(FLASH->ECCR, ((__FLAG__) & FLASH_FLAG_ECCR_ERRORS)); }\
if(((__FLAG__) & ~(FLASH_FLAG_ECCR_ERRORS)) != 0U) { WRITE_REG(FLASH->SR, ((__FLAG__) & ~(FLASH_FLAG_ECCR_ERRORS))); }\
} while (0)
/**
* @}
*/
/* Include FLASH HAL Extended module */
#include "stm32g4xx_hal_flash_ex.h"
#include "stm32g4xx_hal_flash_ramfunc.h"
/* Exported variables --------------------------------------------------------*/
/** @defgroup FLASH_Exported_Variables FLASH Exported Variables
* @{
*/
extern FLASH_ProcessTypeDef pFlash;
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup FLASH_Exported_Functions
* @{
*/
/* Program operation functions ***********************************************/
/** @addtogroup FLASH_Exported_Functions_Group1
* @{
*/
HAL_StatusTypeDef HAL_FLASH_Program(uint32_t TypeProgram, uint32_t Address, uint64_t Data);
HAL_StatusTypeDef HAL_FLASH_Program_IT(uint32_t TypeProgram, uint32_t Address, uint64_t Data);
/* FLASH IRQ handler method */
void HAL_FLASH_IRQHandler(void);
/* Callbacks in non blocking modes */
void HAL_FLASH_EndOfOperationCallback(uint32_t ReturnValue);
void HAL_FLASH_OperationErrorCallback(uint32_t ReturnValue);
/**
* @}
*/
/* Peripheral Control functions **********************************************/
/** @addtogroup FLASH_Exported_Functions_Group2
* @{
*/
HAL_StatusTypeDef HAL_FLASH_Unlock(void);
HAL_StatusTypeDef HAL_FLASH_Lock(void);
/* Option bytes control */
HAL_StatusTypeDef HAL_FLASH_OB_Unlock(void);
HAL_StatusTypeDef HAL_FLASH_OB_Lock(void);
HAL_StatusTypeDef HAL_FLASH_OB_Launch(void);
/**
* @}
*/
/* Peripheral State functions ************************************************/
/** @addtogroup FLASH_Exported_Functions_Group3
* @{
*/
uint32_t HAL_FLASH_GetError(void);
/**
* @}
*/
/**
* @}
*/
/** @addtogroup FLASH_Private_Functions
* @{
*/
HAL_StatusTypeDef FLASH_WaitForLastOperation(uint32_t Timeout);
/**
* @}
*/
/* Private constants --------------------------------------------------------*/
/** @defgroup FLASH_Private_Constants FLASH Private Constants
* @{
*/
#define FLASH_SIZE_DATA_REGISTER FLASHSIZE_BASE
#if defined (FLASH_OPTR_DBANK)
#define FLASH_SIZE ((((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0xFFFFU)) ? (0x200UL << 10U) : \
(((*((uint32_t *)FLASH_SIZE_DATA_REGISTER)) & 0xFFFFUL) << 10U))
#define FLASH_BANK_SIZE (FLASH_SIZE >> 1)
#define FLASH_PAGE_NB ((FLASH_SIZE == 0x00080000U) ? 128U : \
((FLASH_SIZE == 0x00040000U) ? 64U : 32U))
#define FLASH_PAGE_SIZE_128_BITS 0x1000U /* 4 KB */
#else
#define FLASH_SIZE ((((*((uint16_t *)FLASH_SIZE_DATA_REGISTER)) == 0xFFFFU)) ? (0x80UL << 10U) : \
(((*((uint32_t *)FLASH_SIZE_DATA_REGISTER)) & 0xFFFFUL) << 10U))
#define FLASH_BANK_SIZE (FLASH_SIZE)
#define FLASH_PAGE_NB ((FLASH_SIZE == 0x00080000U) ? 256U : \
((FLASH_SIZE == 0x00040000U) ? 128U : 64U))
#endif
#define FLASH_PAGE_SIZE 0x800U /* 2 KB */
#define FLASH_TIMEOUT_VALUE 1000U /* 1 s */
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup FLASH_Private_Macros FLASH Private Macros
* @{
*/
#define IS_FLASH_TYPEERASE(VALUE) (((VALUE) == FLASH_TYPEERASE_PAGES) || \
((VALUE) == FLASH_TYPEERASE_MASSERASE))
#if defined (FLASH_OPTR_DBANK)
#define IS_FLASH_BANK(BANK) (((BANK) == FLASH_BANK_1) || \
((BANK) == FLASH_BANK_2) || \
((BANK) == FLASH_BANK_BOTH))
#define IS_FLASH_BANK_EXCLUSIVE(BANK) (((BANK) == FLASH_BANK_1) || \
((BANK) == FLASH_BANK_2))
#else
#define IS_FLASH_BANK(BANK) ((BANK) == FLASH_BANK_1)
#define IS_FLASH_BANK_EXCLUSIVE(BANK) ((BANK) == FLASH_BANK_1)
#endif
#define IS_FLASH_TYPEPROGRAM(VALUE) (((VALUE) == FLASH_TYPEPROGRAM_DOUBLEWORD) || \
((VALUE) == FLASH_TYPEPROGRAM_FAST) || \
((VALUE) == FLASH_TYPEPROGRAM_FAST_AND_LAST))
#define IS_FLASH_MAIN_MEM_ADDRESS(ADDRESS) (((ADDRESS) >= FLASH_BASE) && ((ADDRESS) < (FLASH_BASE+FLASH_SIZE)))
#define IS_FLASH_OTP_ADDRESS(ADDRESS) (((ADDRESS) >= 0x1FFF7000U) && ((ADDRESS) <= 0x1FFF73FFU))
#define IS_FLASH_PROGRAM_ADDRESS(ADDRESS) (IS_FLASH_MAIN_MEM_ADDRESS(ADDRESS) || IS_FLASH_OTP_ADDRESS(ADDRESS))
#define IS_FLASH_PAGE(PAGE) ((PAGE) < FLASH_PAGE_NB)
#define IS_OPTIONBYTE(VALUE) (((VALUE) <= (OPTIONBYTE_WRP | OPTIONBYTE_RDP | OPTIONBYTE_USER | OPTIONBYTE_PCROP | \
OPTIONBYTE_BOOT_LOCK | OPTIONBYTE_SEC)))
#if defined (FLASH_OPTR_DBANK)
#define IS_OB_WRPAREA(VALUE) (((VALUE) == OB_WRPAREA_BANK1_AREAA) || ((VALUE) == OB_WRPAREA_BANK1_AREAB) || \
((VALUE) == OB_WRPAREA_BANK2_AREAA) || ((VALUE) == OB_WRPAREA_BANK2_AREAB))
#else
#define IS_OB_WRPAREA(VALUE) (((VALUE) == OB_WRPAREA_BANK1_AREAA) || ((VALUE) == OB_WRPAREA_BANK1_AREAB))
#endif
#define IS_OB_BOOT_LOCK(VALUE) (((VALUE) == OB_BOOT_LOCK_ENABLE) || ((VALUE) == OB_BOOT_LOCK_DISABLE))
#define IS_OB_RDP_LEVEL(LEVEL) (((LEVEL) == OB_RDP_LEVEL_0) ||\
((LEVEL) == OB_RDP_LEVEL_1) ||\
((LEVEL) == OB_RDP_LEVEL_2))
#define IS_OB_USER_TYPE(TYPE) (((TYPE) <= 0x1FFFFU) && ((TYPE) != 0U))
#define IS_OB_USER_BOR_LEVEL(LEVEL) (((LEVEL) == OB_BOR_LEVEL_0) || ((LEVEL) == OB_BOR_LEVEL_1) || \
((LEVEL) == OB_BOR_LEVEL_2) || ((LEVEL) == OB_BOR_LEVEL_3) || \
((LEVEL) == OB_BOR_LEVEL_4))
#define IS_OB_USER_STOP(VALUE) (((VALUE) == OB_STOP_RST) || ((VALUE) == OB_STOP_NORST))
#define IS_OB_USER_STANDBY(VALUE) (((VALUE) == OB_STANDBY_RST) || ((VALUE) == OB_STANDBY_NORST))
#define IS_OB_USER_SHUTDOWN(VALUE) (((VALUE) == OB_SHUTDOWN_RST) || ((VALUE) == OB_SHUTDOWN_NORST))
#define IS_OB_USER_IWDG(VALUE) (((VALUE) == OB_IWDG_HW) || ((VALUE) == OB_IWDG_SW))
#define IS_OB_USER_IWDG_STOP(VALUE) (((VALUE) == OB_IWDG_STOP_FREEZE) || ((VALUE) == OB_IWDG_STOP_RUN))
#define IS_OB_USER_IWDG_STDBY(VALUE) (((VALUE) == OB_IWDG_STDBY_FREEZE) || ((VALUE) == OB_IWDG_STDBY_RUN))
#define IS_OB_USER_WWDG(VALUE) (((VALUE) == OB_WWDG_HW) || ((VALUE) == OB_WWDG_SW))
#if defined (FLASH_OPTR_DBANK)
#define IS_OB_USER_BFB2(VALUE) (((VALUE) == OB_BFB2_DISABLE) || ((VALUE) == OB_BFB2_ENABLE))
#define IS_OB_USER_DBANK(VALUE) (((VALUE) == OB_DBANK_128_BITS) || ((VALUE) == OB_DBANK_64_BITS))
#endif
#if defined (FLASH_OPTR_PB4_PUPEN)
#define IS_OB_USER_PB4_PUPEN(VALUE) (((VALUE) == OB_PB4_PUPEN_DISABLE) || ((VALUE) == OB_PB4_PUPEN_ENABLE))
#endif
#define IS_OB_USER_BOOT1(VALUE) (((VALUE) == OB_BOOT1_SRAM) || ((VALUE) == OB_BOOT1_SYSTEM))
#define IS_OB_USER_SRAM_PARITY(VALUE) (((VALUE) == OB_SRAM_PARITY_ENABLE) || ((VALUE) == OB_SRAM_PARITY_DISABLE))
#define IS_OB_USER_CCMSRAM_RST(VALUE) (((VALUE) == OB_CCMSRAM_RST_ERASE) || ((VALUE) == OB_CCMSRAM_RST_NOT_ERASE))
#define IS_OB_USER_SWBOOT0(VALUE) (((VALUE) == OB_BOOT0_FROM_OB) || ((VALUE) == OB_BOOT0_FROM_PIN))
#define IS_OB_USER_BOOT0(VALUE) (((VALUE) == OB_nBOOT0_RESET) || ((VALUE) == OB_nBOOT0_SET))
#define IS_OB_USER_NRST_MODE(VALUE) (((VALUE) == OB_NRST_MODE_GPIO) || ((VALUE) == OB_NRST_MODE_INPUT_ONLY) || \
((VALUE) == OB_NRST_MODE_INPUT_OUTPUT))
#define IS_OB_USER_IRHEN(VALUE) (((VALUE) == OB_IRH_ENABLE) || ((VALUE) == OB_IRH_DISABLE))
#define IS_OB_PCROP_RDP(VALUE) (((VALUE) == OB_PCROP_RDP_NOT_ERASE) || ((VALUE) == OB_PCROP_RDP_ERASE))
#define IS_OB_SECMEM_SIZE(VALUE) ((VALUE) <= FLASH_PAGE_NB)
#define IS_FLASH_LATENCY(LATENCY) (((LATENCY) == FLASH_LATENCY_0) || ((LATENCY) == FLASH_LATENCY_1) || \
((LATENCY) == FLASH_LATENCY_2) || ((LATENCY) == FLASH_LATENCY_3) || \
((LATENCY) == FLASH_LATENCY_4) || ((LATENCY) == FLASH_LATENCY_5) || \
((LATENCY) == FLASH_LATENCY_6) || ((LATENCY) == FLASH_LATENCY_7) || \
((LATENCY) == FLASH_LATENCY_8) || ((LATENCY) == FLASH_LATENCY_9) || \
((LATENCY) == FLASH_LATENCY_10) || ((LATENCY) == FLASH_LATENCY_11) || \
((LATENCY) == FLASH_LATENCY_12) || ((LATENCY) == FLASH_LATENCY_13) || \
((LATENCY) == FLASH_LATENCY_14) || ((LATENCY) == FLASH_LATENCY_15))
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_FLASH_H */
| 46,691 | C | 44.821393 | 172 | 0.564306 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_dma.h | /**
******************************************************************************
* @file stm32g4xx_ll_dma.h
* @author MCD Application Team
* @brief Header file of DMA LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_LL_DMA_H
#define __STM32G4xx_LL_DMA_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
#include "stm32g4xx_ll_dmamux.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined (DMA1) || defined (DMA2)
/** @defgroup DMA_LL DMA
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup DMA_LL_Private_Variables DMA Private Variables
* @{
*/
/* Array used to get the DMA channel register offset versus channel index LL_DMA_CHANNEL_x */
static const uint8_t CHANNEL_OFFSET_TAB[] =
{
(uint8_t)(DMA1_Channel1_BASE - DMA1_BASE),
(uint8_t)(DMA1_Channel2_BASE - DMA1_BASE),
(uint8_t)(DMA1_Channel3_BASE - DMA1_BASE),
(uint8_t)(DMA1_Channel4_BASE - DMA1_BASE),
(uint8_t)(DMA1_Channel5_BASE - DMA1_BASE),
(uint8_t)(DMA1_Channel6_BASE - DMA1_BASE)
#if defined (DMA1_Channel7)
,
(uint8_t)(DMA1_Channel7_BASE - DMA1_BASE)
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
,
(uint8_t)(DMA1_Channel8_BASE - DMA1_BASE)
#endif /* DMA1_Channel8 */
};
/**
* @}
*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup DMA_LL_Private_Constants DMA Private Constants
* @{
*/
/* Define used to get CSELR register offset */
#define DMA_CSELR_OFFSET (uint32_t)(DMA1_CSELR_BASE - DMA1_BASE)
/* Defines used for the bit position in the register and perform offsets */
#define DMA_POSITION_CSELR_CXS POSITION_VAL(DMA_CSELR_C1S << ((Channel-1U)*4U))
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup DMA_LL_Private_Macros DMA Private Macros
* @{
*/
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported types ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup DMA_LL_ES_INIT DMA Exported Init structure
* @{
*/
typedef struct
{
uint32_t PeriphOrM2MSrcAddress; /*!< Specifies the peripheral base address for DMA transfer
or as Source base address in case of memory to memory transfer direction.
This parameter must be a value between Min_Data = 0 and Max_Data = 0xFFFFFFFF. */
uint32_t MemoryOrM2MDstAddress; /*!< Specifies the memory base address for DMA transfer
or as Destination base address in case of memory to memory transfer direction.
This parameter must be a value between Min_Data = 0 and Max_Data = 0xFFFFFFFF. */
uint32_t Direction; /*!< Specifies if the data will be transferred from memory to peripheral,
from memory to memory or from peripheral to memory.
This parameter can be a value of @ref DMA_LL_EC_DIRECTION
This feature can be modified afterwards using unitary function @ref LL_DMA_SetDataTransferDirection(). */
uint32_t Mode; /*!< Specifies the normal or circular operation mode.
This parameter can be a value of @ref DMA_LL_EC_MODE
@note: The circular buffer mode cannot be used if the memory to memory
data transfer direction is configured on the selected Channel
This feature can be modified afterwards using unitary function @ref LL_DMA_SetMode(). */
uint32_t PeriphOrM2MSrcIncMode; /*!< Specifies whether the Peripheral address or Source address in case of memory to memory transfer direction
is incremented or not.
This parameter can be a value of @ref DMA_LL_EC_PERIPH
This feature can be modified afterwards using unitary function @ref LL_DMA_SetPeriphIncMode(). */
uint32_t MemoryOrM2MDstIncMode; /*!< Specifies whether the Memory address or Destination address in case of memory to memory transfer direction
is incremented or not.
This parameter can be a value of @ref DMA_LL_EC_MEMORY
This feature can be modified afterwards using unitary function @ref LL_DMA_SetMemoryIncMode(). */
uint32_t PeriphOrM2MSrcDataSize; /*!< Specifies the Peripheral data size alignment or Source data size alignment (byte, half word, word)
in case of memory to memory transfer direction.
This parameter can be a value of @ref DMA_LL_EC_PDATAALIGN
This feature can be modified afterwards using unitary function @ref LL_DMA_SetPeriphSize(). */
uint32_t MemoryOrM2MDstDataSize; /*!< Specifies the Memory data size alignment or Destination data size alignment (byte, half word, word)
in case of memory to memory transfer direction.
This parameter can be a value of @ref DMA_LL_EC_MDATAALIGN
This feature can be modified afterwards using unitary function @ref LL_DMA_SetMemorySize(). */
uint32_t NbData; /*!< Specifies the number of data to transfer, in data unit.
The data unit is equal to the source buffer configuration set in PeripheralSize
or MemorySize parameters depending in the transfer direction.
This parameter must be a value between Min_Data = 0 and Max_Data = 0x0000FFFF
This feature can be modified afterwards using unitary function @ref LL_DMA_SetDataLength(). */
uint32_t PeriphRequest; /*!< Specifies the peripheral request.
This parameter can be a value of @ref DMAMUX_LL_EC_REQUEST
This feature can be modified afterwards using unitary function @ref LL_DMA_SetPeriphRequest(). */
uint32_t Priority; /*!< Specifies the channel priority level.
This parameter can be a value of @ref DMA_LL_EC_PRIORITY
This feature can be modified afterwards using unitary function @ref LL_DMA_SetChannelPriorityLevel(). */
} LL_DMA_InitTypeDef;
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup DMA_LL_Exported_Constants DMA Exported Constants
* @{
*/
/** @defgroup DMA_LL_EC_CLEAR_FLAG Clear Flags Defines
* @brief Flags defines which can be used with LL_DMA_WriteReg function
* @{
*/
#define LL_DMA_IFCR_CGIF1 DMA_IFCR_CGIF1 /*!< Channel 1 global flag */
#define LL_DMA_IFCR_CTCIF1 DMA_IFCR_CTCIF1 /*!< Channel 1 transfer complete flag */
#define LL_DMA_IFCR_CHTIF1 DMA_IFCR_CHTIF1 /*!< Channel 1 half transfer flag */
#define LL_DMA_IFCR_CTEIF1 DMA_IFCR_CTEIF1 /*!< Channel 1 transfer error flag */
#define LL_DMA_IFCR_CGIF2 DMA_IFCR_CGIF2 /*!< Channel 2 global flag */
#define LL_DMA_IFCR_CTCIF2 DMA_IFCR_CTCIF2 /*!< Channel 2 transfer complete flag */
#define LL_DMA_IFCR_CHTIF2 DMA_IFCR_CHTIF2 /*!< Channel 2 half transfer flag */
#define LL_DMA_IFCR_CTEIF2 DMA_IFCR_CTEIF2 /*!< Channel 2 transfer error flag */
#define LL_DMA_IFCR_CGIF3 DMA_IFCR_CGIF3 /*!< Channel 3 global flag */
#define LL_DMA_IFCR_CTCIF3 DMA_IFCR_CTCIF3 /*!< Channel 3 transfer complete flag */
#define LL_DMA_IFCR_CHTIF3 DMA_IFCR_CHTIF3 /*!< Channel 3 half transfer flag */
#define LL_DMA_IFCR_CTEIF3 DMA_IFCR_CTEIF3 /*!< Channel 3 transfer error flag */
#define LL_DMA_IFCR_CGIF4 DMA_IFCR_CGIF4 /*!< Channel 4 global flag */
#define LL_DMA_IFCR_CTCIF4 DMA_IFCR_CTCIF4 /*!< Channel 4 transfer complete flag */
#define LL_DMA_IFCR_CHTIF4 DMA_IFCR_CHTIF4 /*!< Channel 4 half transfer flag */
#define LL_DMA_IFCR_CTEIF4 DMA_IFCR_CTEIF4 /*!< Channel 4 transfer error flag */
#define LL_DMA_IFCR_CGIF5 DMA_IFCR_CGIF5 /*!< Channel 5 global flag */
#define LL_DMA_IFCR_CTCIF5 DMA_IFCR_CTCIF5 /*!< Channel 5 transfer complete flag */
#define LL_DMA_IFCR_CHTIF5 DMA_IFCR_CHTIF5 /*!< Channel 5 half transfer flag */
#define LL_DMA_IFCR_CTEIF5 DMA_IFCR_CTEIF5 /*!< Channel 5 transfer error flag */
#define LL_DMA_IFCR_CGIF6 DMA_IFCR_CGIF6 /*!< Channel 6 global flag */
#define LL_DMA_IFCR_CTCIF6 DMA_IFCR_CTCIF6 /*!< Channel 6 transfer complete flag */
#define LL_DMA_IFCR_CHTIF6 DMA_IFCR_CHTIF6 /*!< Channel 6 half transfer flag */
#define LL_DMA_IFCR_CTEIF6 DMA_IFCR_CTEIF6 /*!< Channel 6 transfer error flag */
#if defined (DMA1_Channel7)
#define LL_DMA_IFCR_CGIF7 DMA_IFCR_CGIF7 /*!< Channel 7 global flag */
#define LL_DMA_IFCR_CTCIF7 DMA_IFCR_CTCIF7 /*!< Channel 7 transfer complete flag */
#define LL_DMA_IFCR_CHTIF7 DMA_IFCR_CHTIF7 /*!< Channel 7 half transfer flag */
#define LL_DMA_IFCR_CTEIF7 DMA_IFCR_CTEIF7 /*!< Channel 7 transfer error flag */
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
#define LL_DMA_IFCR_CGIF8 DMA_IFCR_CGIF8 /*!< Channel 8 global flag */
#define LL_DMA_IFCR_CTCIF8 DMA_IFCR_CTCIF8 /*!< Channel 8 transfer complete flag */
#define LL_DMA_IFCR_CHTIF8 DMA_IFCR_CHTIF8 /*!< Channel 8 half transfer flag */
#define LL_DMA_IFCR_CTEIF8 DMA_IFCR_CTEIF8 /*!< Channel 8 transfer error flag */
#endif /* DMA1_Channel8 */
/**
* @}
*/
/** @defgroup DMA_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_DMA_ReadReg function
* @{
*/
#define LL_DMA_ISR_GIF1 DMA_ISR_GIF1 /*!< Channel 1 global flag */
#define LL_DMA_ISR_TCIF1 DMA_ISR_TCIF1 /*!< Channel 1 transfer complete flag */
#define LL_DMA_ISR_HTIF1 DMA_ISR_HTIF1 /*!< Channel 1 half transfer flag */
#define LL_DMA_ISR_TEIF1 DMA_ISR_TEIF1 /*!< Channel 1 transfer error flag */
#define LL_DMA_ISR_GIF2 DMA_ISR_GIF2 /*!< Channel 2 global flag */
#define LL_DMA_ISR_TCIF2 DMA_ISR_TCIF2 /*!< Channel 2 transfer complete flag */
#define LL_DMA_ISR_HTIF2 DMA_ISR_HTIF2 /*!< Channel 2 half transfer flag */
#define LL_DMA_ISR_TEIF2 DMA_ISR_TEIF2 /*!< Channel 2 transfer error flag */
#define LL_DMA_ISR_GIF3 DMA_ISR_GIF3 /*!< Channel 3 global flag */
#define LL_DMA_ISR_TCIF3 DMA_ISR_TCIF3 /*!< Channel 3 transfer complete flag */
#define LL_DMA_ISR_HTIF3 DMA_ISR_HTIF3 /*!< Channel 3 half transfer flag */
#define LL_DMA_ISR_TEIF3 DMA_ISR_TEIF3 /*!< Channel 3 transfer error flag */
#define LL_DMA_ISR_GIF4 DMA_ISR_GIF4 /*!< Channel 4 global flag */
#define LL_DMA_ISR_TCIF4 DMA_ISR_TCIF4 /*!< Channel 4 transfer complete flag */
#define LL_DMA_ISR_HTIF4 DMA_ISR_HTIF4 /*!< Channel 4 half transfer flag */
#define LL_DMA_ISR_TEIF4 DMA_ISR_TEIF4 /*!< Channel 4 transfer error flag */
#define LL_DMA_ISR_GIF5 DMA_ISR_GIF5 /*!< Channel 5 global flag */
#define LL_DMA_ISR_TCIF5 DMA_ISR_TCIF5 /*!< Channel 5 transfer complete flag */
#define LL_DMA_ISR_HTIF5 DMA_ISR_HTIF5 /*!< Channel 5 half transfer flag */
#define LL_DMA_ISR_TEIF5 DMA_ISR_TEIF5 /*!< Channel 5 transfer error flag */
#define LL_DMA_ISR_GIF6 DMA_ISR_GIF6 /*!< Channel 6 global flag */
#define LL_DMA_ISR_TCIF6 DMA_ISR_TCIF6 /*!< Channel 6 transfer complete flag */
#define LL_DMA_ISR_HTIF6 DMA_ISR_HTIF6 /*!< Channel 6 half transfer flag */
#define LL_DMA_ISR_TEIF6 DMA_ISR_TEIF6 /*!< Channel 6 transfer error flag */
#if defined (DMA1_Channel7)
#define LL_DMA_ISR_GIF7 DMA_ISR_GIF7 /*!< Channel 7 global flag */
#define LL_DMA_ISR_TCIF7 DMA_ISR_TCIF7 /*!< Channel 7 transfer complete flag */
#define LL_DMA_ISR_HTIF7 DMA_ISR_HTIF7 /*!< Channel 7 half transfer flag */
#define LL_DMA_ISR_TEIF7 DMA_ISR_TEIF7 /*!< Channel 7 transfer error flag */
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
#define LL_DMA_ISR_GIF8 DMA_ISR_GIF8 /*!< Channel 8 global flag */
#define LL_DMA_ISR_TCIF8 DMA_ISR_TCIF8 /*!< Channel 8 transfer complete flag */
#define LL_DMA_ISR_HTIF8 DMA_ISR_HTIF8 /*!< Channel 8 half transfer flag */
#define LL_DMA_ISR_TEIF8 DMA_ISR_TEIF8 /*!< Channel 8 transfer error flag */
#endif /* DMA1_Channel8 */
/**
* @}
*/
/** @defgroup DMA_LL_EC_IT IT Defines
* @brief IT defines which can be used with LL_DMA_ReadReg and LL_DMA_WriteReg functions
* @{
*/
#define LL_DMA_CCR_TCIE DMA_CCR_TCIE /*!< Transfer complete interrupt */
#define LL_DMA_CCR_HTIE DMA_CCR_HTIE /*!< Half Transfer interrupt */
#define LL_DMA_CCR_TEIE DMA_CCR_TEIE /*!< Transfer error interrupt */
/**
* @}
*/
/** @defgroup DMA_LL_EC_CHANNEL CHANNEL
* @{
*/
#define LL_DMA_CHANNEL_1 0x00000000U /*!< DMA Channel 1 */
#define LL_DMA_CHANNEL_2 0x00000001U /*!< DMA Channel 2 */
#define LL_DMA_CHANNEL_3 0x00000002U /*!< DMA Channel 3 */
#define LL_DMA_CHANNEL_4 0x00000003U /*!< DMA Channel 4 */
#define LL_DMA_CHANNEL_5 0x00000004U /*!< DMA Channel 5 */
#define LL_DMA_CHANNEL_6 0x00000005U /*!< DMA Channel 6 */
#if defined (DMA1_Channel7)
#define LL_DMA_CHANNEL_7 0x00000006U /*!< DMA Channel 7 */
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
#define LL_DMA_CHANNEL_8 0x00000007U /*!< DMA Channel 8 */
#endif /* DMA1_Channel8 */
#if defined(USE_FULL_LL_DRIVER)
#define LL_DMA_CHANNEL_ALL 0xFFFF0000U /*!< DMA Channel all (used only for function @ref LL_DMA_DeInit(). */
#endif /*USE_FULL_LL_DRIVER*/
/**
* @}
*/
/** @defgroup DMA_LL_EC_DIRECTION Transfer Direction
* @{
*/
#define LL_DMA_DIRECTION_PERIPH_TO_MEMORY 0x00000000U /*!< Peripheral to memory direction */
#define LL_DMA_DIRECTION_MEMORY_TO_PERIPH DMA_CCR_DIR /*!< Memory to peripheral direction */
#define LL_DMA_DIRECTION_MEMORY_TO_MEMORY DMA_CCR_MEM2MEM /*!< Memory to memory direction */
/**
* @}
*/
/** @defgroup DMA_LL_EC_MODE Transfer mode
* @{
*/
#define LL_DMA_MODE_NORMAL 0x00000000U /*!< Normal Mode */
#define LL_DMA_MODE_CIRCULAR DMA_CCR_CIRC /*!< Circular Mode */
/**
* @}
*/
/** @defgroup DMA_LL_EC_PERIPH Peripheral increment mode
* @{
*/
#define LL_DMA_PERIPH_INCREMENT DMA_CCR_PINC /*!< Peripheral increment mode Enable */
#define LL_DMA_PERIPH_NOINCREMENT 0x00000000U /*!< Peripheral increment mode Disable */
/**
* @}
*/
/** @defgroup DMA_LL_EC_MEMORY Memory increment mode
* @{
*/
#define LL_DMA_MEMORY_INCREMENT DMA_CCR_MINC /*!< Memory increment mode Enable */
#define LL_DMA_MEMORY_NOINCREMENT 0x00000000U /*!< Memory increment mode Disable */
/**
* @}
*/
/** @defgroup DMA_LL_EC_PDATAALIGN Peripheral data alignment
* @{
*/
#define LL_DMA_PDATAALIGN_BYTE 0x00000000U /*!< Peripheral data alignment : Byte */
#define LL_DMA_PDATAALIGN_HALFWORD DMA_CCR_PSIZE_0 /*!< Peripheral data alignment : HalfWord */
#define LL_DMA_PDATAALIGN_WORD DMA_CCR_PSIZE_1 /*!< Peripheral data alignment : Word */
/**
* @}
*/
/** @defgroup DMA_LL_EC_MDATAALIGN Memory data alignment
* @{
*/
#define LL_DMA_MDATAALIGN_BYTE 0x00000000U /*!< Memory data alignment : Byte */
#define LL_DMA_MDATAALIGN_HALFWORD DMA_CCR_MSIZE_0 /*!< Memory data alignment : HalfWord */
#define LL_DMA_MDATAALIGN_WORD DMA_CCR_MSIZE_1 /*!< Memory data alignment : Word */
/**
* @}
*/
/** @defgroup DMA_LL_EC_PRIORITY Transfer Priority level
* @{
*/
#define LL_DMA_PRIORITY_LOW 0x00000000U /*!< Priority level : Low */
#define LL_DMA_PRIORITY_MEDIUM DMA_CCR_PL_0 /*!< Priority level : Medium */
#define LL_DMA_PRIORITY_HIGH DMA_CCR_PL_1 /*!< Priority level : High */
#define LL_DMA_PRIORITY_VERYHIGH DMA_CCR_PL /*!< Priority level : Very_High */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup DMA_LL_Exported_Macros DMA Exported Macros
* @{
*/
/** @defgroup DMA_LL_EM_WRITE_READ Common Write and read registers macros
* @{
*/
/**
* @brief Write a value in DMA register
* @param __INSTANCE__ DMA Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_DMA_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG(__INSTANCE__->__REG__, (__VALUE__))
/**
* @brief Read a value in DMA register
* @param __INSTANCE__ DMA Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_DMA_ReadReg(__INSTANCE__, __REG__) READ_REG(__INSTANCE__->__REG__)
/**
* @}
*/
/** @defgroup DMA_LL_EM_CONVERT_DMAxCHANNELy Convert DMAxChannely
* @{
*/
/**
* @brief Convert DMAx_Channely into DMAx
* @param __CHANNEL_INSTANCE__ DMAx_Channely
* @retval DMAx
*/
#if defined (DMA1_Channel8)
#define __LL_DMA_GET_INSTANCE(__CHANNEL_INSTANCE__) \
(((uint32_t)(__CHANNEL_INSTANCE__) > ((uint32_t)DMA1_Channel8)) ? DMA2 : DMA1)
#else
#define __LL_DMA_GET_INSTANCE(__CHANNEL_INSTANCE__) \
(((uint32_t)(__CHANNEL_INSTANCE__) > ((uint32_t)DMA1_Channel6)) ? DMA2 : DMA1)
#endif /* DMA1_Channel8 */
/**
* @brief Convert DMAx_Channely into LL_DMA_CHANNEL_y
* @param __CHANNEL_INSTANCE__ DMAx_Channely
* @retval LL_DMA_CHANNEL_y
*/
#if defined (DMA1_Channel8)
#define __LL_DMA_GET_CHANNEL(__CHANNEL_INSTANCE__) \
(((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel1)) ? LL_DMA_CHANNEL_1 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel1)) ? LL_DMA_CHANNEL_1 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel2)) ? LL_DMA_CHANNEL_2 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel2)) ? LL_DMA_CHANNEL_2 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel3)) ? LL_DMA_CHANNEL_3 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel3)) ? LL_DMA_CHANNEL_3 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel4)) ? LL_DMA_CHANNEL_4 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel4)) ? LL_DMA_CHANNEL_4 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel5)) ? LL_DMA_CHANNEL_5 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel5)) ? LL_DMA_CHANNEL_5 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel6)) ? LL_DMA_CHANNEL_6 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel6)) ? LL_DMA_CHANNEL_6 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel7)) ? LL_DMA_CHANNEL_7 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel7)) ? LL_DMA_CHANNEL_7 : \
LL_DMA_CHANNEL_8)
#else
#define __LL_DMA_GET_CHANNEL(__CHANNEL_INSTANCE__) \
(((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel1)) ? LL_DMA_CHANNEL_1 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel1)) ? LL_DMA_CHANNEL_1 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel2)) ? LL_DMA_CHANNEL_2 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel2)) ? LL_DMA_CHANNEL_2 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel3)) ? LL_DMA_CHANNEL_3 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel3)) ? LL_DMA_CHANNEL_3 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel4)) ? LL_DMA_CHANNEL_4 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel4)) ? LL_DMA_CHANNEL_4 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA1_Channel5)) ? LL_DMA_CHANNEL_5 : \
((uint32_t)(__CHANNEL_INSTANCE__) == ((uint32_t)DMA2_Channel5)) ? LL_DMA_CHANNEL_5 : \
LL_DMA_CHANNEL_6)
#endif /* DMA1_Channel8 */
/**
* @brief Convert DMA Instance DMAx and LL_DMA_CHANNEL_y into DMAx_Channely
* @param __DMA_INSTANCE__ DMAx
* @param __CHANNEL__ LL_DMA_CHANNEL_y
* @retval DMAx_Channely
*/
#if defined (DMA1_Channel8)
#define __LL_DMA_GET_CHANNEL_INSTANCE(__DMA_INSTANCE__, __CHANNEL__) \
((((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_1))) ? DMA1_Channel1 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_1))) ? DMA2_Channel1 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_2))) ? DMA1_Channel2 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_2))) ? DMA2_Channel2 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_3))) ? DMA1_Channel3 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_3))) ? DMA2_Channel3 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_4))) ? DMA1_Channel4 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_4))) ? DMA2_Channel4 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_5))) ? DMA1_Channel5 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_5))) ? DMA2_Channel5 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_6))) ? DMA1_Channel6 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_6))) ? DMA2_Channel6 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_7))) ? DMA1_Channel7 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_7))) ? DMA2_Channel7 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_8))) ? DMA1_Channel8 : \
DMA2_Channel8)
#else
#define __LL_DMA_GET_CHANNEL_INSTANCE(__DMA_INSTANCE__, __CHANNEL__) \
((((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_1))) ? DMA1_Channel1 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_1))) ? DMA2_Channel1 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_2))) ? DMA1_Channel2 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_2))) ? DMA2_Channel2 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_3))) ? DMA1_Channel3 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_3))) ? DMA2_Channel3 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_4))) ? DMA1_Channel4 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_4))) ? DMA2_Channel4 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_5))) ? DMA1_Channel5 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA2)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_5))) ? DMA2_Channel5 : \
(((uint32_t)(__DMA_INSTANCE__) == ((uint32_t)DMA1)) && ((uint32_t)(__CHANNEL__) == ((uint32_t)LL_DMA_CHANNEL_6))) ? DMA1_Channel6 : \
DMA2_Channel6)
#endif /* DMA1_Channel8 */
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup DMA_LL_Exported_Functions DMA Exported Functions
* @{
*/
/** @defgroup DMA_LL_EF_Configuration Configuration
* @{
*/
/**
* @brief Enable DMA channel.
* @rmtoll CCR EN LL_DMA_EnableChannel
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_EnableChannel(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
SET_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_EN);
}
/**
* @brief Disable DMA channel.
* @rmtoll CCR EN LL_DMA_DisableChannel
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_DisableChannel(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
CLEAR_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_EN);
}
/**
* @brief Check if DMA channel is enabled or disabled.
* @rmtoll CCR EN LL_DMA_IsEnabledChannel
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsEnabledChannel(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return ((READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_EN) == (DMA_CCR_EN)) ? 1UL : 0UL);
}
/**
* @brief Configure all parameters link to DMA transfer.
* @rmtoll CCR DIR LL_DMA_ConfigTransfer\n
* CCR MEM2MEM LL_DMA_ConfigTransfer\n
* CCR CIRC LL_DMA_ConfigTransfer\n
* CCR PINC LL_DMA_ConfigTransfer\n
* CCR MINC LL_DMA_ConfigTransfer\n
* CCR PSIZE LL_DMA_ConfigTransfer\n
* CCR MSIZE LL_DMA_ConfigTransfer\n
* CCR PL LL_DMA_ConfigTransfer
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param Configuration This parameter must be a combination of all the following values:
* @arg @ref LL_DMA_DIRECTION_PERIPH_TO_MEMORY or @ref LL_DMA_DIRECTION_MEMORY_TO_PERIPH or @ref LL_DMA_DIRECTION_MEMORY_TO_MEMORY
* @arg @ref LL_DMA_MODE_NORMAL or @ref LL_DMA_MODE_CIRCULAR
* @arg @ref LL_DMA_PERIPH_INCREMENT or @ref LL_DMA_PERIPH_NOINCREMENT
* @arg @ref LL_DMA_MEMORY_INCREMENT or @ref LL_DMA_MEMORY_NOINCREMENT
* @arg @ref LL_DMA_PDATAALIGN_BYTE or @ref LL_DMA_PDATAALIGN_HALFWORD or @ref LL_DMA_PDATAALIGN_WORD
* @arg @ref LL_DMA_MDATAALIGN_BYTE or @ref LL_DMA_MDATAALIGN_HALFWORD or @ref LL_DMA_MDATAALIGN_WORD
* @arg @ref LL_DMA_PRIORITY_LOW or @ref LL_DMA_PRIORITY_MEDIUM or @ref LL_DMA_PRIORITY_HIGH or @ref LL_DMA_PRIORITY_VERYHIGH
* @retval None
*/
__STATIC_INLINE void LL_DMA_ConfigTransfer(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t Configuration)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_DIR | DMA_CCR_MEM2MEM | DMA_CCR_CIRC | DMA_CCR_PINC | DMA_CCR_MINC | DMA_CCR_PSIZE | DMA_CCR_MSIZE | DMA_CCR_PL,
Configuration);
}
/**
* @brief Set Data transfer direction (read from peripheral or from memory).
* @rmtoll CCR DIR LL_DMA_SetDataTransferDirection\n
* CCR MEM2MEM LL_DMA_SetDataTransferDirection
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param Direction This parameter can be one of the following values:
* @arg @ref LL_DMA_DIRECTION_PERIPH_TO_MEMORY
* @arg @ref LL_DMA_DIRECTION_MEMORY_TO_PERIPH
* @arg @ref LL_DMA_DIRECTION_MEMORY_TO_MEMORY
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetDataTransferDirection(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t Direction)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_DIR | DMA_CCR_MEM2MEM, Direction);
}
/**
* @brief Get Data transfer direction (read from peripheral or from memory).
* @rmtoll CCR DIR LL_DMA_GetDataTransferDirection\n
* CCR MEM2MEM LL_DMA_GetDataTransferDirection
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMA_DIRECTION_PERIPH_TO_MEMORY
* @arg @ref LL_DMA_DIRECTION_MEMORY_TO_PERIPH
* @arg @ref LL_DMA_DIRECTION_MEMORY_TO_MEMORY
*/
__STATIC_INLINE uint32_t LL_DMA_GetDataTransferDirection(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_DIR | DMA_CCR_MEM2MEM));
}
/**
* @brief Set DMA mode circular or normal.
* @note The circular buffer mode cannot be used if the memory-to-memory
* data transfer is configured on the selected Channel.
* @rmtoll CCR CIRC LL_DMA_SetMode
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param Mode This parameter can be one of the following values:
* @arg @ref LL_DMA_MODE_NORMAL
* @arg @ref LL_DMA_MODE_CIRCULAR
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetMode(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t Mode)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_CIRC,
Mode);
}
/**
* @brief Get DMA mode circular or normal.
* @rmtoll CCR CIRC LL_DMA_GetMode
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMA_MODE_NORMAL
* @arg @ref LL_DMA_MODE_CIRCULAR
*/
__STATIC_INLINE uint32_t LL_DMA_GetMode(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_CIRC));
}
/**
* @brief Set Peripheral increment mode.
* @rmtoll CCR PINC LL_DMA_SetPeriphIncMode
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param PeriphOrM2MSrcIncMode This parameter can be one of the following values:
* @arg @ref LL_DMA_PERIPH_INCREMENT
* @arg @ref LL_DMA_PERIPH_NOINCREMENT
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetPeriphIncMode(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t PeriphOrM2MSrcIncMode)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_PINC,
PeriphOrM2MSrcIncMode);
}
/**
* @brief Get Peripheral increment mode.
* @rmtoll CCR PINC LL_DMA_GetPeriphIncMode
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMA_PERIPH_INCREMENT
* @arg @ref LL_DMA_PERIPH_NOINCREMENT
*/
__STATIC_INLINE uint32_t LL_DMA_GetPeriphIncMode(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_PINC));
}
/**
* @brief Set Memory increment mode.
* @rmtoll CCR MINC LL_DMA_SetMemoryIncMode
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param MemoryOrM2MDstIncMode This parameter can be one of the following values:
* @arg @ref LL_DMA_MEMORY_INCREMENT
* @arg @ref LL_DMA_MEMORY_NOINCREMENT
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetMemoryIncMode(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t MemoryOrM2MDstIncMode)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_MINC,
MemoryOrM2MDstIncMode);
}
/**
* @brief Get Memory increment mode.
* @rmtoll CCR MINC LL_DMA_GetMemoryIncMode
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMA_MEMORY_INCREMENT
* @arg @ref LL_DMA_MEMORY_NOINCREMENT
*/
__STATIC_INLINE uint32_t LL_DMA_GetMemoryIncMode(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_MINC));
}
/**
* @brief Set Peripheral size.
* @rmtoll CCR PSIZE LL_DMA_SetPeriphSize
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param PeriphOrM2MSrcDataSize This parameter can be one of the following values:
* @arg @ref LL_DMA_PDATAALIGN_BYTE
* @arg @ref LL_DMA_PDATAALIGN_HALFWORD
* @arg @ref LL_DMA_PDATAALIGN_WORD
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetPeriphSize(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t PeriphOrM2MSrcDataSize)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_PSIZE,
PeriphOrM2MSrcDataSize);
}
/**
* @brief Get Peripheral size.
* @rmtoll CCR PSIZE LL_DMA_GetPeriphSize
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMA_PDATAALIGN_BYTE
* @arg @ref LL_DMA_PDATAALIGN_HALFWORD
* @arg @ref LL_DMA_PDATAALIGN_WORD
*/
__STATIC_INLINE uint32_t LL_DMA_GetPeriphSize(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_PSIZE));
}
/**
* @brief Set Memory size.
* @rmtoll CCR MSIZE LL_DMA_SetMemorySize
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param MemoryOrM2MDstDataSize This parameter can be one of the following values:
* @arg @ref LL_DMA_MDATAALIGN_BYTE
* @arg @ref LL_DMA_MDATAALIGN_HALFWORD
* @arg @ref LL_DMA_MDATAALIGN_WORD
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetMemorySize(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t MemoryOrM2MDstDataSize)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_MSIZE,
MemoryOrM2MDstDataSize);
}
/**
* @brief Get Memory size.
* @rmtoll CCR MSIZE LL_DMA_GetMemorySize
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMA_MDATAALIGN_BYTE
* @arg @ref LL_DMA_MDATAALIGN_HALFWORD
* @arg @ref LL_DMA_MDATAALIGN_WORD
*/
__STATIC_INLINE uint32_t LL_DMA_GetMemorySize(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_MSIZE));
}
/**
* @brief Set Channel priority level.
* @rmtoll CCR PL LL_DMA_SetChannelPriorityLevel
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param Priority This parameter can be one of the following values:
* @arg @ref LL_DMA_PRIORITY_LOW
* @arg @ref LL_DMA_PRIORITY_MEDIUM
* @arg @ref LL_DMA_PRIORITY_HIGH
* @arg @ref LL_DMA_PRIORITY_VERYHIGH
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetChannelPriorityLevel(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t Priority)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_PL,
Priority);
}
/**
* @brief Get Channel priority level.
* @rmtoll CCR PL LL_DMA_GetChannelPriorityLevel
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMA_PRIORITY_LOW
* @arg @ref LL_DMA_PRIORITY_MEDIUM
* @arg @ref LL_DMA_PRIORITY_HIGH
* @arg @ref LL_DMA_PRIORITY_VERYHIGH
*/
__STATIC_INLINE uint32_t LL_DMA_GetChannelPriorityLevel(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_PL));
}
/**
* @brief Set Number of data to transfer.
* @note This action has no effect if
* channel is enabled.
* @rmtoll CNDTR NDT LL_DMA_SetDataLength
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param NbData Between Min_Data = 0 and Max_Data = 0x0000FFFF
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetDataLength(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t NbData)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
MODIFY_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CNDTR,
DMA_CNDTR_NDT, NbData);
}
/**
* @brief Get Number of data to transfer.
* @note Once the channel is enabled, the return value indicate the
* remaining bytes to be transmitted.
* @rmtoll CNDTR NDT LL_DMA_GetDataLength
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
*/
__STATIC_INLINE uint32_t LL_DMA_GetDataLength(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CNDTR,
DMA_CNDTR_NDT));
}
/**
* @brief Configure the Source and Destination addresses.
* @note This API must not be called when the DMA channel is enabled.
* @note Each IP using DMA provides an API to get directly the register address (LL_PPP_DMA_GetRegAddr).
* @rmtoll CPAR PA LL_DMA_ConfigAddresses\n
* CMAR MA LL_DMA_ConfigAddresses
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param SrcAddress Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
* @param DstAddress Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
* @param Direction This parameter can be one of the following values:
* @arg @ref LL_DMA_DIRECTION_PERIPH_TO_MEMORY
* @arg @ref LL_DMA_DIRECTION_MEMORY_TO_PERIPH
* @arg @ref LL_DMA_DIRECTION_MEMORY_TO_MEMORY
* @retval None
*/
__STATIC_INLINE void LL_DMA_ConfigAddresses(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t SrcAddress,
uint32_t DstAddress, uint32_t Direction)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
/* Direction Memory to Periph */
if (Direction == LL_DMA_DIRECTION_MEMORY_TO_PERIPH)
{
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CMAR, SrcAddress);
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CPAR, DstAddress);
}
/* Direction Periph to Memory and Memory to Memory */
else
{
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CPAR, SrcAddress);
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CMAR, DstAddress);
}
}
/**
* @brief Set the Memory address.
* @note Interface used for direction LL_DMA_DIRECTION_PERIPH_TO_MEMORY or LL_DMA_DIRECTION_MEMORY_TO_PERIPH only.
* @note This API must not be called when the DMA channel is enabled.
* @rmtoll CMAR MA LL_DMA_SetMemoryAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param MemoryAddress Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetMemoryAddress(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t MemoryAddress)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CMAR, MemoryAddress);
}
/**
* @brief Set the Peripheral address.
* @note Interface used for direction LL_DMA_DIRECTION_PERIPH_TO_MEMORY or LL_DMA_DIRECTION_MEMORY_TO_PERIPH only.
* @note This API must not be called when the DMA channel is enabled.
* @rmtoll CPAR PA LL_DMA_SetPeriphAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param PeriphAddress Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetPeriphAddress(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t PeriphAddress)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CPAR, PeriphAddress);
}
/**
* @brief Get Memory address.
* @note Interface used for direction LL_DMA_DIRECTION_PERIPH_TO_MEMORY or LL_DMA_DIRECTION_MEMORY_TO_PERIPH only.
* @rmtoll CMAR MA LL_DMA_GetMemoryAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
*/
__STATIC_INLINE uint32_t LL_DMA_GetMemoryAddress(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CMAR));
}
/**
* @brief Get Peripheral address.
* @note Interface used for direction LL_DMA_DIRECTION_PERIPH_TO_MEMORY or LL_DMA_DIRECTION_MEMORY_TO_PERIPH only.
* @rmtoll CPAR PA LL_DMA_GetPeriphAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
*/
__STATIC_INLINE uint32_t LL_DMA_GetPeriphAddress(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CPAR));
}
/**
* @brief Set the Memory to Memory Source address.
* @note Interface used for direction LL_DMA_DIRECTION_MEMORY_TO_MEMORY only.
* @note This API must not be called when the DMA channel is enabled.
* @rmtoll CPAR PA LL_DMA_SetM2MSrcAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param MemoryAddress Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetM2MSrcAddress(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t MemoryAddress)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CPAR, MemoryAddress);
}
/**
* @brief Set the Memory to Memory Destination address.
* @note Interface used for direction LL_DMA_DIRECTION_MEMORY_TO_MEMORY only.
* @note This API must not be called when the DMA channel is enabled.
* @rmtoll CMAR MA LL_DMA_SetM2MDstAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param MemoryAddress Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetM2MDstAddress(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t MemoryAddress)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
WRITE_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CMAR, MemoryAddress);
}
/**
* @brief Get the Memory to Memory Source address.
* @note Interface used for direction LL_DMA_DIRECTION_MEMORY_TO_MEMORY only.
* @rmtoll CPAR PA LL_DMA_GetM2MSrcAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
*/
__STATIC_INLINE uint32_t LL_DMA_GetM2MSrcAddress(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CPAR));
}
/**
* @brief Get the Memory to Memory Destination address.
* @note Interface used for direction LL_DMA_DIRECTION_MEMORY_TO_MEMORY only.
* @rmtoll CMAR MA LL_DMA_GetM2MDstAddress
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Between Min_Data = 0 and Max_Data = 0xFFFFFFFF
*/
__STATIC_INLINE uint32_t LL_DMA_GetM2MDstAddress(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return (READ_REG(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CMAR));
}
/**
* @brief Set DMA request for DMA instance on Channel x.
* @note Please refer to Reference Manual to get the available mapping of Request value link to Channel Selection.
* @rmtoll CSELR C1S LL_DMA_SetPeriphRequest\n
* CSELR C2S LL_DMA_SetPeriphRequest\n
* CSELR C3S LL_DMA_SetPeriphRequest\n
* CSELR C4S LL_DMA_SetPeriphRequest\n
* CSELR C5S LL_DMA_SetPeriphRequest\n
* CSELR C6S LL_DMA_SetPeriphRequest\n
* CSELR C7S LL_DMA_SetPeriphRequest
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @param PeriphRequest This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_MEM2MEM
* @arg @ref LL_DMAMUX_REQ_GENERATOR0
* @arg @ref LL_DMAMUX_REQ_GENERATOR1
* @arg @ref LL_DMAMUX_REQ_GENERATOR2
* @arg @ref LL_DMAMUX_REQ_GENERATOR3
* @arg @ref LL_DMAMUX_REQ_ADC1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM6_UP
* @arg @ref LL_DMAMUX_REQ_TIM7_UP
* @arg @ref LL_DMAMUX_REQ_SPI1_RX
* @arg @ref LL_DMAMUX_REQ_SPI1_TX
* @arg @ref LL_DMAMUX_REQ_SPI2_RX
* @arg @ref LL_DMAMUX_REQ_SPI2_TX
* @arg @ref LL_DMAMUX_REQ_SPI3_RX
* @arg @ref LL_DMAMUX_REQ_SPI3_TX
* @arg @ref LL_DMAMUX_REQ_I2C1_RX
* @arg @ref LL_DMAMUX_REQ_I2C1_TX
* @arg @ref LL_DMAMUX_REQ_I2C2_RX
* @arg @ref LL_DMAMUX_REQ_I2C2_TX
* @arg @ref LL_DMAMUX_REQ_I2C3_RX
* @arg @ref LL_DMAMUX_REQ_I2C3_TX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_RX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_TX
* @arg @ref LL_DMAMUX_REQ_USART1_RX
* @arg @ref LL_DMAMUX_REQ_USART1_TX
* @arg @ref LL_DMAMUX_REQ_USART2_RX
* @arg @ref LL_DMAMUX_REQ_USART2_TX
* @arg @ref LL_DMAMUX_REQ_USART3_RX
* @arg @ref LL_DMAMUX_REQ_USART3_TX
* @arg @ref LL_DMAMUX_REQ_UART4_RX
* @arg @ref LL_DMAMUX_REQ_UART4_TX
* @arg @ref LL_DMAMUX_REQ_UART5_RX (*)
* @arg @ref LL_DMAMUX_REQ_UART5_TX (*)
* @arg @ref LL_DMAMUX_REQ_LPUART1_RX
* @arg @ref LL_DMAMUX_REQ_LPUART1_TX
* @arg @ref LL_DMAMUX_REQ_ADC2
* @arg @ref LL_DMAMUX_REQ_ADC3 (*)
* @arg @ref LL_DMAMUX_REQ_ADC4 (*)
* @arg @ref LL_DMAMUX_REQ_ADC5 (*)
* @arg @ref LL_DMAMUX_REQ_QSPI (*)
* @arg @ref LL_DMAMUX_REQ_DAC2_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM1_CH1
* @arg @ref LL_DMAMUX_REQ_TIM1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM1_CH3
* @arg @ref LL_DMAMUX_REQ_TIM1_CH4
* @arg @ref LL_DMAMUX_REQ_TIM1_UP
* @arg @ref LL_DMAMUX_REQ_TIM1_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM1_COM
* @arg @ref LL_DMAMUX_REQ_TIM8_CH1
* @arg @ref LL_DMAMUX_REQ_TIM8_CH2
* @arg @ref LL_DMAMUX_REQ_TIM8_CH3
* @arg @ref LL_DMAMUX_REQ_TIM8_CH4
* @arg @ref LL_DMAMUX_REQ_TIM8_UP
* @arg @ref LL_DMAMUX_REQ_TIM8_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM8_COM
* @arg @ref LL_DMAMUX_REQ_TIM2_CH1
* @arg @ref LL_DMAMUX_REQ_TIM2_CH2
* @arg @ref LL_DMAMUX_REQ_TIM2_CH3
* @arg @ref LL_DMAMUX_REQ_TIM2_CH4
* @arg @ref LL_DMAMUX_REQ_TIM2_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_CH1
* @arg @ref LL_DMAMUX_REQ_TIM3_CH2
* @arg @ref LL_DMAMUX_REQ_TIM3_CH3
* @arg @ref LL_DMAMUX_REQ_TIM3_CH4
* @arg @ref LL_DMAMUX_REQ_TIM3_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM4_CH1
* @arg @ref LL_DMAMUX_REQ_TIM4_CH2
* @arg @ref LL_DMAMUX_REQ_TIM4_CH3
* @arg @ref LL_DMAMUX_REQ_TIM4_CH4
* @arg @ref LL_DMAMUX_REQ_TIM4_UP
* @arg @ref LL_DMAMUX_REQ_TIM5_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_UP (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM15_CH1
* @arg @ref LL_DMAMUX_REQ_TIM15_UP
* @arg @ref LL_DMAMUX_REQ_TIM15_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM15_COM
* @arg @ref LL_DMAMUX_REQ_TIM16_CH1
* @arg @ref LL_DMAMUX_REQ_TIM16_UP
* @arg @ref LL_DMAMUX_REQ_TIM17_CH1
* @arg @ref LL_DMAMUX_REQ_TIM17_UP
* @arg @ref LL_DMAMUX_REQ_TIM20_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_UP (*)
* @arg @ref LL_DMAMUX_REQ_AES_IN
* @arg @ref LL_DMAMUX_REQ_AES_OUT
* @arg @ref LL_DMAMUX_REQ_TIM20_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_COM (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_M (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_A (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_B (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_C (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_D (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_E (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_F (*)
* @arg @ref LL_DMAMUX_REQ_DAC3_CH1
* @arg @ref LL_DMAMUX_REQ_DAC3_CH2
* @arg @ref LL_DMAMUX_REQ_DAC4_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_DAC4_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_RX (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_TX (*)
* @arg @ref LL_DMAMUX_REQ_SAI1_A
* @arg @ref LL_DMAMUX_REQ_SAI1_B
* @arg @ref LL_DMAMUX_REQ_FMAC_WRITE
* @arg @ref LL_DMAMUX_REQ_FMAC_READ
* @arg @ref LL_DMAMUX_REQ_CORDIC_WRITE
* @arg @ref LL_DMAMUX_REQ_CORDIC_READ
* @arg @ref LL_DMAMUX_REQ_UCPD1_RX
* @arg @ref LL_DMAMUX_REQ_UCPD1_TX
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_SetPeriphRequest(DMA_TypeDef *DMAx, uint32_t Channel, uint32_t PeriphRequest)
{
uint32_t dmamux_ccr_offset = ((((uint32_t)DMAx ^ (uint32_t)DMA1) >> 10U) * 8U);
MODIFY_REG((DMAMUX1_Channel0 + Channel + dmamux_ccr_offset)->CCR, DMAMUX_CxCR_DMAREQ_ID, PeriphRequest);
}
/**
* @brief Get DMA request for DMA instance on Channel x.
* @rmtoll CSELR C1S LL_DMA_GetPeriphRequest\n
* CSELR C2S LL_DMA_GetPeriphRequest\n
* CSELR C3S LL_DMA_GetPeriphRequest\n
* CSELR C4S LL_DMA_GetPeriphRequest\n
* CSELR C5S LL_DMA_GetPeriphRequest\n
* CSELR C6S LL_DMA_GetPeriphRequest\n
* CSELR C7S LL_DMA_GetPeriphRequest
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_MEM2MEM
* @arg @ref LL_DMAMUX_REQ_GENERATOR0
* @arg @ref LL_DMAMUX_REQ_GENERATOR1
* @arg @ref LL_DMAMUX_REQ_GENERATOR2
* @arg @ref LL_DMAMUX_REQ_GENERATOR3
* @arg @ref LL_DMAMUX_REQ_ADC1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM6_UP
* @arg @ref LL_DMAMUX_REQ_TIM7_UP
* @arg @ref LL_DMAMUX_REQ_SPI1_RX
* @arg @ref LL_DMAMUX_REQ_SPI1_TX
* @arg @ref LL_DMAMUX_REQ_SPI2_RX
* @arg @ref LL_DMAMUX_REQ_SPI2_TX
* @arg @ref LL_DMAMUX_REQ_SPI3_RX
* @arg @ref LL_DMAMUX_REQ_SPI3_TX
* @arg @ref LL_DMAMUX_REQ_I2C1_RX
* @arg @ref LL_DMAMUX_REQ_I2C1_TX
* @arg @ref LL_DMAMUX_REQ_I2C2_RX
* @arg @ref LL_DMAMUX_REQ_I2C2_TX
* @arg @ref LL_DMAMUX_REQ_I2C3_RX
* @arg @ref LL_DMAMUX_REQ_I2C3_TX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_RX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_TX
* @arg @ref LL_DMAMUX_REQ_USART1_RX
* @arg @ref LL_DMAMUX_REQ_USART1_TX
* @arg @ref LL_DMAMUX_REQ_USART2_RX
* @arg @ref LL_DMAMUX_REQ_USART2_TX
* @arg @ref LL_DMAMUX_REQ_USART3_RX
* @arg @ref LL_DMAMUX_REQ_USART3_TX
* @arg @ref LL_DMAMUX_REQ_UART4_RX
* @arg @ref LL_DMAMUX_REQ_UART4_TX
* @arg @ref LL_DMAMUX_REQ_UART5_RX (*)
* @arg @ref LL_DMAMUX_REQ_UART5_TX (*)
* @arg @ref LL_DMAMUX_REQ_LPUART1_RX
* @arg @ref LL_DMAMUX_REQ_LPUART1_TX
* @arg @ref LL_DMAMUX_REQ_ADC2
* @arg @ref LL_DMAMUX_REQ_ADC3 (*)
* @arg @ref LL_DMAMUX_REQ_ADC4 (*)
* @arg @ref LL_DMAMUX_REQ_ADC5 (*)
* @arg @ref LL_DMAMUX_REQ_QSPI (*)
* @arg @ref LL_DMAMUX_REQ_DAC2_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM1_CH1
* @arg @ref LL_DMAMUX_REQ_TIM1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM1_CH3
* @arg @ref LL_DMAMUX_REQ_TIM1_CH4
* @arg @ref LL_DMAMUX_REQ_TIM1_UP
* @arg @ref LL_DMAMUX_REQ_TIM1_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM1_COM
* @arg @ref LL_DMAMUX_REQ_TIM8_CH1
* @arg @ref LL_DMAMUX_REQ_TIM8_CH2
* @arg @ref LL_DMAMUX_REQ_TIM8_CH3
* @arg @ref LL_DMAMUX_REQ_TIM8_CH4
* @arg @ref LL_DMAMUX_REQ_TIM8_UP
* @arg @ref LL_DMAMUX_REQ_TIM8_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM8_COM
* @arg @ref LL_DMAMUX_REQ_TIM2_CH1
* @arg @ref LL_DMAMUX_REQ_TIM2_CH2
* @arg @ref LL_DMAMUX_REQ_TIM2_CH3
* @arg @ref LL_DMAMUX_REQ_TIM2_CH4
* @arg @ref LL_DMAMUX_REQ_TIM2_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_CH1
* @arg @ref LL_DMAMUX_REQ_TIM3_CH2
* @arg @ref LL_DMAMUX_REQ_TIM3_CH3
* @arg @ref LL_DMAMUX_REQ_TIM3_CH4
* @arg @ref LL_DMAMUX_REQ_TIM3_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM4_CH1
* @arg @ref LL_DMAMUX_REQ_TIM4_CH2
* @arg @ref LL_DMAMUX_REQ_TIM4_CH3
* @arg @ref LL_DMAMUX_REQ_TIM4_CH4
* @arg @ref LL_DMAMUX_REQ_TIM4_UP
* @arg @ref LL_DMAMUX_REQ_TIM5_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_UP (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM15_CH1
* @arg @ref LL_DMAMUX_REQ_TIM15_UP
* @arg @ref LL_DMAMUX_REQ_TIM15_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM15_COM
* @arg @ref LL_DMAMUX_REQ_TIM16_CH1
* @arg @ref LL_DMAMUX_REQ_TIM16_UP
* @arg @ref LL_DMAMUX_REQ_TIM17_CH1
* @arg @ref LL_DMAMUX_REQ_TIM17_UP
* @arg @ref LL_DMAMUX_REQ_TIM20_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_UP (*)
* @arg @ref LL_DMAMUX_REQ_AES_IN
* @arg @ref LL_DMAMUX_REQ_AES_OUT
* @arg @ref LL_DMAMUX_REQ_TIM20_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_COM (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_M (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_A (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_B (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_C (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_D (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_E (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_F (*)
* @arg @ref LL_DMAMUX_REQ_DAC3_CH1
* @arg @ref LL_DMAMUX_REQ_DAC3_CH2
* @arg @ref LL_DMAMUX_REQ_DAC4_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_DAC4_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_RX (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_TX (*)
* @arg @ref LL_DMAMUX_REQ_SAI1_A
* @arg @ref LL_DMAMUX_REQ_SAI1_B
* @arg @ref LL_DMAMUX_REQ_FMAC_WRITE
* @arg @ref LL_DMAMUX_REQ_FMAC_READ
* @arg @ref LL_DMAMUX_REQ_CORDIC_WRITE
* @arg @ref LL_DMAMUX_REQ_CORDIC_READ
* @arg @ref LL_DMAMUX_REQ_UCPD1_RX
* @arg @ref LL_DMAMUX_REQ_UCPD1_TX
* (*) Not on all G4 devices
*/
__STATIC_INLINE uint32_t LL_DMA_GetPeriphRequest(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dmamux_ccr_offset = ((((uint32_t)DMAx ^ (uint32_t)DMA1) >> 10U) * 8U);
return (READ_BIT((DMAMUX1_Channel0 + Channel + dmamux_ccr_offset)->CCR, DMAMUX_CxCR_DMAREQ_ID));
}
/**
* @}
*/
/** @defgroup DMA_LL_EF_FLAG_Management FLAG_Management
* @{
*/
/**
* @brief Get Channel 1 global interrupt flag.
* @rmtoll ISR GIF1 LL_DMA_IsActiveFlag_GI1
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI1(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF1) == (DMA_ISR_GIF1)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 2 global interrupt flag.
* @rmtoll ISR GIF2 LL_DMA_IsActiveFlag_GI2
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI2(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF2) == (DMA_ISR_GIF2)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 3 global interrupt flag.
* @rmtoll ISR GIF3 LL_DMA_IsActiveFlag_GI3
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI3(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF3) == (DMA_ISR_GIF3)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 4 global interrupt flag.
* @rmtoll ISR GIF4 LL_DMA_IsActiveFlag_GI4
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI4(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF4) == (DMA_ISR_GIF4)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 5 global interrupt flag.
* @rmtoll ISR GIF5 LL_DMA_IsActiveFlag_GI5
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI5(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF5) == (DMA_ISR_GIF5)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 6 global interrupt flag.
* @rmtoll ISR GIF6 LL_DMA_IsActiveFlag_GI6
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI6(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF6) == (DMA_ISR_GIF6)) ? 1UL : 0UL);
}
#if defined (DMA1_Channel7)
/**
* @brief Get Channel 7 global interrupt flag.
* @rmtoll ISR GIF7 LL_DMA_IsActiveFlag_GI7
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI7(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF7) == (DMA_ISR_GIF7)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Get Channel 8 global interrupt flag.
* @rmtoll ISR GIF8 LL_DMA_IsActiveFlag_GI8
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_GI8(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_GIF8) == (DMA_ISR_GIF8)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel8 */
/**
* @brief Get Channel 1 transfer complete flag.
* @rmtoll ISR TCIF1 LL_DMA_IsActiveFlag_TC1
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC1(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF1) == (DMA_ISR_TCIF1)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 2 transfer complete flag.
* @rmtoll ISR TCIF2 LL_DMA_IsActiveFlag_TC2
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC2(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF2) == (DMA_ISR_TCIF2)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 3 transfer complete flag.
* @rmtoll ISR TCIF3 LL_DMA_IsActiveFlag_TC3
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC3(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF3) == (DMA_ISR_TCIF3)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 4 transfer complete flag.
* @rmtoll ISR TCIF4 LL_DMA_IsActiveFlag_TC4
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC4(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF4) == (DMA_ISR_TCIF4)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 5 transfer complete flag.
* @rmtoll ISR TCIF5 LL_DMA_IsActiveFlag_TC5
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC5(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF5) == (DMA_ISR_TCIF5)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 6 transfer complete flag.
* @rmtoll ISR TCIF6 LL_DMA_IsActiveFlag_TC6
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC6(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF6) == (DMA_ISR_TCIF6)) ? 1UL : 0UL);
}
#if defined (DMA1_Channel7)
/**
* @brief Get Channel 7 transfer complete flag.
* @rmtoll ISR TCIF7 LL_DMA_IsActiveFlag_TC7
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC7(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF7) == (DMA_ISR_TCIF7)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Get Channel 8 transfer complete flag.
* @rmtoll ISR TCIF8 LL_DMA_IsActiveFlag_TC8
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TC8(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TCIF8) == (DMA_ISR_TCIF8)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel8 */
/**
* @brief Get Channel 1 half transfer flag.
* @rmtoll ISR HTIF1 LL_DMA_IsActiveFlag_HT1
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT1(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF1) == (DMA_ISR_HTIF1)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 2 half transfer flag.
* @rmtoll ISR HTIF2 LL_DMA_IsActiveFlag_HT2
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT2(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF2) == (DMA_ISR_HTIF2)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 3 half transfer flag.
* @rmtoll ISR HTIF3 LL_DMA_IsActiveFlag_HT3
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT3(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF3) == (DMA_ISR_HTIF3)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 4 half transfer flag.
* @rmtoll ISR HTIF4 LL_DMA_IsActiveFlag_HT4
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT4(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF4) == (DMA_ISR_HTIF4)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 5 half transfer flag.
* @rmtoll ISR HTIF5 LL_DMA_IsActiveFlag_HT5
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT5(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF5) == (DMA_ISR_HTIF5)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 6 half transfer flag.
* @rmtoll ISR HTIF6 LL_DMA_IsActiveFlag_HT6
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT6(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF6) == (DMA_ISR_HTIF6)) ? 1UL : 0UL);
}
#if defined (DMA1_Channel8)
/**
* @brief Get Channel 7 half transfer flag.
* @rmtoll ISR HTIF7 LL_DMA_IsActiveFlag_HT7
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT7(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF7) == (DMA_ISR_HTIF7)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Get Channel 8 half transfer flag.
* @rmtoll ISR HTIF8 LL_DMA_IsActiveFlag_HT8
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_HT8(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_HTIF8) == (DMA_ISR_HTIF8)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel8 */
/**
* @brief Get Channel 1 transfer error flag.
* @rmtoll ISR TEIF1 LL_DMA_IsActiveFlag_TE1
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE1(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF1) == (DMA_ISR_TEIF1)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 2 transfer error flag.
* @rmtoll ISR TEIF2 LL_DMA_IsActiveFlag_TE2
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE2(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF2) == (DMA_ISR_TEIF2)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 3 transfer error flag.
* @rmtoll ISR TEIF3 LL_DMA_IsActiveFlag_TE3
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE3(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF3) == (DMA_ISR_TEIF3)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 4 transfer error flag.
* @rmtoll ISR TEIF4 LL_DMA_IsActiveFlag_TE4
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE4(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF4) == (DMA_ISR_TEIF4)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 5 transfer error flag.
* @rmtoll ISR TEIF5 LL_DMA_IsActiveFlag_TE5
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE5(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF5) == (DMA_ISR_TEIF5)) ? 1UL : 0UL);
}
/**
* @brief Get Channel 6 transfer error flag.
* @rmtoll ISR TEIF6 LL_DMA_IsActiveFlag_TE6
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE6(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF6) == (DMA_ISR_TEIF6)) ? 1UL : 0UL);
}
#if defined (DMA1_Channel7)
/**
* @brief Get Channel 7 transfer error flag.
* @rmtoll ISR TEIF7 LL_DMA_IsActiveFlag_TE7
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE7(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF7) == (DMA_ISR_TEIF7)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Get Channel 8 transfer error flag.
* @rmtoll ISR TEIF8 LL_DMA_IsActiveFlag_TE8
* @param DMAx DMAx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsActiveFlag_TE8(DMA_TypeDef *DMAx)
{
return ((READ_BIT(DMAx->ISR, DMA_ISR_TEIF8) == (DMA_ISR_TEIF8)) ? 1UL : 0UL);
}
#endif /* DMA1_Channel8 */
/**
* @brief Clear Channel 1 global interrupt flag.
* @note Do not Clear Channel 1 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC1, LL_DMA_ClearFlag_HT1,
LL_DMA_ClearFlag_TE1. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF1 LL_DMA_ClearFlag_GI1
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI1(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF1);
}
/**
* @brief Clear Channel 2 global interrupt flag.
* @note Do not Clear Channel 2 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC2, LL_DMA_ClearFlag_HT2,
LL_DMA_ClearFlag_TE2. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF2 LL_DMA_ClearFlag_GI2
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI2(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF2);
}
/**
* @brief Clear Channel 3 global interrupt flag.
* @note Do not Clear Channel 3 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC3, LL_DMA_ClearFlag_HT3,
LL_DMA_ClearFlag_TE3. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF3 LL_DMA_ClearFlag_GI3
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI3(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF3);
}
/**
* @brief Clear Channel 4 global interrupt flag.
* @note Do not Clear Channel 4 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC4, LL_DMA_ClearFlag_HT4,
LL_DMA_ClearFlag_TE4. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF4 LL_DMA_ClearFlag_GI4
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI4(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF4);
}
/**
* @brief Clear Channel 5 global interrupt flag.
* @note Do not Clear Channel 5 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC5, LL_DMA_ClearFlag_HT5,
LL_DMA_ClearFlag_TE5. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF5 LL_DMA_ClearFlag_GI5
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI5(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF5);
}
/**
* @brief Clear Channel 6 global interrupt flag.
* @note Do not Clear Channel 6 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC6, LL_DMA_ClearFlag_HT6,
LL_DMA_ClearFlag_TE6. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF6 LL_DMA_ClearFlag_GI6
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI6(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF6);
}
#if defined (DMA1_Channel7)
/**
* @brief Clear Channel 7 global interrupt flag.
* @note Do not Clear Channel 7 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC7, LL_DMA_ClearFlag_HT7,
LL_DMA_ClearFlag_TE7. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF7 LL_DMA_ClearFlag_GI7
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI7(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF7);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Clear Channel 8 global interrupt flag.
* @note Do not Clear Channel 8 global interrupt flag when the channel in ON.
Instead clear specific flags transfer complete, half transfer & transfer
error flag with LL_DMA_ClearFlag_TC8, LL_DMA_ClearFlag_HT8,
LL_DMA_ClearFlag_TE8. bug id 2.3.1 in Product Errata Sheet.
* @rmtoll IFCR CGIF8 LL_DMA_ClearFlag_GI8
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_GI8(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CGIF8);
}
#endif /* DMA1_Channel8 */
/**
* @brief Clear Channel 1 transfer complete flag.
* @rmtoll IFCR CTCIF1 LL_DMA_ClearFlag_TC1
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC1(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF1);
}
/**
* @brief Clear Channel 2 transfer complete flag.
* @rmtoll IFCR CTCIF2 LL_DMA_ClearFlag_TC2
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC2(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF2);
}
/**
* @brief Clear Channel 3 transfer complete flag.
* @rmtoll IFCR CTCIF3 LL_DMA_ClearFlag_TC3
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC3(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF3);
}
/**
* @brief Clear Channel 4 transfer complete flag.
* @rmtoll IFCR CTCIF4 LL_DMA_ClearFlag_TC4
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC4(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF4);
}
/**
* @brief Clear Channel 5 transfer complete flag.
* @rmtoll IFCR CTCIF5 LL_DMA_ClearFlag_TC5
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC5(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF5);
}
/**
* @brief Clear Channel 6 transfer complete flag.
* @rmtoll IFCR CTCIF6 LL_DMA_ClearFlag_TC6
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC6(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF6);
}
#if defined (DMA1_Channel7)
/**
* @brief Clear Channel 7 transfer complete flag.
* @rmtoll IFCR CTCIF7 LL_DMA_ClearFlag_TC7
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC7(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF7);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Clear Channel 8 transfer complete flag.
* @rmtoll IFCR CTCIF8 LL_DMA_ClearFlag_TC8
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TC8(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTCIF8);
}
#endif /* DMA1_Channel8 */
/**
* @brief Clear Channel 1 half transfer flag.
* @rmtoll IFCR CHTIF1 LL_DMA_ClearFlag_HT1
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT1(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF1);
}
/**
* @brief Clear Channel 2 half transfer flag.
* @rmtoll IFCR CHTIF2 LL_DMA_ClearFlag_HT2
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT2(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF2);
}
/**
* @brief Clear Channel 3 half transfer flag.
* @rmtoll IFCR CHTIF3 LL_DMA_ClearFlag_HT3
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT3(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF3);
}
/**
* @brief Clear Channel 4 half transfer flag.
* @rmtoll IFCR CHTIF4 LL_DMA_ClearFlag_HT4
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT4(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF4);
}
/**
* @brief Clear Channel 5 half transfer flag.
* @rmtoll IFCR CHTIF5 LL_DMA_ClearFlag_HT5
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT5(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF5);
}
/**
* @brief Clear Channel 6 half transfer flag.
* @rmtoll IFCR CHTIF6 LL_DMA_ClearFlag_HT6
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT6(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF6);
}
#if defined (DMA1_Channel7)
/**
* @brief Clear Channel 7 half transfer flag.
* @rmtoll IFCR CHTIF7 LL_DMA_ClearFlag_HT7
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT7(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF7);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Clear Channel 8 half transfer flag.
* @rmtoll IFCR CHTIF8 LL_DMA_ClearFlag_HT8
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_HT8(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CHTIF8);
}
#endif /* DMA1_Channel8 */
/**
* @brief Clear Channel 1 transfer error flag.
* @rmtoll IFCR CTEIF1 LL_DMA_ClearFlag_TE1
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE1(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF1);
}
/**
* @brief Clear Channel 2 transfer error flag.
* @rmtoll IFCR CTEIF2 LL_DMA_ClearFlag_TE2
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE2(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF2);
}
/**
* @brief Clear Channel 3 transfer error flag.
* @rmtoll IFCR CTEIF3 LL_DMA_ClearFlag_TE3
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE3(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF3);
}
/**
* @brief Clear Channel 4 transfer error flag.
* @rmtoll IFCR CTEIF4 LL_DMA_ClearFlag_TE4
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE4(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF4);
}
/**
* @brief Clear Channel 5 transfer error flag.
* @rmtoll IFCR CTEIF5 LL_DMA_ClearFlag_TE5
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE5(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF5);
}
/**
* @brief Clear Channel 6 transfer error flag.
* @rmtoll IFCR CTEIF6 LL_DMA_ClearFlag_TE6
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE6(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF6);
}
#if defined (DMA1_Channel7)
/**
* @brief Clear Channel 7 transfer error flag.
* @rmtoll IFCR CTEIF7 LL_DMA_ClearFlag_TE7
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE7(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF7);
}
#endif /* DMA1_Channel7 */
#if defined (DMA1_Channel8)
/**
* @brief Clear Channel 8 transfer error flag.
* @rmtoll IFCR CTEIF8 LL_DMA_ClearFlag_TE8
* @param DMAx DMAx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMA_ClearFlag_TE8(DMA_TypeDef *DMAx)
{
WRITE_REG(DMAx->IFCR, DMA_IFCR_CTEIF8);
}
#endif /* DMA1_Channel8 */
/**
* @}
*/
/** @defgroup DMA_LL_EF_IT_Management IT_Management
* @{
*/
/**
* @brief Enable Transfer complete interrupt.
* @rmtoll CCR TCIE LL_DMA_EnableIT_TC
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_EnableIT_TC(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
SET_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_TCIE);
}
/**
* @brief Enable Half transfer interrupt.
* @rmtoll CCR HTIE LL_DMA_EnableIT_HT
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_EnableIT_HT(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
SET_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_HTIE);
}
/**
* @brief Enable Transfer error interrupt.
* @rmtoll CCR TEIE LL_DMA_EnableIT_TE
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_EnableIT_TE(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
SET_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_TEIE);
}
/**
* @brief Disable Transfer complete interrupt.
* @rmtoll CCR TCIE LL_DMA_DisableIT_TC
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_DisableIT_TC(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
CLEAR_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_TCIE);
}
/**
* @brief Disable Half transfer interrupt.
* @rmtoll CCR HTIE LL_DMA_DisableIT_HT
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_DisableIT_HT(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
CLEAR_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_HTIE);
}
/**
* @brief Disable Transfer error interrupt.
* @rmtoll CCR TEIE LL_DMA_DisableIT_TE
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMA_DisableIT_TE(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
CLEAR_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR, DMA_CCR_TEIE);
}
/**
* @brief Check if Transfer complete Interrupt is enabled.
* @rmtoll CCR TCIE LL_DMA_IsEnabledIT_TC
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsEnabledIT_TC(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return ((READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_TCIE) == (DMA_CCR_TCIE)) ? 1UL : 0UL);
}
/**
* @brief Check if Half transfer Interrupt is enabled.
* @rmtoll CCR HTIE LL_DMA_IsEnabledIT_HT
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsEnabledIT_HT(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return ((READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_HTIE) == (DMA_CCR_HTIE)) ? 1UL : 0UL);
}
/**
* @brief Check if Transfer error Interrupt is enabled.
* @rmtoll CCR TEIE LL_DMA_IsEnabledIT_TE
* @param DMAx DMAx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMA_CHANNEL_1
* @arg @ref LL_DMA_CHANNEL_2
* @arg @ref LL_DMA_CHANNEL_3
* @arg @ref LL_DMA_CHANNEL_4
* @arg @ref LL_DMA_CHANNEL_5
* @arg @ref LL_DMA_CHANNEL_6
* @arg @ref LL_DMA_CHANNEL_7 (*)
* @arg @ref LL_DMA_CHANNEL_8 (*)
* (*) Not on all G4 devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMA_IsEnabledIT_TE(DMA_TypeDef *DMAx, uint32_t Channel)
{
uint32_t dma_base_addr = (uint32_t)DMAx;
return ((READ_BIT(((DMA_Channel_TypeDef *)((uint32_t)(dma_base_addr + CHANNEL_OFFSET_TAB[Channel])))->CCR,
DMA_CCR_TEIE) == (DMA_CCR_TEIE)) ? 1UL : 0UL);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup DMA_LL_EF_Init Initialization and de-initialization functions
* @{
*/
uint32_t LL_DMA_Init(DMA_TypeDef *DMAx, uint32_t Channel, LL_DMA_InitTypeDef *DMA_InitStruct);
uint32_t LL_DMA_DeInit(DMA_TypeDef *DMAx, uint32_t Channel);
void LL_DMA_StructInit(LL_DMA_InitTypeDef *DMA_InitStruct);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* DMA1 || DMA2 */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_LL_DMA_H */
| 104,723 | C | 39.606437 | 146 | 0.585497 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_rcc.h | /**
******************************************************************************
* @file stm32g4xx_hal_rcc.h
* @author MCD Application Team
* @brief Header file of RCC HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_RCC_H
#define STM32G4xx_HAL_RCC_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup RCC
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup RCC_Exported_Types RCC Exported Types
* @{
*/
/**
* @brief RCC PLL configuration structure definition
*/
typedef struct
{
uint32_t PLLState; /*!< The new state of the PLL.
This parameter can be a value of @ref RCC_PLL_Config */
uint32_t PLLSource; /*!< RCC_PLLSource: PLL entry clock source.
This parameter must be a value of @ref RCC_PLL_Clock_Source */
uint32_t PLLM; /*!< PLLM: Division factor for PLL VCO input clock.
This parameter must be a value of @ref RCC_PLLM_Clock_Divider */
uint32_t PLLN; /*!< PLLN: Multiplication factor for PLL VCO output clock.
This parameter must be a number between Min_Data = 8 and Max_Data = 127 */
uint32_t PLLP; /*!< PLLP: Division factor for ADC clock.
This parameter must be a value of @ref RCC_PLLP_Clock_Divider */
uint32_t PLLQ; /*!< PLLQ: Division factor for SAI, I2S, USB, FDCAN and QUADSPI clocks.
This parameter must be a value of @ref RCC_PLLQ_Clock_Divider */
uint32_t PLLR; /*!< PLLR: Division for the main system clock.
User have to set the PLLR parameter correctly to not exceed max frequency 170MHZ.
This parameter must be a value of @ref RCC_PLLR_Clock_Divider */
}RCC_PLLInitTypeDef;
/**
* @brief RCC Internal/External Oscillator (HSE, HSI, LSE and LSI) configuration structure definition
*/
typedef struct
{
uint32_t OscillatorType; /*!< The oscillators to be configured.
This parameter can be a value of @ref RCC_Oscillator_Type */
uint32_t HSEState; /*!< The new state of the HSE.
This parameter can be a value of @ref RCC_HSE_Config */
uint32_t LSEState; /*!< The new state of the LSE.
This parameter can be a value of @ref RCC_LSE_Config */
uint32_t HSIState; /*!< The new state of the HSI.
This parameter can be a value of @ref RCC_HSI_Config */
uint32_t HSICalibrationValue; /*!< The calibration trimming value (default is RCC_HSICALIBRATION_DEFAULT).
This parameter must be a number between Min_Data = 0x00 and Max_Data = 0xFF */
uint32_t LSIState; /*!< The new state of the LSI.
This parameter can be a value of @ref RCC_LSI_Config */
uint32_t HSI48State; /*!< The new state of the HSI48.
This parameter can be a value of @ref RCC_HSI48_Config */
RCC_PLLInitTypeDef PLL; /*!< Main PLL structure parameters */
}RCC_OscInitTypeDef;
/**
* @brief RCC System, AHB and APB busses clock configuration structure definition
*/
typedef struct
{
uint32_t ClockType; /*!< The clock to be configured.
This parameter can be a value of @ref RCC_System_Clock_Type */
uint32_t SYSCLKSource; /*!< The clock source used as system clock (SYSCLK).
This parameter can be a value of @ref RCC_System_Clock_Source */
uint32_t AHBCLKDivider; /*!< The AHB clock (HCLK) divider. This clock is derived from the system clock (SYSCLK).
This parameter can be a value of @ref RCC_AHB_Clock_Source */
uint32_t APB1CLKDivider; /*!< The APB1 clock (PCLK1) divider. This clock is derived from the AHB clock (HCLK).
This parameter can be a value of @ref RCC_APB1_APB2_Clock_Source */
uint32_t APB2CLKDivider; /*!< The APB2 clock (PCLK2) divider. This clock is derived from the AHB clock (HCLK).
This parameter can be a value of @ref RCC_APB1_APB2_Clock_Source */
}RCC_ClkInitTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup RCC_Exported_Constants RCC Exported Constants
* @{
*/
/** @defgroup RCC_Timeout_Value Timeout Values
* @{
*/
#define RCC_DBP_TIMEOUT_VALUE 2U /* 2 ms (minimum Tick + 1) */
#define RCC_LSE_TIMEOUT_VALUE LSE_STARTUP_TIMEOUT
/**
* @}
*/
/** @defgroup RCC_Oscillator_Type Oscillator Type
* @{
*/
#define RCC_OSCILLATORTYPE_NONE 0x00000000U /*!< Oscillator configuration unchanged */
#define RCC_OSCILLATORTYPE_HSE 0x00000001U /*!< HSE to configure */
#define RCC_OSCILLATORTYPE_HSI 0x00000002U /*!< HSI to configure */
#define RCC_OSCILLATORTYPE_LSE 0x00000004U /*!< LSE to configure */
#define RCC_OSCILLATORTYPE_LSI 0x00000008U /*!< LSI to configure */
#define RCC_OSCILLATORTYPE_HSI48 0x00000020U /*!< HSI48 to configure */
/**
* @}
*/
/** @defgroup RCC_HSE_Config HSE Config
* @{
*/
#define RCC_HSE_OFF 0x00000000U /*!< HSE clock deactivation */
#define RCC_HSE_ON RCC_CR_HSEON /*!< HSE clock activation */
#define RCC_HSE_BYPASS (RCC_CR_HSEBYP | RCC_CR_HSEON) /*!< External clock source for HSE clock */
/**
* @}
*/
/** @defgroup RCC_LSE_Config LSE Config
* @{
*/
#define RCC_LSE_OFF 0x00000000U /*!< LSE clock deactivation */
#define RCC_LSE_ON RCC_BDCR_LSEON /*!< LSE clock activation */
#define RCC_LSE_BYPASS (RCC_BDCR_LSEBYP | RCC_BDCR_LSEON) /*!< External clock source for LSE clock */
/**
* @}
*/
/** @defgroup RCC_HSI_Config HSI Config
* @{
*/
#define RCC_HSI_OFF 0x00000000U /*!< HSI clock deactivation */
#define RCC_HSI_ON RCC_CR_HSION /*!< HSI clock activation */
#define RCC_HSICALIBRATION_DEFAULT 0x40U /* Default HSI calibration trimming value */
/**
* @}
*/
/** @defgroup RCC_LSI_Config LSI Config
* @{
*/
#define RCC_LSI_OFF 0x00000000U /*!< LSI clock deactivation */
#define RCC_LSI_ON RCC_CSR_LSION /*!< LSI clock activation */
/**
* @}
*/
/** @defgroup RCC_HSI48_Config HSI48 Config
* @{
*/
#define RCC_HSI48_OFF 0x00000000U /*!< HSI48 clock deactivation */
#define RCC_HSI48_ON RCC_CRRCR_HSI48ON /*!< HSI48 clock activation */
/**
* @}
*/
/** @defgroup RCC_PLL_Config PLL Config
* @{
*/
#define RCC_PLL_NONE 0x00000000U /*!< PLL configuration unchanged */
#define RCC_PLL_OFF 0x00000001U /*!< PLL deactivation */
#define RCC_PLL_ON 0x00000002U /*!< PLL activation */
/**
* @}
*/
/** @defgroup RCC_PLLM_Clock_Divider PLLM Clock Divider
* @{
*/
#define RCC_PLLM_DIV1 0x00000001U /*!< PLLM division factor = 1 */
#define RCC_PLLM_DIV2 0x00000002U /*!< PLLM division factor = 2 */
#define RCC_PLLM_DIV3 0x00000003U /*!< PLLM division factor = 3 */
#define RCC_PLLM_DIV4 0x00000004U /*!< PLLM division factor = 4 */
#define RCC_PLLM_DIV5 0x00000005U /*!< PLLM division factor = 5 */
#define RCC_PLLM_DIV6 0x00000006U /*!< PLLM division factor = 6 */
#define RCC_PLLM_DIV7 0x00000007U /*!< PLLM division factor = 7 */
#define RCC_PLLM_DIV8 0x00000008U /*!< PLLM division factor = 8 */
#define RCC_PLLM_DIV9 0x00000009U /*!< PLLM division factor = 9 */
#define RCC_PLLM_DIV10 0x0000000AU /*!< PLLM division factor = 10 */
#define RCC_PLLM_DIV11 0x0000000BU /*!< PLLM division factor = 11 */
#define RCC_PLLM_DIV12 0x0000000CU /*!< PLLM division factor = 12 */
#define RCC_PLLM_DIV13 0x0000000DU /*!< PLLM division factor = 13 */
#define RCC_PLLM_DIV14 0x0000000EU /*!< PLLM division factor = 14 */
#define RCC_PLLM_DIV15 0x0000000FU /*!< PLLM division factor = 15 */
#define RCC_PLLM_DIV16 0x00000010U /*!< PLLM division factor = 16 */
/**
* @}
*/
/** @defgroup RCC_PLLP_Clock_Divider PLLP Clock Divider
* @{
*/
#define RCC_PLLP_DIV2 0x00000002U /*!< PLLP division factor = 2 */
#define RCC_PLLP_DIV3 0x00000003U /*!< PLLP division factor = 3 */
#define RCC_PLLP_DIV4 0x00000004U /*!< PLLP division factor = 4 */
#define RCC_PLLP_DIV5 0x00000005U /*!< PLLP division factor = 5 */
#define RCC_PLLP_DIV6 0x00000006U /*!< PLLP division factor = 6 */
#define RCC_PLLP_DIV7 0x00000007U /*!< PLLP division factor = 7 */
#define RCC_PLLP_DIV8 0x00000008U /*!< PLLP division factor = 8 */
#define RCC_PLLP_DIV9 0x00000009U /*!< PLLP division factor = 9 */
#define RCC_PLLP_DIV10 0x0000000AU /*!< PLLP division factor = 10 */
#define RCC_PLLP_DIV11 0x0000000BU /*!< PLLP division factor = 11 */
#define RCC_PLLP_DIV12 0x0000000CU /*!< PLLP division factor = 12 */
#define RCC_PLLP_DIV13 0x0000000DU /*!< PLLP division factor = 13 */
#define RCC_PLLP_DIV14 0x0000000EU /*!< PLLP division factor = 14 */
#define RCC_PLLP_DIV15 0x0000000FU /*!< PLLP division factor = 15 */
#define RCC_PLLP_DIV16 0x00000010U /*!< PLLP division factor = 16 */
#define RCC_PLLP_DIV17 0x00000011U /*!< PLLP division factor = 17 */
#define RCC_PLLP_DIV18 0x00000012U /*!< PLLP division factor = 18 */
#define RCC_PLLP_DIV19 0x00000013U /*!< PLLP division factor = 19 */
#define RCC_PLLP_DIV20 0x00000014U /*!< PLLP division factor = 20 */
#define RCC_PLLP_DIV21 0x00000015U /*!< PLLP division factor = 21 */
#define RCC_PLLP_DIV22 0x00000016U /*!< PLLP division factor = 22 */
#define RCC_PLLP_DIV23 0x00000017U /*!< PLLP division factor = 23 */
#define RCC_PLLP_DIV24 0x00000018U /*!< PLLP division factor = 24 */
#define RCC_PLLP_DIV25 0x00000019U /*!< PLLP division factor = 25 */
#define RCC_PLLP_DIV26 0x0000001AU /*!< PLLP division factor = 26 */
#define RCC_PLLP_DIV27 0x0000001BU /*!< PLLP division factor = 27 */
#define RCC_PLLP_DIV28 0x0000001CU /*!< PLLP division factor = 28 */
#define RCC_PLLP_DIV29 0x0000001DU /*!< PLLP division factor = 29 */
#define RCC_PLLP_DIV30 0x0000001EU /*!< PLLP division factor = 30 */
#define RCC_PLLP_DIV31 0x0000001FU /*!< PLLP division factor = 31 */
/**
* @}
*/
/** @defgroup RCC_PLLQ_Clock_Divider PLLQ Clock Divider
* @{
*/
#define RCC_PLLQ_DIV2 0x00000002U /*!< PLLQ division factor = 2 */
#define RCC_PLLQ_DIV4 0x00000004U /*!< PLLQ division factor = 4 */
#define RCC_PLLQ_DIV6 0x00000006U /*!< PLLQ division factor = 6 */
#define RCC_PLLQ_DIV8 0x00000008U /*!< PLLQ division factor = 8 */
/**
* @}
*/
/** @defgroup RCC_PLLR_Clock_Divider PLLR Clock Divider
* @{
*/
#define RCC_PLLR_DIV2 0x00000002U /*!< PLLR division factor = 2 */
#define RCC_PLLR_DIV4 0x00000004U /*!< PLLR division factor = 4 */
#define RCC_PLLR_DIV6 0x00000006U /*!< PLLR division factor = 6 */
#define RCC_PLLR_DIV8 0x00000008U /*!< PLLR division factor = 8 */
/**
* @}
*/
/** @defgroup RCC_PLL_Clock_Source PLL Clock Source
* @{
*/
#define RCC_PLLSOURCE_NONE 0x00000000U /*!< No clock selected as PLL entry clock source */
#define RCC_PLLSOURCE_HSI RCC_PLLCFGR_PLLSRC_HSI /*!< HSI clock selected as PLL entry clock source */
#define RCC_PLLSOURCE_HSE RCC_PLLCFGR_PLLSRC_HSE /*!< HSE clock selected as PLL entry clock source */
/**
* @}
*/
/** @defgroup RCC_PLL_Clock_Output PLL Clock Output
* @{
*/
#define RCC_PLL_ADCCLK RCC_PLLCFGR_PLLPEN /*!< PLLADCCLK selection from main PLL */
#define RCC_PLL_48M1CLK RCC_PLLCFGR_PLLQEN /*!< PLL48M1CLK selection from main PLL */
#define RCC_PLL_SYSCLK RCC_PLLCFGR_PLLREN /*!< PLLCLK selection from main PLL */
/**
* @}
*/
/** @defgroup RCC_System_Clock_Type System Clock Type
* @{
*/
#define RCC_CLOCKTYPE_SYSCLK 0x00000001U /*!< SYSCLK to configure */
#define RCC_CLOCKTYPE_HCLK 0x00000002U /*!< HCLK to configure */
#define RCC_CLOCKTYPE_PCLK1 0x00000004U /*!< PCLK1 to configure */
#define RCC_CLOCKTYPE_PCLK2 0x00000008U /*!< PCLK2 to configure */
/**
* @}
*/
/** @defgroup RCC_System_Clock_Source System Clock Source
* @{
*/
#define RCC_SYSCLKSOURCE_HSI RCC_CFGR_SW_HSI /*!< HSI selection as system clock */
#define RCC_SYSCLKSOURCE_HSE RCC_CFGR_SW_HSE /*!< HSE selection as system clock */
#define RCC_SYSCLKSOURCE_PLLCLK RCC_CFGR_SW_PLL /*!< PLL selection as system clock */
/**
* @}
*/
/** @defgroup RCC_System_Clock_Source_Status System Clock Source Status
* @{
*/
#define RCC_SYSCLKSOURCE_STATUS_HSI RCC_CFGR_SWS_HSI /*!< HSI used as system clock */
#define RCC_SYSCLKSOURCE_STATUS_HSE RCC_CFGR_SWS_HSE /*!< HSE used as system clock */
#define RCC_SYSCLKSOURCE_STATUS_PLLCLK RCC_CFGR_SWS_PLL /*!< PLL used as system clock */
/**
* @}
*/
/** @defgroup RCC_AHB_Clock_Source AHB Clock Source
* @{
*/
#define RCC_SYSCLK_DIV1 RCC_CFGR_HPRE_DIV1 /*!< SYSCLK not divided */
#define RCC_SYSCLK_DIV2 RCC_CFGR_HPRE_DIV2 /*!< SYSCLK divided by 2 */
#define RCC_SYSCLK_DIV4 RCC_CFGR_HPRE_DIV4 /*!< SYSCLK divided by 4 */
#define RCC_SYSCLK_DIV8 RCC_CFGR_HPRE_DIV8 /*!< SYSCLK divided by 8 */
#define RCC_SYSCLK_DIV16 RCC_CFGR_HPRE_DIV16 /*!< SYSCLK divided by 16 */
#define RCC_SYSCLK_DIV64 RCC_CFGR_HPRE_DIV64 /*!< SYSCLK divided by 64 */
#define RCC_SYSCLK_DIV128 RCC_CFGR_HPRE_DIV128 /*!< SYSCLK divided by 128 */
#define RCC_SYSCLK_DIV256 RCC_CFGR_HPRE_DIV256 /*!< SYSCLK divided by 256 */
#define RCC_SYSCLK_DIV512 RCC_CFGR_HPRE_DIV512 /*!< SYSCLK divided by 512 */
/**
* @}
*/
/** @defgroup RCC_APB1_APB2_Clock_Source APB1 APB2 Clock Source
* @{
*/
#define RCC_HCLK_DIV1 RCC_CFGR_PPRE1_DIV1 /*!< HCLK not divided */
#define RCC_HCLK_DIV2 RCC_CFGR_PPRE1_DIV2 /*!< HCLK divided by 2 */
#define RCC_HCLK_DIV4 RCC_CFGR_PPRE1_DIV4 /*!< HCLK divided by 4 */
#define RCC_HCLK_DIV8 RCC_CFGR_PPRE1_DIV8 /*!< HCLK divided by 8 */
#define RCC_HCLK_DIV16 RCC_CFGR_PPRE1_DIV16 /*!< HCLK divided by 16 */
/**
* @}
*/
/** @defgroup RCC_RTC_Clock_Source RTC Clock Source
* @{
*/
#define RCC_RTCCLKSOURCE_NONE 0x00000000U /*!< No clock used as RTC clock */
#define RCC_RTCCLKSOURCE_LSE RCC_BDCR_RTCSEL_0 /*!< LSE oscillator clock used as RTC clock */
#define RCC_RTCCLKSOURCE_LSI RCC_BDCR_RTCSEL_1 /*!< LSI oscillator clock used as RTC clock */
#define RCC_RTCCLKSOURCE_HSE_DIV32 RCC_BDCR_RTCSEL /*!< HSE oscillator clock divided by 32 used as RTC clock */
/**
* @}
*/
/** @defgroup RCC_MCO_Index MCO Index
* @{
*/
/* 32 28 20 16 0
--------------------------------
| MCO | GPIO | GPIO | GPIO |
| Index | AF | Port | Pin |
-------------------------------*/
#define RCC_MCO_GPIOPORT_POS 16U
#define RCC_MCO_GPIOPORT_MASK (0xFUL << RCC_MCO_GPIOPORT_POS)
#define RCC_MCO_GPIOAF_POS 20U
#define RCC_MCO_GPIOAF_MASK (0xFFUL << RCC_MCO_GPIOAF_POS)
#define RCC_MCO_INDEX_POS 28U
#define RCC_MCO_INDEX_MASK (0x1UL << RCC_MCO_INDEX_POS)
#define RCC_MCO1_INDEX (0x0UL << RCC_MCO_INDEX_POS) /*!< MCO1 index */
#define RCC_MCO_PA8 (RCC_MCO1_INDEX | (GPIO_AF0_MCO << RCC_MCO_GPIOAF_POS) | (GPIO_GET_INDEX(GPIOA) << RCC_MCO_GPIOPORT_POS) | GPIO_PIN_8)
#define RCC_MCO_PG10 (RCC_MCO1_INDEX | (GPIO_AF0_MCO << RCC_MCO_GPIOAF_POS) | (GPIO_GET_INDEX(GPIOG) << RCC_MCO_GPIOPORT_POS) | GPIO_PIN_10)
/* Legacy Defines*/
#define RCC_MCO1 RCC_MCO_PA8
#define RCC_MCO RCC_MCO1 /*!< MCO1 to be compliant with other families with 2 MCOs*/
/**
* @}
*/
/** @defgroup RCC_MCO1_Clock_Source MCO1 Clock Source
* @{
*/
#define RCC_MCO1SOURCE_NOCLOCK 0x00000000U /*!< MCO1 output disabled, no clock on MCO1 */
#define RCC_MCO1SOURCE_SYSCLK RCC_CFGR_MCOSEL_0 /*!< SYSCLK selection as MCO1 source */
#define RCC_MCO1SOURCE_HSI (RCC_CFGR_MCOSEL_0| RCC_CFGR_MCOSEL_1) /*!< HSI selection as MCO1 source */
#define RCC_MCO1SOURCE_HSE RCC_CFGR_MCOSEL_2 /*!< HSE selection as MCO1 source */
#define RCC_MCO1SOURCE_PLLCLK (RCC_CFGR_MCOSEL_0|RCC_CFGR_MCOSEL_2) /*!< PLLCLK selection as MCO1 source */
#define RCC_MCO1SOURCE_LSI (RCC_CFGR_MCOSEL_1|RCC_CFGR_MCOSEL_2) /*!< LSI selection as MCO1 source */
#define RCC_MCO1SOURCE_LSE (RCC_CFGR_MCOSEL_0|RCC_CFGR_MCOSEL_1|RCC_CFGR_MCOSEL_2) /*!< LSE selection as MCO1 source */
#define RCC_MCO1SOURCE_HSI48 RCC_CFGR_MCOSEL_3 /*!< HSI48 selection as MCO1 source */
/**
* @}
*/
/** @defgroup RCC_MCOx_Clock_Prescaler MCO1 Clock Prescaler
* @{
*/
#define RCC_MCODIV_1 RCC_CFGR_MCOPRE_DIV1 /*!< MCO not divided */
#define RCC_MCODIV_2 RCC_CFGR_MCOPRE_DIV2 /*!< MCO divided by 2 */
#define RCC_MCODIV_4 RCC_CFGR_MCOPRE_DIV4 /*!< MCO divided by 4 */
#define RCC_MCODIV_8 RCC_CFGR_MCOPRE_DIV8 /*!< MCO divided by 8 */
#define RCC_MCODIV_16 RCC_CFGR_MCOPRE_DIV16 /*!< MCO divided by 16 */
/**
* @}
*/
/** @defgroup RCC_Interrupt Interrupts
* @{
*/
#define RCC_IT_LSIRDY RCC_CIFR_LSIRDYF /*!< LSI Ready Interrupt flag */
#define RCC_IT_LSERDY RCC_CIFR_LSERDYF /*!< LSE Ready Interrupt flag */
#define RCC_IT_HSIRDY RCC_CIFR_HSIRDYF /*!< HSI16 Ready Interrupt flag */
#define RCC_IT_HSERDY RCC_CIFR_HSERDYF /*!< HSE Ready Interrupt flag */
#define RCC_IT_PLLRDY RCC_CIFR_PLLRDYF /*!< PLL Ready Interrupt flag */
#define RCC_IT_CSS RCC_CIFR_CSSF /*!< Clock Security System Interrupt flag */
#define RCC_IT_LSECSS RCC_CIFR_LSECSSF /*!< LSE Clock Security System Interrupt flag */
#define RCC_IT_HSI48RDY RCC_CIFR_HSI48RDYF /*!< HSI48 Ready Interrupt flag */
/**
* @}
*/
/** @defgroup RCC_Flag Flags
* Elements values convention: XXXYYYYYb
* - YYYYY : Flag position in the register
* - XXX : Register index
* - 001: CR register
* - 010: BDCR register
* - 011: CSR register
* - 100: CRRCR register
* @{
*/
/* Flags in the CR register */
#define RCC_FLAG_HSIRDY ((CR_REG_INDEX << 5U) | RCC_CR_HSIRDY_Pos) /*!< HSI Ready flag */
#define RCC_FLAG_HSERDY ((CR_REG_INDEX << 5U) | RCC_CR_HSERDY_Pos) /*!< HSE Ready flag */
#define RCC_FLAG_PLLRDY ((CR_REG_INDEX << 5U) | RCC_CR_PLLRDY_Pos) /*!< PLL Ready flag */
/* Flags in the BDCR register */
#define RCC_FLAG_LSERDY ((BDCR_REG_INDEX << 5U) | RCC_BDCR_LSERDY_Pos) /*!< LSE Ready flag */
#define RCC_FLAG_LSECSSD ((BDCR_REG_INDEX << 5U) | RCC_BDCR_LSECSSD_Pos) /*!< LSE Clock Security System Interrupt flag */
/* Flags in the CSR register */
#define RCC_FLAG_LSIRDY ((CSR_REG_INDEX << 5U) | RCC_CSR_LSIRDY_Pos) /*!< LSI Ready flag */
#define RCC_FLAG_OBLRST ((CSR_REG_INDEX << 5U) | RCC_CSR_OBLRSTF_Pos) /*!< Option Byte Loader reset flag */
#define RCC_FLAG_PINRST ((CSR_REG_INDEX << 5U) | RCC_CSR_PINRSTF_Pos) /*!< PIN reset flag */
#define RCC_FLAG_BORRST ((CSR_REG_INDEX << 5U) | RCC_CSR_BORRSTF_Pos) /*!< BOR reset flag */
#define RCC_FLAG_SFTRST ((CSR_REG_INDEX << 5U) | RCC_CSR_SFTRSTF_Pos) /*!< Software Reset flag */
#define RCC_FLAG_IWDGRST ((CSR_REG_INDEX << 5U) | RCC_CSR_IWDGRSTF_Pos) /*!< Independent Watchdog reset flag */
#define RCC_FLAG_WWDGRST ((CSR_REG_INDEX << 5U) | RCC_CSR_WWDGRSTF_Pos) /*!< Window watchdog reset flag */
#define RCC_FLAG_LPWRRST ((CSR_REG_INDEX << 5U) | RCC_CSR_LPWRRSTF_Pos) /*!< Low-Power reset flag */
/* Flags in the CRRCR register */
#define RCC_FLAG_HSI48RDY ((CRRCR_REG_INDEX << 5U) | RCC_CRRCR_HSI48RDY_Pos) /*!< HSI48 Ready flag */
/**
* @}
*/
/** @defgroup RCC_LSEDrive_Config LSE Drive Config
* @{
*/
#define RCC_LSEDRIVE_LOW 0x00000000U /*!< LSE low drive capability */
#define RCC_LSEDRIVE_MEDIUMLOW RCC_BDCR_LSEDRV_0 /*!< LSE medium low drive capability */
#define RCC_LSEDRIVE_MEDIUMHIGH RCC_BDCR_LSEDRV_1 /*!< LSE medium high drive capability */
#define RCC_LSEDRIVE_HIGH RCC_BDCR_LSEDRV /*!< LSE high drive capability */
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup RCC_Exported_Macros RCC Exported Macros
* @{
*/
/** @defgroup RCC_AHB1_Peripheral_Clock_Enable_Disable AHB1 Peripheral Clock Enable Disable
* @brief Enable or disable the AHB1 peripheral clock.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_DMA1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA1EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_DMA2_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA2EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA2EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_DMAMUX1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMAMUX1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMAMUX1EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_CORDIC_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CORDICEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CORDICEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_FMAC_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FMACEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FMACEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_FLASH_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FLASHEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FLASHEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_CRC_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CRCEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CRCEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_DMA1_CLK_DISABLE() CLEAR_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA1EN)
#define __HAL_RCC_DMA2_CLK_DISABLE() CLEAR_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA2EN)
#define __HAL_RCC_DMAMUX1_CLK_DISABLE() CLEAR_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMAMUX1EN)
#define __HAL_RCC_CORDIC_CLK_DISABLE() CLEAR_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CORDICEN)
#define __HAL_RCC_FMAC_CLK_DISABLE() CLEAR_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FMACEN)
#define __HAL_RCC_FLASH_CLK_DISABLE() CLEAR_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FLASHEN)
#define __HAL_RCC_CRC_CLK_DISABLE() CLEAR_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CRCEN)
/**
* @}
*/
/** @defgroup RCC_AHB2_Peripheral_Clock_Enable_Disable AHB2 Peripheral Clock Enable Disable
* @brief Enable or disable the AHB2 peripheral clock.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_GPIOA_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOAEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOAEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_GPIOB_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOBEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOBEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_GPIOC_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOCEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOCEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_GPIOD_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIODEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIODEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_GPIOE_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOEEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOEEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_GPIOF_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOFEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOFEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_GPIOG_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOGEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOGEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_ADC12_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC12EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC12EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC345EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC345EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC1EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(DAC2)
#define __HAL_RCC_DAC2_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC2EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC2EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC3EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC3EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(DAC4)
#define __HAL_RCC_DAC4_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC4EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC4EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_AESEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_AESEN); \
UNUSED(tmpreg); \
} while(0)
#endif /* AES */
#define __HAL_RCC_RNG_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB2ENR, RCC_AHB2ENR_RNGEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_RNGEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_GPIOA_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOAEN)
#define __HAL_RCC_GPIOB_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOBEN)
#define __HAL_RCC_GPIOC_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOCEN)
#define __HAL_RCC_GPIOD_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIODEN)
#define __HAL_RCC_GPIOE_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOEEN)
#define __HAL_RCC_GPIOF_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOFEN)
#define __HAL_RCC_GPIOG_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOGEN)
#define __HAL_RCC_ADC12_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC12EN)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC345EN)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC1EN)
#if defined(DAC2)
#define __HAL_RCC_DAC2_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC2EN)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC3EN)
#if defined(DAC4)
#define __HAL_RCC_DAC4_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC4EN)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_AESEN);
#endif /* AES */
#define __HAL_RCC_RNG_CLK_DISABLE() CLEAR_BIT(RCC->AHB2ENR, RCC_AHB2ENR_RNGEN)
/**
* @}
*/
/** @defgroup RCC_AHB3_Clock_Enable_Disable AHB3 Peripheral Clock Enable Disable
* @brief Enable or disable the AHB3 peripheral clock.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB3ENR, RCC_AHB3ENR_FMCEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB3ENR, RCC_AHB3ENR_FMCEN); \
UNUSED(tmpreg); \
} while(0)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->AHB3ENR, RCC_AHB3ENR_QSPIEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->AHB3ENR, RCC_AHB3ENR_QSPIEN); \
UNUSED(tmpreg); \
} while(0)
#endif /* QUADSPI */
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_CLK_DISABLE() CLEAR_BIT(RCC->AHB3ENR, RCC_AHB3ENR_FMCEN)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_CLK_DISABLE() CLEAR_BIT(RCC->AHB3ENR, RCC_AHB3ENR_QSPIEN)
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup RCC_APB1_Clock_Enable_Disable APB1 Peripheral Clock Enable Disable
* @brief Enable or disable the APB1 peripheral clock.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_TIM2_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM2EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM2EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM3_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM3EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM3EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM4_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM4EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM4EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(TIM5)
#define __HAL_RCC_TIM5_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM5EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM5EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM6EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM6EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM7_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM7EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM7EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_CRS_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_CRSEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_CRSEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_RTCAPB_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_RTCAPBEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_RTCAPBEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_WWDG_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_WWDGEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_WWDGEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_SPI2_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI2EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI2EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_SPI3_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI3EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI3EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_USART2_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART2EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART2EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_USART3_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART3EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART3EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(UART4)
#define __HAL_RCC_UART4_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART4EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART4EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART5EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART5EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* UART5 */
#define __HAL_RCC_I2C1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C1EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_I2C2_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C2EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C2EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_USB_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USBEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USBEN); \
UNUSED(tmpreg); \
} while(0)
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_FDCANEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_FDCANEN); \
UNUSED(tmpreg); \
} while(0)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_PWREN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_PWREN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_I2C3_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C3EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C3EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_LPTIM1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR1, RCC_APB1ENR1_LPTIM1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_LPTIM1EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_LPUART1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR2, RCC_APB1ENR2_LPUART1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_LPUART1EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(I2C4)
#define __HAL_RCC_I2C4_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR2, RCC_APB1ENR2_I2C4EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_I2C4EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB1ENR2, RCC_APB1ENR2_UCPD1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_UCPD1EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM2_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM2EN)
#define __HAL_RCC_TIM3_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM3EN)
#define __HAL_RCC_TIM4_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM4EN)
#if defined(TIM5)
#define __HAL_RCC_TIM5_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM5EN)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM6EN)
#define __HAL_RCC_TIM7_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM7EN)
#define __HAL_RCC_CRS_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_CRSEN);
#define __HAL_RCC_RTCAPB_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_RTCAPBEN);
#define __HAL_RCC_WWDG_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_WWDGEN)
#define __HAL_RCC_SPI2_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI2EN)
#define __HAL_RCC_SPI3_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI3EN)
#define __HAL_RCC_USART2_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART2EN)
#define __HAL_RCC_USART3_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART3EN)
#if defined(UART4)
#define __HAL_RCC_UART4_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART4EN)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART5EN)
#endif /* UART5 */
#define __HAL_RCC_I2C1_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C1EN)
#define __HAL_RCC_I2C2_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C2EN)
#define __HAL_RCC_USB_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USBEN)
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_FDCANEN)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_PWREN)
#define __HAL_RCC_I2C3_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C3EN)
#define __HAL_RCC_LPTIM1_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR1, RCC_APB1ENR1_LPTIM1EN)
#define __HAL_RCC_LPUART1_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR2, RCC_APB1ENR2_LPUART1EN)
#if defined(I2C4)
#define __HAL_RCC_I2C4_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR2, RCC_APB1ENR2_I2C4EN)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_CLK_DISABLE() CLEAR_BIT(RCC->APB1ENR2, RCC_APB1ENR2_UCPD1EN)
/**
* @}
*/
/** @defgroup RCC_APB2_Clock_Enable_Disable APB2 Peripheral Clock Enable Disable
* @brief Enable or disable the APB2 peripheral clock.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_SYSCFG_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_SYSCFGEN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SYSCFGEN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM1EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_SPI1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI1EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM8_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM8EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM8EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_USART1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_USART1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_USART1EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(SPI4)
#define __HAL_RCC_SPI4_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI4EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI4EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM15EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM15EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM16_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM16EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM16EN); \
UNUSED(tmpreg); \
} while(0)
#define __HAL_RCC_TIM17_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM17EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM17EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(TIM20)
#define __HAL_RCC_TIM20_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM20EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM20EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_SAI1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SAI1EN); \
UNUSED(tmpreg); \
} while(0)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_CLK_ENABLE() do { \
__IO uint32_t tmpreg; \
SET_BIT(RCC->APB2ENR, RCC_APB2ENR_HRTIM1EN); \
/* Delay after an RCC peripheral clock enabling */ \
tmpreg = READ_BIT(RCC->APB2ENR, RCC_APB2ENR_HRTIM1EN); \
UNUSED(tmpreg); \
} while(0)
#endif /* HRTIM1 */
#define __HAL_RCC_SYSCFG_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_SYSCFGEN)
#define __HAL_RCC_TIM1_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM1EN)
#define __HAL_RCC_SPI1_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI1EN)
#define __HAL_RCC_TIM8_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM8EN)
#define __HAL_RCC_USART1_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_USART1EN)
#if defined(SPI4)
#define __HAL_RCC_SPI4_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI4EN)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM15EN)
#define __HAL_RCC_TIM16_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM16EN)
#define __HAL_RCC_TIM17_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM17EN)
#if defined(TIM20)
#define __HAL_RCC_TIM20_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM20EN)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_SAI1EN)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_CLK_DISABLE() CLEAR_BIT(RCC->APB2ENR, RCC_APB2ENR_HRTIM1EN)
#endif /* HRTIM1 */
/**
* @}
*/
/** @defgroup RCC_AHB1_Peripheral_Clock_Enable_Disable_Status AHB1 Peripheral Clock Enabled or Disabled Status
* @brief Check whether the AHB1 peripheral clock is enabled or not.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_DMA1_IS_CLK_ENABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA1EN) != 0U)
#define __HAL_RCC_DMA2_IS_CLK_ENABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA2EN) != 0U)
#define __HAL_RCC_DMAMUX1_IS_CLK_ENABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMAMUX1EN) != 0U)
#define __HAL_RCC_CORDIC_IS_CLK_ENABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CORDICEN) != 0U)
#define __HAL_RCC_FMAC_IS_CLK_ENABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FMACEN) != 0U)
#define __HAL_RCC_FLASH_IS_CLK_ENABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FLASHEN) != 0U)
#define __HAL_RCC_CRC_IS_CLK_ENABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CRCEN) != 0U)
#define __HAL_RCC_DMA1_IS_CLK_DISABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA1EN) == 0U)
#define __HAL_RCC_DMA2_IS_CLK_DISABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMA2EN) == 0U)
#define __HAL_RCC_DMAMUX1_IS_CLK_DISABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_DMAMUX1EN) == 0U)
#define __HAL_RCC_CORDIC_IS_CLK_DISABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CORDICEN) == 0U)
#define __HAL_RCC_FMAC_IS_CLK_DISABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FMACEN) == 0U)
#define __HAL_RCC_FLASH_IS_CLK_DISABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_FLASHEN) == 0U)
#define __HAL_RCC_CRC_IS_CLK_DISABLED() (READ_BIT(RCC->AHB1ENR, RCC_AHB1ENR_CRCEN) == 0U)
/**
* @}
*/
/** @defgroup RCC_AHB2_Clock_Enable_Disable_Status AHB2 Peripheral Clock Enabled or Disabled Status
* @brief Check whether the AHB2 peripheral clock is enabled or not.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_GPIOA_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOAEN) != 0U)
#define __HAL_RCC_GPIOB_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOBEN) != 0U)
#define __HAL_RCC_GPIOC_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOCEN) != 0U)
#define __HAL_RCC_GPIOD_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIODEN) != 0U)
#define __HAL_RCC_GPIOE_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOEEN) != 0U)
#define __HAL_RCC_GPIOF_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOFEN) != 0U)
#define __HAL_RCC_GPIOG_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOGEN) != 0U)
#define __HAL_RCC_ADC12_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC12EN) != 0U)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC345EN) != 0U)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC1EN) != 0U)
#if defined(DAC2)
#define __HAL_RCC_DAC2_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC2EN) != 0U)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC3EN) != 0U)
#if defined(DAC4)
#define __HAL_RCC_DAC4_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC4EN) != 0U)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_AESEN) != 0U)
#endif /* AES */
#define __HAL_RCC_RNG_IS_CLK_ENABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_RNGEN) != 0U)
#define __HAL_RCC_GPIOA_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOAEN) == 0U)
#define __HAL_RCC_GPIOB_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOBEN) == 0U)
#define __HAL_RCC_GPIOC_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOCEN) == 0U)
#define __HAL_RCC_GPIOD_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIODEN) == 0U)
#define __HAL_RCC_GPIOE_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOEEN) == 0U)
#define __HAL_RCC_GPIOF_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOFEN) == 0U)
#define __HAL_RCC_GPIOG_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_GPIOGEN) == 0U)
#define __HAL_RCC_ADC12_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC12EN) == 0U)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_ADC345EN) == 0U)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC1EN) == 0U)
#if defined(DAC2)
#define __HAL_RCC_DAC2_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC2EN) == 0U)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC3EN) == 0U)
#if defined(DAC4)
#define __HAL_RCC_DAC4_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_DAC4EN) == 0U)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_AESEN) == 0U)
#endif /* AES */
#define __HAL_RCC_RNG_IS_CLK_DISABLED() (READ_BIT(RCC->AHB2ENR, RCC_AHB2ENR_RNGEN) == 0U)
/**
* @}
*/
/** @defgroup RCC_AHB3_Clock_Enable_Disable_Status AHB3 Peripheral Clock Enabled or Disabled Status
* @brief Check whether the AHB3 peripheral clock is enabled or not.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_IS_CLK_ENABLED() (READ_BIT(RCC->AHB3ENR, RCC_AHB3ENR_FMCEN) != 0U)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_IS_CLK_ENABLED() (READ_BIT(RCC->AHB3ENR, RCC_AHB3ENR_QSPIEN) != 0U)
#endif /* QUADSPI */
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_IS_CLK_DISABLED() (READ_BIT(RCC->AHB3ENR, RCC_AHB3ENR_FMCEN) == 0U)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_IS_CLK_DISABLED() (READ_BIT(RCC->AHB3ENR, RCC_AHB3ENR_QSPIEN) == 0U)
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup RCC_APB1_Clock_Enable_Disable_Status APB1 Peripheral Clock Enabled or Disabled Status
* @brief Check whether the APB1 peripheral clock is enabled or not.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_TIM2_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM2EN) != 0U)
#define __HAL_RCC_TIM3_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM3EN) != 0U)
#define __HAL_RCC_TIM4_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM4EN) != 0U)
#if defined(TIM5)
#define __HAL_RCC_TIM5_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM5EN) != 0U)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM6EN) != 0U)
#define __HAL_RCC_TIM7_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM7EN) != 0U)
#define __HAL_RCC_CRS_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_CRSEN) != 0U)
#define __HAL_RCC_RTCAPB_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_RTCAPBEN) != 0U)
#define __HAL_RCC_WWDG_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_WWDGEN) != 0U)
#define __HAL_RCC_SPI2_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI2EN) != 0U)
#define __HAL_RCC_SPI3_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI3EN) != 0U)
#define __HAL_RCC_USART2_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART2EN) != 0U)
#define __HAL_RCC_USART3_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART3EN) != 0U)
#if defined(UART4)
#define __HAL_RCC_UART4_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART4EN) != 0U)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART5EN) != 0U)
#endif /* UART5 */
#define __HAL_RCC_I2C1_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C1EN) != 0U)
#define __HAL_RCC_I2C2_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C2EN) != 0U)
#define __HAL_RCC_USB_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USBEN) != 0U)
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_FDCANEN) != 0U)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_PWREN) != 0U)
#define __HAL_RCC_I2C3_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C3EN) != 0U)
#define __HAL_RCC_LPTIM1_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_LPTIM1EN) != 0U)
#define __HAL_RCC_LPUART1_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_LPUART1EN) != 0U)
#if defined(I2C4)
#define __HAL_RCC_I2C4_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_I2C4EN) != 0U)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_IS_CLK_ENABLED() (READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_UCPD1EN) != 0U)
#define __HAL_RCC_TIM2_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM2EN) == 0U)
#define __HAL_RCC_TIM3_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM3EN) == 0U)
#define __HAL_RCC_TIM4_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM4EN) == 0U)
#if defined(TIM5)
#define __HAL_RCC_TIM5_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM5EN) == 0U)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM6EN) == 0U)
#define __HAL_RCC_TIM7_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_TIM7EN) == 0U)
#define __HAL_RCC_CRS_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_CRSEN) == 0U)
#define __HAL_RCC_RTCAPB_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_RTCAPBEN) == 0U)
#define __HAL_RCC_WWDG_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_WWDGEN) == 0U)
#define __HAL_RCC_SPI2_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI2EN) == 0U)
#define __HAL_RCC_SPI3_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_SPI3EN) == 0U)
#define __HAL_RCC_USART2_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART2EN) == 0U)
#define __HAL_RCC_USART3_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USART3EN) == 0U)
#if defined(UART4)
#define __HAL_RCC_UART4_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART4EN) == 0U)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_UART5EN) == 0U)
#endif /* UART5 */
#define __HAL_RCC_I2C1_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C1EN) == 0U)
#define __HAL_RCC_I2C2_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C2EN) == 0U)
#if defined(USB)
#define __HAL_RCC_USB_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_USBEN) == 0U)
#endif /* USB */
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_FDCANEN) == 0U)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_PWREN) == 0U)
#define __HAL_RCC_I2C3_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_I2C3EN) == 0U)
#define __HAL_RCC_LPTIM1_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR1, RCC_APB1ENR1_LPTIM1EN) == 0U)
#define __HAL_RCC_LPUART1_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_LPUART1EN) == 0U)
#if defined(I2C4)
#define __HAL_RCC_I2C4_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_I2C4EN) == 0U)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_IS_CLK_DISABLED() (READ_BIT(RCC->APB1ENR2, RCC_APB1ENR2_UCPD1EN) == 0U)
/**
* @}
*/
/** @defgroup RCC_APB2_Clock_Enable_Disable_Status APB2 Peripheral Clock Enabled or Disabled Status
* @brief Check whether the APB2 peripheral clock is enabled or not.
* @note After reset, the peripheral clock (used for registers read/write access)
* is disabled and the application software has to enable this clock before
* using it.
* @{
*/
#define __HAL_RCC_SYSCFG_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SYSCFGEN) != 0U)
#define __HAL_RCC_TIM1_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM1EN) != 0U)
#define __HAL_RCC_SPI1_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI1EN) != 0U)
#define __HAL_RCC_TIM8_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM8EN) != 0U)
#define __HAL_RCC_USART1_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_USART1EN) != 0U)
#if defined(SPI4)
#define __HAL_RCC_SPI4_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI4EN) != 0U)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM15EN) != 0U)
#define __HAL_RCC_TIM16_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM16EN) != 0U)
#define __HAL_RCC_TIM17_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM17EN) != 0U)
#if defined(TIM20)
#define __HAL_RCC_TIM20_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM20EN) != 0U)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SAI1EN) != 0U)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_IS_CLK_ENABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_HRTIM1EN) != 0U)
#endif /* HRTIM1 */
#define __HAL_RCC_SYSCFG_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SYSCFGEN) == 0U)
#define __HAL_RCC_TIM1_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM1EN) == 0U)
#define __HAL_RCC_SPI1_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI1EN) == 0U)
#define __HAL_RCC_TIM8_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM8EN) == 0U)
#define __HAL_RCC_USART1_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_USART1EN) == 0U)
#if defined(SPI4)
#define __HAL_RCC_SPI4_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SPI4EN) == 0U)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM15EN) == 0U)
#define __HAL_RCC_TIM16_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM16EN) == 0U)
#define __HAL_RCC_TIM17_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM17EN) == 0U)
#if defined(TIM20)
#define __HAL_RCC_TIM20_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_TIM20EN) == 0U)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_SAI1EN) == 0U)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_IS_CLK_DISABLED() (READ_BIT(RCC->APB2ENR, RCC_APB2ENR_HRTIM1EN) == 0U)
#endif /* HRTIM1 */
/**
* @}
*/
/** @defgroup RCC_AHB1_Force_Release_Reset AHB1 Peripheral Force Release Reset
* @brief Force or release AHB1 peripheral reset.
* @{
*/
#define __HAL_RCC_AHB1_FORCE_RESET() WRITE_REG(RCC->AHB1RSTR, 0xFFFFFFFFU)
#define __HAL_RCC_DMA1_FORCE_RESET() SET_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_DMA1RST)
#define __HAL_RCC_DMA2_FORCE_RESET() SET_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_DMA2RST)
#define __HAL_RCC_DMAMUX1_FORCE_RESET() SET_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_DMAMUX1RST)
#define __HAL_RCC_CORDIC_FORCE_RESET() SET_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_CORDICRST)
#define __HAL_RCC_FMAC_FORCE_RESET() SET_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_FMACRST)
#define __HAL_RCC_FLASH_FORCE_RESET() SET_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_FLASHRST)
#define __HAL_RCC_CRC_FORCE_RESET() SET_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_CRCRST)
#define __HAL_RCC_AHB1_RELEASE_RESET() WRITE_REG(RCC->AHB1RSTR, 0x00000000U)
#define __HAL_RCC_DMA1_RELEASE_RESET() CLEAR_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_DMA1RST)
#define __HAL_RCC_DMA2_RELEASE_RESET() CLEAR_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_DMA2RST)
#define __HAL_RCC_DMAMUX1_RELEASE_RESET() CLEAR_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_DMAMUX1RST)
#define __HAL_RCC_CORDIC_RELEASE_RESET() CLEAR_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_CORDICRST)
#define __HAL_RCC_FMAC_RELEASE_RESET() CLEAR_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_FMACRST)
#define __HAL_RCC_FLASH_RELEASE_RESET() CLEAR_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_FLASHRST)
#define __HAL_RCC_CRC_RELEASE_RESET() CLEAR_BIT(RCC->AHB1RSTR, RCC_AHB1RSTR_CRCRST)
/**
* @}
*/
/** @defgroup RCC_AHB2_Force_Release_Reset AHB2 Peripheral Force Release Reset
* @brief Force or release AHB2 peripheral reset.
* @{
*/
#define __HAL_RCC_AHB2_FORCE_RESET() WRITE_REG(RCC->AHB2RSTR, 0xFFFFFFFFU)
#define __HAL_RCC_GPIOA_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOARST)
#define __HAL_RCC_GPIOB_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOBRST)
#define __HAL_RCC_GPIOC_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOCRST)
#define __HAL_RCC_GPIOD_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIODRST)
#define __HAL_RCC_GPIOE_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOERST)
#define __HAL_RCC_GPIOF_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOFRST)
#define __HAL_RCC_GPIOG_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOGRST)
#define __HAL_RCC_ADC12_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_ADC12RST)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_ADC345RST)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC1RST)
#if defined(DAC2)
#define __HAL_RCC_DAC2_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC2RST)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC3RST)
#if defined(DAC4)
#define __HAL_RCC_DAC4_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC4RST)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_AESRST)
#endif /* AES */
#define __HAL_RCC_RNG_FORCE_RESET() SET_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_RNGRST)
#define __HAL_RCC_AHB2_RELEASE_RESET() WRITE_REG(RCC->AHB2RSTR, 0x00000000U)
#define __HAL_RCC_GPIOA_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOARST)
#define __HAL_RCC_GPIOB_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOBRST)
#define __HAL_RCC_GPIOC_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOCRST)
#define __HAL_RCC_GPIOD_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIODRST)
#define __HAL_RCC_GPIOE_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOERST)
#define __HAL_RCC_GPIOF_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOFRST)
#define __HAL_RCC_GPIOG_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_GPIOGRST)
#define __HAL_RCC_ADC12_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_ADC12RST)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_ADC345RST)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC1RST)
#if defined(DAC2)
#define __HAL_RCC_DAC2_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC2RST)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC3RST)
#if defined(DAC4)
#define __HAL_RCC_DAC4_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_DAC4RST)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_AESRST)
#endif /* AES */
#define __HAL_RCC_RNG_RELEASE_RESET() CLEAR_BIT(RCC->AHB2RSTR, RCC_AHB2RSTR_RNGRST)
/**
* @}
*/
/** @defgroup RCC_AHB3_Force_Release_Reset AHB3 Peripheral Force Release Reset
* @brief Force or release AHB3 peripheral reset.
* @{
*/
#define __HAL_RCC_AHB3_FORCE_RESET() WRITE_REG(RCC->AHB3RSTR, 0xFFFFFFFFU)
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_FORCE_RESET() SET_BIT(RCC->AHB3RSTR, RCC_AHB3RSTR_FMCRST)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_FORCE_RESET() SET_BIT(RCC->AHB3RSTR, RCC_AHB3RSTR_QSPIRST)
#endif /* QUADSPI */
#define __HAL_RCC_AHB3_RELEASE_RESET() WRITE_REG(RCC->AHB3RSTR, 0x00000000U)
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_RELEASE_RESET() CLEAR_BIT(RCC->AHB3RSTR, RCC_AHB3RSTR_FMCRST)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_RELEASE_RESET() CLEAR_BIT(RCC->AHB3RSTR, RCC_AHB3RSTR_QSPIRST)
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup RCC_APB1_Force_Release_Reset APB1 Peripheral Force Release Reset
* @brief Force or release APB1 peripheral reset.
* @{
*/
#define __HAL_RCC_APB1_FORCE_RESET() WRITE_REG(RCC->APB1RSTR1, 0xFFFFFFFFU)
#define __HAL_RCC_TIM2_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM2RST)
#define __HAL_RCC_TIM3_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM3RST)
#define __HAL_RCC_TIM4_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM4RST)
#if defined(TIM5)
#define __HAL_RCC_TIM5_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM5RST)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM6RST)
#define __HAL_RCC_TIM7_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM7RST)
#define __HAL_RCC_CRS_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_CRSRST)
#define __HAL_RCC_SPI2_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_SPI2RST)
#define __HAL_RCC_SPI3_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_SPI3RST)
#define __HAL_RCC_USART2_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_USART2RST)
#define __HAL_RCC_USART3_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_USART3RST)
#if defined(UART4)
#define __HAL_RCC_UART4_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_UART4RST)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_UART5RST)
#endif /* UART5 */
#define __HAL_RCC_I2C1_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_I2C1RST)
#define __HAL_RCC_I2C2_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_I2C2RST)
#define __HAL_RCC_USB_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_USBRST)
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_FDCANRST)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_PWRRST)
#define __HAL_RCC_I2C3_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_I2C3RST)
#define __HAL_RCC_LPTIM1_FORCE_RESET() SET_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_LPTIM1RST)
#define __HAL_RCC_LPUART1_FORCE_RESET() SET_BIT(RCC->APB1RSTR2, RCC_APB1RSTR2_LPUART1RST)
#if defined(I2C4)
#define __HAL_RCC_I2C4_FORCE_RESET() SET_BIT(RCC->APB1RSTR2, RCC_APB1RSTR2_I2C4RST)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_FORCE_RESET() SET_BIT(RCC->APB1RSTR2, RCC_APB1RSTR2_UCPD1RST)
#define __HAL_RCC_APB1_RELEASE_RESET() WRITE_REG(RCC->APB1RSTR1, 0x00000000U)
#define __HAL_RCC_TIM2_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM2RST)
#define __HAL_RCC_TIM3_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM3RST)
#define __HAL_RCC_TIM4_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM4RST)
#if defined(TIM5)
#define __HAL_RCC_TIM5_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM5RST)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM6RST)
#define __HAL_RCC_TIM7_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_TIM7RST)
#define __HAL_RCC_CRS_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_CRSRST)
#define __HAL_RCC_SPI2_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_SPI2RST)
#define __HAL_RCC_SPI3_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_SPI3RST)
#define __HAL_RCC_USART2_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_USART2RST)
#define __HAL_RCC_USART3_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_USART3RST)
#if defined(UART4)
#define __HAL_RCC_UART4_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_UART4RST)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_UART5RST)
#endif /* UART5 */
#define __HAL_RCC_I2C1_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_I2C1RST)
#define __HAL_RCC_I2C2_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_I2C2RST)
#define __HAL_RCC_USB_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_USBRST)
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_FDCANRST)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_PWRRST)
#define __HAL_RCC_I2C3_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_I2C3RST)
#define __HAL_RCC_LPTIM1_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR1, RCC_APB1RSTR1_LPTIM1RST)
#define __HAL_RCC_LPUART1_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR2, RCC_APB1RSTR2_LPUART1RST)
#if defined(I2C4)
#define __HAL_RCC_I2C4_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR2, RCC_APB1RSTR2_I2C4RST)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_RELEASE_RESET() CLEAR_BIT(RCC->APB1RSTR2, RCC_APB1RSTR2_UCPD1RST)
/**
* @}
*/
/** @defgroup RCC_APB2_Force_Release_Reset APB2 Peripheral Force Release Reset
* @brief Force or release APB2 peripheral reset.
* @{
*/
#define __HAL_RCC_APB2_FORCE_RESET() WRITE_REG(RCC->APB2RSTR, 0xFFFFFFFFU)
#define __HAL_RCC_SYSCFG_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SYSCFGRST)
#define __HAL_RCC_TIM1_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM1RST)
#define __HAL_RCC_SPI1_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SPI1RST)
#define __HAL_RCC_TIM8_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM8RST)
#define __HAL_RCC_USART1_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_USART1RST)
#if defined(SPI4)
#define __HAL_RCC_SPI4_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SPI4RST)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM15RST)
#define __HAL_RCC_TIM16_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM16RST)
#define __HAL_RCC_TIM17_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM17RST)
#if defined(TIM20)
#define __HAL_RCC_TIM20_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM20RST)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SAI1RST)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_FORCE_RESET() SET_BIT(RCC->APB2RSTR, RCC_APB2RSTR_HRTIM1RST)
#endif /* HRTIM1 */
#define __HAL_RCC_APB2_RELEASE_RESET() WRITE_REG(RCC->APB2RSTR, 0x00000000U)
#define __HAL_RCC_SYSCFG_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SYSCFGRST)
#define __HAL_RCC_TIM1_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM1RST)
#define __HAL_RCC_SPI1_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SPI1RST)
#define __HAL_RCC_TIM8_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM8RST)
#define __HAL_RCC_USART1_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_USART1RST)
#if defined(SPI4)
#define __HAL_RCC_SPI4_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SPI4RST)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM15RST)
#define __HAL_RCC_TIM16_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM16RST)
#define __HAL_RCC_TIM17_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM17RST)
#if defined(TIM20)
#define __HAL_RCC_TIM20_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_TIM20RST)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_SAI1RST)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_RELEASE_RESET() CLEAR_BIT(RCC->APB2RSTR, RCC_APB2RSTR_HRTIM1RST)
#endif /* HRTIM1 */
/**
* @}
*/
/** @defgroup RCC_AHB1_Clock_Sleep_Enable_Disable AHB1 Peripheral Clock Sleep Enable Disable
* @brief Enable or disable the AHB1 peripheral clock during Low Power (Sleep) mode.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_DMA1_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA1SMEN)
#define __HAL_RCC_DMA2_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA2SMEN)
#define __HAL_RCC_DMAMUX1_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMAMUX1SMEN)
#define __HAL_RCC_CORDIC_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CORDICSMEN)
#define __HAL_RCC_FMAC_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FMACSMEN)
#define __HAL_RCC_FLASH_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FLASHSMEN)
#define __HAL_RCC_SRAM1_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_SRAM1SMEN)
#define __HAL_RCC_CRC_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CRCSMEN)
#define __HAL_RCC_DMA1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA1SMEN)
#define __HAL_RCC_DMA2_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA2SMEN)
#define __HAL_RCC_DMAMUX1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMAMUX1SMEN)
#define __HAL_RCC_CORDIC_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CORDICSMEN)
#define __HAL_RCC_FMAC_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FMACSMEN)
#define __HAL_RCC_FLASH_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FLASHSMEN)
#define __HAL_RCC_SRAM1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_SRAM1SMEN)
#define __HAL_RCC_CRC_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CRCSMEN)
/**
* @}
*/
/** @defgroup RCC_AHB2_Clock_Sleep_Enable_Disable AHB2 Peripheral Clock Sleep Enable Disable
* @brief Enable or disable the AHB2 peripheral clock during Low Power (Sleep) mode.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_GPIOA_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOASMEN)
#define __HAL_RCC_GPIOB_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOBSMEN)
#define __HAL_RCC_GPIOC_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOCSMEN)
#define __HAL_RCC_GPIOD_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIODSMEN)
#define __HAL_RCC_GPIOE_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOESMEN)
#define __HAL_RCC_GPIOF_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOFSMEN)
#define __HAL_RCC_GPIOG_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOGSMEN)
#define __HAL_RCC_SRAM2_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_SRAM2SMEN)
#define __HAL_RCC_CCM_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_CCMSRAMSMEN)
#define __HAL_RCC_ADC12_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC12SMEN)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC345SMEN)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC1SMEN)
#if defined(DAC2)
#define __HAL_RCC_DAC2_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC2SMEN)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC3SMEN)
#if defined(DAC4)
#define __HAL_RCC_DAC4_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC4SMEN)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_AESSMEN)
#endif /* AES */
#define __HAL_RCC_RNG_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_RNGSMEN)
#define __HAL_RCC_GPIOA_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOASMEN)
#define __HAL_RCC_GPIOB_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOBSMEN)
#define __HAL_RCC_GPIOC_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOCSMEN)
#define __HAL_RCC_GPIOD_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIODSMEN)
#define __HAL_RCC_GPIOE_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOESMEN)
#define __HAL_RCC_GPIOF_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOFSMEN)
#define __HAL_RCC_GPIOG_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOGSMEN)
#define __HAL_RCC_SRAM2_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_SRAM2SMEN)
#define __HAL_RCC_CCM_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_CCMSRAMSMEN)
#define __HAL_RCC_ADC12_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC12SMEN)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC345SMEN)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC1SMEN)
#if defined(DAC2)
#define __HAL_RCC_DAC2_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC2SMEN)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC3SMEN)
#if defined(DAC4)
#define __HAL_RCC_DAC4_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC4SMEN)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_AESSMEN)
#endif /* AES */
#define __HAL_RCC_RNG_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_RNGSMEN)
/**
* @}
*/
/** @defgroup RCC_AHB3_Clock_Sleep_Enable_Disable AHB3 Peripheral Clock Sleep Enable Disable
* @brief Enable or disable the AHB3 peripheral clock during Low Power (Sleep) mode.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_FMCSMEN)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_CLK_SLEEP_ENABLE() SET_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_QSPISMEN)
#endif /* QUADSPI */
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_FMCSMEN)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_QSPISMEN)
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup RCC_APB1_Clock_Sleep_Enable_Disable APB1 Peripheral Clock Sleep Enable Disable
* @brief Enable or disable the APB1 peripheral clock during Low Power (Sleep) mode.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_TIM2_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM2SMEN)
#define __HAL_RCC_TIM3_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM3SMEN)
#define __HAL_RCC_TIM4_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM4SMEN)
#if defined(TIM5)
#define __HAL_RCC_TIM5_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM5SMEN)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM6SMEN)
#define __HAL_RCC_TIM7_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM7SMEN)
#define __HAL_RCC_CRS_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_CRSSMEN)
#define __HAL_RCC_RTCAPB_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_RTCAPBSMEN)
#define __HAL_RCC_WWDG_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_WWDGSMEN)
#define __HAL_RCC_SPI2_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI2SMEN)
#define __HAL_RCC_SPI3_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI3SMEN)
#define __HAL_RCC_USART2_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART2SMEN)
#define __HAL_RCC_USART3_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART3SMEN)
#if defined(UART4)
#define __HAL_RCC_UART4_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART4SMEN)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART5SMEN)
#endif /* UART5 */
#define __HAL_RCC_I2C1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C1SMEN)
#define __HAL_RCC_I2C2_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C2SMEN)
#if defined(USB)
#define __HAL_RCC_USB_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USBSMEN)
#endif /* USB */
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_FDCANSMEN)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_PWRSMEN)
#define __HAL_RCC_I2C3_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C3SMEN)
#define __HAL_RCC_LPTIM1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_LPTIM1SMEN)
#define __HAL_RCC_LPUART1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_LPUART1SMEN)
#if defined(I2C4)
#define __HAL_RCC_I2C4_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_I2C4SMEN)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_UCPD1SMEN)
#define __HAL_RCC_TIM2_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM2SMEN)
#define __HAL_RCC_TIM3_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM3SMEN)
#define __HAL_RCC_TIM4_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM4SMEN)
#if defined(TIM5)
#define __HAL_RCC_TIM5_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM5SMEN)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM6SMEN)
#define __HAL_RCC_TIM7_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM7SMEN)
#define __HAL_RCC_CRS_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_CRSSMEN)
#define __HAL_RCC_RTCAPB_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_RTCAPBSMEN)
#define __HAL_RCC_WWDG_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_WWDGSMEN)
#define __HAL_RCC_SPI2_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI2SMEN)
#define __HAL_RCC_SPI3_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI3SMEN)
#define __HAL_RCC_USART2_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART2SMEN)
#define __HAL_RCC_USART3_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART3SMEN)
#if defined(UART4)
#define __HAL_RCC_UART4_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART4SMEN)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART5SMEN)
#endif /* UART5 */
#define __HAL_RCC_I2C1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C1SMEN)
#define __HAL_RCC_I2C2_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C2SMEN)
#if defined(USB)
#define __HAL_RCC_USB_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USBSMEN)
#endif /* USB */
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_FDCANSMEN)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_PWRSMEN)
#define __HAL_RCC_I2C3_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C3SMEN)
#define __HAL_RCC_LPTIM1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_LPTIM1SMEN)
#define __HAL_RCC_LPUART1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_LPUART1SMEN)
#if defined(I2C4)
#define __HAL_RCC_I2C4_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_I2C4SMEN)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_UCPD1SMEN)
/**
* @}
*/
/** @defgroup RCC_APB2_Clock_Sleep_Enable_Disable APB2 Peripheral Clock Sleep Enable Disable
* @brief Enable or disable the APB2 peripheral clock during Low Power (Sleep) mode.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_SYSCFG_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SYSCFGSMEN)
#define __HAL_RCC_TIM1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM1SMEN)
#define __HAL_RCC_SPI1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI1SMEN)
#define __HAL_RCC_TIM8_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM8SMEN)
#define __HAL_RCC_USART1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_USART1SMEN)
#if defined(SPI4)
#define __HAL_RCC_SPI4_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI4SMEN)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM15SMEN)
#define __HAL_RCC_TIM16_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM16SMEN)
#define __HAL_RCC_TIM17_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM17SMEN)
#if defined(TIM20)
#define __HAL_RCC_TIM20_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM20SMEN)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SAI1SMEN)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_CLK_SLEEP_ENABLE() SET_BIT(RCC->APB2SMENR, RCC_APB2SMENR_HRTIM1SMEN)
#endif /* HRTIM1 */
#define __HAL_RCC_SYSCFG_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SYSCFGSMEN)
#define __HAL_RCC_TIM1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM1SMEN)
#define __HAL_RCC_SPI1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI1SMEN)
#define __HAL_RCC_TIM8_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM8SMEN)
#define __HAL_RCC_USART1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_USART1SMEN)
#if defined(SPI4)
#define __HAL_RCC_SPI4_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI4SMEN)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM15SMEN)
#define __HAL_RCC_TIM16_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM16SMEN)
#define __HAL_RCC_TIM17_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM17SMEN)
#if defined(TIM20)
#define __HAL_RCC_TIM20_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM20SMEN)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SAI1SMEN)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_CLK_SLEEP_DISABLE() CLEAR_BIT(RCC->APB2SMENR, RCC_APB2SMENR_HRTIM1SMEN)
#endif /* HRTIM1 */
/**
* @}
*/
/** @defgroup RCC_AHB1_Clock_Sleep_Enable_Disable_Status AHB1 Peripheral Clock Sleep Enabled or Disabled Status
* @brief Check whether the AHB1 peripheral clock during Low Power (Sleep) mode is enabled or not.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_DMA1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA1SMEN) != 0U)
#define __HAL_RCC_DMA2_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA2SMEN) != 0U)
#define __HAL_RCC_DMAMUX1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMAMUX1SMEN) != 0U)
#define __HAL_RCC_CORDIC_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CORDICSMEN) != 0U)
#define __HAL_RCC_FMAC_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FMACSMEN) != 0U)
#define __HAL_RCC_FLASH_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FLASHSMEN) != 0U)
#define __HAL_RCC_SRAM1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_SRAM1SMEN) != 0U)
#define __HAL_RCC_CRC_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CRCSMEN) != 0U)
#define __HAL_RCC_DMA1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA1SMEN) == 0U)
#define __HAL_RCC_DMA2_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMA2SMEN) == 0U)
#define __HAL_RCC_DMAMUX1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_DMAMUX1SMEN) == 0U)
#define __HAL_RCC_CORDIC_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CORDICSMEN) == 0U)
#define __HAL_RCC_FMAC_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FMACSMEN) == 0U)
#define __HAL_RCC_FLASH_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_FLASHSMEN) == 0U)
#define __HAL_RCC_SRAM1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_SRAM1SMEN) == 0U)
#define __HAL_RCC_CRC_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB1SMENR, RCC_AHB1SMENR_CRCSMEN) == 0U)
/**
* @}
*/
/** @defgroup RCC_AHB2_Clock_Sleep_Enable_Disable_Status AHB2 Peripheral Clock Sleep Enabled or Disabled Status
* @brief Check whether the AHB2 peripheral clock during Low Power (Sleep) mode is enabled or not.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_GPIOA_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOASMEN) != 0U)
#define __HAL_RCC_GPIOB_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOBSMEN) != 0U)
#define __HAL_RCC_GPIOC_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOCSMEN) != 0U)
#define __HAL_RCC_GPIOD_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIODSMEN) != 0U)
#define __HAL_RCC_GPIOE_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOESMEN) != 0U)
#define __HAL_RCC_GPIOF_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOFSMEN) != 0U)
#define __HAL_RCC_GPIOG_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOGSMEN) != 0U)
#define __HAL_RCC_SRAM2_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_SRAM2SMEN) != 0U)
#define __HAL_RCC_CCM_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_CCMSRAMSMEN) != 0U)
#define __HAL_RCC_ADC12_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC12SMEN) != 0U)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC345SMEN) != 0U)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC1SMEN) != 0U)
#if defined(DAC2)
#define __HAL_RCC_DAC2_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC2SMEN) != 0U)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC3SMEN) != 0U)
#if defined(DAC4)
#define __HAL_RCC_DAC4_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC4SMEN) != 0U)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_AESSMEN) != 0U)
#endif /* AES */
#define __HAL_RCC_RNG_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_RNGSMEN) != 0U)
#define __HAL_RCC_GPIOA_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOASMEN) == 0U)
#define __HAL_RCC_GPIOB_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOBSMEN) == 0U)
#define __HAL_RCC_GPIOC_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOCSMEN) == 0U)
#define __HAL_RCC_GPIOD_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIODSMEN) == 0U)
#define __HAL_RCC_GPIOE_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOESMEN) == 0U)
#define __HAL_RCC_GPIOF_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOFSMEN) == 0U)
#define __HAL_RCC_GPIOG_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_GPIOGSMEN) == 0U)
#define __HAL_RCC_SRAM2_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_SRAM2SMEN) == 0U)
#define __HAL_RCC_CCM_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_CCMSRAMSMEN) == 0U)
#define __HAL_RCC_ADC12_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC12SMEN) == 0U)
#if defined(ADC345_COMMON)
#define __HAL_RCC_ADC345_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_ADC345SMEN) == 0U)
#endif /* ADC345_COMMON */
#define __HAL_RCC_DAC1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC1SMEN) == 0U)
#if defined(DAC2)
#define __HAL_RCC_DAC2_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC2SMEN) == 0U)
#endif /* DAC2 */
#define __HAL_RCC_DAC3_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC3SMEN) == 0U)
#if defined(DAC4)
#define __HAL_RCC_DAC4_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_DAC4SMEN) == 0U)
#endif /* DAC4 */
#if defined(AES)
#define __HAL_RCC_AES_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_AESSMEN) == 0U)
#endif /* AES */
#define __HAL_RCC_RNG_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB2SMENR, RCC_AHB2SMENR_RNGSMEN) == 0U)
/**
* @}
*/
/** @defgroup RCC_AHB3_Clock_Sleep_Enable_Disable_Status AHB3 Peripheral Clock Sleep Enabled or Disabled Status
* @brief Check whether the AHB3 peripheral clock during Low Power (Sleep) mode is enabled or not.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_FMCSMEN) != 0U)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_QSPISMEN) != 0U)
#endif /* QUADSPI */
#if defined(FMC_BANK1)
#define __HAL_RCC_FMC_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_FMCSMEN) == 0U)
#endif /* FMC_BANK1 */
#if defined(QUADSPI)
#define __HAL_RCC_QSPI_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->AHB3SMENR, RCC_AHB3SMENR_QSPISMEN) == 0U)
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup RCC_APB1_Clock_Sleep_Enable_Disable_Status APB1 Peripheral Clock Sleep Enabled or Disabled Status
* @brief Check whether the APB1 peripheral clock during Low Power (Sleep) mode is enabled or not.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_TIM2_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM2SMEN) != 0U)
#define __HAL_RCC_TIM3_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM3SMEN) != 0U)
#define __HAL_RCC_TIM4_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM4SMEN) != 0U)
#if defined(TIM5)
#define __HAL_RCC_TIM5_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM5SMEN) != 0U)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM6SMEN) != 0U)
#define __HAL_RCC_TIM7_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM7SMEN) != 0U)
#define __HAL_RCC_CRS_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_CRSSMEN) != 0U)
#define __HAL_RCC_RTCAPB_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_RTCAPBSMEN) != 0U)
#define __HAL_RCC_WWDG_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_WWDGSMEN) != 0U)
#define __HAL_RCC_SPI2_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI2SMEN) != 0U)
#define __HAL_RCC_SPI3_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI3SMEN) != 0U)
#define __HAL_RCC_USART2_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART2SMEN) != 0U)
#define __HAL_RCC_USART3_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART3SMEN) != 0U)
#if defined(UART4)
#define __HAL_RCC_UART4_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART4SMEN) != 0U)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART5SMEN) != 0U)
#endif /* UART5 */
#define __HAL_RCC_I2C1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C1SMEN) != 0U)
#define __HAL_RCC_I2C2_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C2SMEN) != 0U)
#define __HAL_RCC_USB_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USBSMEN) != 0U)
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_FDCANSMEN) != 0U)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_PWRSMEN) != 0U)
#define __HAL_RCC_I2C3_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C3SMEN) != 0U)
#define __HAL_RCC_LPTIM1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_LPTIM1SMEN) != 0U)
#define __HAL_RCC_LPUART1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_LPUART1SMEN) != 0U)
#if defined(I2C4)
#define __HAL_RCC_I2C4_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_I2C4SMEN) != 0U)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_UCPD1SMEN) != 0U)
#define __HAL_RCC_TIM2_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM2SMEN) == 0U)
#define __HAL_RCC_TIM3_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM3SMEN) == 0U)
#define __HAL_RCC_TIM4_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM4SMEN) == 0U)
#if defined(TIM5)
#define __HAL_RCC_TIM5_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM5SMEN) == 0U)
#endif /* TIM5 */
#define __HAL_RCC_TIM6_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM6SMEN) == 0U)
#define __HAL_RCC_TIM7_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_TIM7SMEN) == 0U)
#define __HAL_RCC_CRS_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_CRSSMEN) == 0U)
#define __HAL_RCC_RTCAPB_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_RTCAPBSMEN) == 0U)
#define __HAL_RCC_WWDG_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_WWDGSMEN) == 0U)
#define __HAL_RCC_SPI2_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI2SMEN) == 0U)
#define __HAL_RCC_SPI3_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_SPI3SMEN) == 0U)
#define __HAL_RCC_USART2_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART2SMEN) == 0U)
#define __HAL_RCC_USART3_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USART3SMEN) == 0U)
#if defined(UART4)
#define __HAL_RCC_UART4_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART4SMEN) == 0U)
#endif /* UART4 */
#if defined(UART5)
#define __HAL_RCC_UART5_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_UART5SMEN) == 0U)
#endif /* UART5 */
#define __HAL_RCC_I2C1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C1SMEN) == 0U)
#define __HAL_RCC_I2C2_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C2SMEN) == 0U)
#define __HAL_RCC_USB_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_USBSMEN) == 0U)
#if defined(FDCAN1)
#define __HAL_RCC_FDCAN_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_FDCANSMEN) == 0U)
#endif /* FDCAN1 */
#define __HAL_RCC_PWR_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_PWRSMEN) == 0U)
#define __HAL_RCC_I2C3_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_I2C3SMEN) == 0U)
#define __HAL_RCC_LPTIM1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR1, RCC_APB1SMENR1_LPTIM1SMEN) == 0U)
#define __HAL_RCC_LPUART1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_LPUART1SMEN) == 0U)
#if defined(I2C4)
#define __HAL_RCC_I2C4_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_I2C4SMEN) == 0U)
#endif /* I2C4 */
#define __HAL_RCC_UCPD1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB1SMENR2, RCC_APB1SMENR2_UCPD1SMEN) == 0U)
/**
* @}
*/
/** @defgroup RCC_APB2_Clock_Sleep_Enable_Disable_Status APB2 Peripheral Clock Sleep Enabled or Disabled Status
* @brief Check whether the APB2 peripheral clock during Low Power (Sleep) mode is enabled or not.
* @note Peripheral clock gating in SLEEP mode can be used to further reduce
* power consumption.
* @note After wakeup from SLEEP mode, the peripheral clock is enabled again.
* @note By default, all peripheral clocks are enabled during SLEEP mode.
* @{
*/
#define __HAL_RCC_SYSCFG_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SYSCFGSMEN) != 0U)
#define __HAL_RCC_TIM1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM1SMEN) != 0U)
#define __HAL_RCC_SPI1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI1SMEN) != 0U)
#define __HAL_RCC_TIM8_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM8SMEN) != 0U)
#define __HAL_RCC_USART1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_USART1SMEN) != 0U)
#if defined(SPI4)
#define __HAL_RCC_SPI4_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI4SMEN) != 0U)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM15SMEN) != 0U)
#define __HAL_RCC_TIM16_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM16SMEN) != 0U)
#define __HAL_RCC_TIM17_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM17SMEN) != 0U)
#if defined(TIM20)
#define __HAL_RCC_TIM20_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM20SMEN) != 0U)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SAI1SMEN) != 0U)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_IS_CLK_SLEEP_ENABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_HRTIM1SMEN) != 0U)
#endif /* HRTIM1 */
#define __HAL_RCC_SYSCFG_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SYSCFGSMEN) == 0U)
#define __HAL_RCC_TIM1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM1SMEN) == 0U)
#define __HAL_RCC_SPI1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI1SMEN) == 0U)
#define __HAL_RCC_TIM8_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM8SMEN) == 0U)
#define __HAL_RCC_USART1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_USART1SMEN) == 0U)
#if defined(SPI4)
#define __HAL_RCC_SPI4_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SPI4SMEN) == 0U)
#endif /* SPI4 */
#define __HAL_RCC_TIM15_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM15SMEN) == 0U)
#define __HAL_RCC_TIM16_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM16SMEN) == 0U)
#define __HAL_RCC_TIM17_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM17SMEN) == 0U)
#if defined(TIM20)
#define __HAL_RCC_TIM20_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_TIM20SMEN) == 0U)
#endif /* TIM20 */
#define __HAL_RCC_SAI1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_SAI1SMEN) == 0U)
#if defined(HRTIM1)
#define __HAL_RCC_HRTIM1_IS_CLK_SLEEP_DISABLED() (READ_BIT(RCC->APB2SMENR, RCC_APB2SMENR_HRTIM1SMEN) == 0U)
#endif /* HRTIM1 */
/**
* @}
*/
/** @defgroup RCC_Backup_Domain_Reset RCC Backup Domain Reset
* @{
*/
/** @brief Macros to force or release the Backup domain reset.
* @note This function resets the RTC peripheral (including the backup registers)
* and the RTC clock source selection in RCC_CSR register.
* @note The BKPSRAM is not affected by this reset.
* @retval None
*/
#define __HAL_RCC_BACKUPRESET_FORCE() SET_BIT(RCC->BDCR, RCC_BDCR_BDRST)
#define __HAL_RCC_BACKUPRESET_RELEASE() CLEAR_BIT(RCC->BDCR, RCC_BDCR_BDRST)
/**
* @}
*/
/** @defgroup RCC_RTC_Clock_Configuration RCC RTC Clock Configuration
* @{
*/
/** @brief Macros to enable or disable the RTC clock.
* @note As the RTC is in the Backup domain and write access is denied to
* this domain after reset, you have to enable write access using
* HAL_PWR_EnableBkUpAccess() function before to configure the RTC
* (to be done once after reset).
* @note These macros must be used after the RTC clock source was selected.
* @retval None
*/
#define __HAL_RCC_RTC_ENABLE() SET_BIT(RCC->BDCR, RCC_BDCR_RTCEN)
#define __HAL_RCC_RTC_DISABLE() CLEAR_BIT(RCC->BDCR, RCC_BDCR_RTCEN)
/**
* @}
*/
/** @brief Macros to enable or disable the Internal High Speed 16MHz oscillator (HSI).
* @note The HSI is stopped by hardware when entering STOP and STANDBY modes.
* It is used (enabled by hardware) as system clock source after startup
* from Reset, wakeup from STOP and STANDBY mode, or in case of failure
* of the HSE used directly or indirectly as system clock (if the Clock
* Security System CSS is enabled).
* @note HSI can not be stopped if it is used as system clock source. In this case,
* you have to select another source of the system clock then stop the HSI.
* @note After enabling the HSI, the application software should wait on HSIRDY
* flag to be set indicating that HSI clock is stable and can be used as
* system clock source.
* This parameter can be: ENABLE or DISABLE.
* @note When the HSI is stopped, HSIRDY flag goes low after 6 HSI oscillator
* clock cycles.
* @retval None
*/
#define __HAL_RCC_HSI_ENABLE() SET_BIT(RCC->CR, RCC_CR_HSION)
#define __HAL_RCC_HSI_DISABLE() CLEAR_BIT(RCC->CR, RCC_CR_HSION)
/** @brief Macro to adjust the Internal High Speed 16MHz oscillator (HSI) calibration value.
* @note The calibration is used to compensate for the variations in voltage
* and temperature that influence the frequency of the internal HSI RC.
* @param __HSICALIBRATIONVALUE__ specifies the calibration trimming value
* (default is RCC_HSICALIBRATION_DEFAULT).
* This parameter must be a number between 0 and 0x7F.
* @retval None
*/
#define __HAL_RCC_HSI_CALIBRATIONVALUE_ADJUST(__HSICALIBRATIONVALUE__) \
MODIFY_REG(RCC->ICSCR, RCC_ICSCR_HSITRIM, (__HSICALIBRATIONVALUE__) << RCC_ICSCR_HSITRIM_Pos)
/**
* @brief Macros to enable or disable the force of the Internal High Speed oscillator (HSI)
* in STOP mode to be quickly available as kernel clock for USARTs and I2Cs.
* @note Keeping the HSI ON in STOP mode allows to avoid slowing down the communication
* speed because of the HSI startup time.
* @note The enable of this function has not effect on the HSION bit.
* This parameter can be: ENABLE or DISABLE.
* @retval None
*/
#define __HAL_RCC_HSISTOP_ENABLE() SET_BIT(RCC->CR, RCC_CR_HSIKERON)
#define __HAL_RCC_HSISTOP_DISABLE() CLEAR_BIT(RCC->CR, RCC_CR_HSIKERON)
/** @brief Macros to enable or disable the Internal Low Speed oscillator (LSI).
* @note After enabling the LSI, the application software should wait on
* LSIRDY flag to be set indicating that LSI clock is stable and can
* be used to clock the IWDG and/or the RTC.
* @note LSI can not be disabled if the IWDG is running.
* @note When the LSI is stopped, LSIRDY flag goes low after 6 LSI oscillator
* clock cycles.
* @retval None
*/
#define __HAL_RCC_LSI_ENABLE() SET_BIT(RCC->CSR, RCC_CSR_LSION)
#define __HAL_RCC_LSI_DISABLE() CLEAR_BIT(RCC->CSR, RCC_CSR_LSION)
/**
* @brief Macro to configure the External High Speed oscillator (HSE).
* @note Transition HSE Bypass to HSE On and HSE On to HSE Bypass are not
* supported by this macro. User should request a transition to HSE Off
* first and then HSE On or HSE Bypass.
* @note After enabling the HSE (RCC_HSE_ON or RCC_HSE_Bypass), the application
* software should wait on HSERDY flag to be set indicating that HSE clock
* is stable and can be used to clock the PLL and/or system clock.
* @note HSE state can not be changed if it is used directly or through the
* PLL as system clock. In this case, you have to select another source
* of the system clock then change the HSE state (ex. disable it).
* @note The HSE is stopped by hardware when entering STOP and STANDBY modes.
* @note This function reset the CSSON bit, so if the clock security system(CSS)
* was previously enabled you have to enable it again after calling this
* function.
* @param __STATE__ specifies the new state of the HSE.
* This parameter can be one of the following values:
* @arg @ref RCC_HSE_OFF Turn OFF the HSE oscillator, HSERDY flag goes low after
* 6 HSE oscillator clock cycles.
* @arg @ref RCC_HSE_ON Turn ON the HSE oscillator.
* @arg @ref RCC_HSE_BYPASS HSE oscillator bypassed with external clock.
* @retval None
*/
#define __HAL_RCC_HSE_CONFIG(__STATE__) \
do { \
if((__STATE__) == RCC_HSE_ON) \
{ \
SET_BIT(RCC->CR, RCC_CR_HSEON); \
} \
else if((__STATE__) == RCC_HSE_BYPASS) \
{ \
SET_BIT(RCC->CR, RCC_CR_HSEBYP); \
SET_BIT(RCC->CR, RCC_CR_HSEON); \
} \
else \
{ \
CLEAR_BIT(RCC->CR, RCC_CR_HSEON); \
CLEAR_BIT(RCC->CR, RCC_CR_HSEBYP); \
} \
} while(0)
/**
* @brief Macro to configure the External Low Speed oscillator (LSE).
* @note Transitions LSE Bypass to LSE On and LSE On to LSE Bypass are not
* supported by this macro. User should request a transition to LSE Off
* first and then LSE On or LSE Bypass.
* @note As the LSE is in the Backup domain and write access is denied to
* this domain after reset, you have to enable write access using
* HAL_PWR_EnableBkUpAccess() function before to configure the LSE
* (to be done once after reset).
* @note After enabling the LSE (RCC_LSE_ON or RCC_LSE_BYPASS), the application
* software should wait on LSERDY flag to be set indicating that LSE clock
* is stable and can be used to clock the RTC.
* @param __STATE__ specifies the new state of the LSE.
* This parameter can be one of the following values:
* @arg @ref RCC_LSE_OFF Turn OFF the LSE oscillator, LSERDY flag goes low after
* 6 LSE oscillator clock cycles.
* @arg @ref RCC_LSE_ON Turn ON the LSE oscillator.
* @arg @ref RCC_LSE_BYPASS LSE oscillator bypassed with external clock.
* @retval None
*/
#define __HAL_RCC_LSE_CONFIG(__STATE__) \
do { \
if((__STATE__) == RCC_LSE_ON) \
{ \
SET_BIT(RCC->BDCR, RCC_BDCR_LSEON); \
} \
else if((__STATE__) == RCC_LSE_BYPASS) \
{ \
SET_BIT(RCC->BDCR, RCC_BDCR_LSEBYP); \
SET_BIT(RCC->BDCR, RCC_BDCR_LSEON); \
} \
else \
{ \
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEON); \
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEBYP); \
} \
} while(0)
/** @brief Macros to enable or disable the Internal High Speed 48MHz oscillator (HSI48).
* @note The HSI48 is stopped by hardware when entering STOP and STANDBY modes.
* @note After enabling the HSI48, the application software should wait on HSI48RDY
* flag to be set indicating that HSI48 clock is stable.
* This parameter can be: ENABLE or DISABLE.
* @retval None
*/
#define __HAL_RCC_HSI48_ENABLE() SET_BIT(RCC->CRRCR, RCC_CRRCR_HSI48ON)
#define __HAL_RCC_HSI48_DISABLE() CLEAR_BIT(RCC->CRRCR, RCC_CRRCR_HSI48ON)
/** @brief Macros to configure the RTC clock (RTCCLK).
* @note As the RTC clock configuration bits are in the Backup domain and write
* access is denied to this domain after reset, you have to enable write
* access using the Power Backup Access macro before to configure
* the RTC clock source (to be done once after reset).
* @note Once the RTC clock is configured it cannot be changed unless the
* Backup domain is reset using __HAL_RCC_BACKUPRESET_FORCE() macro, or by
* a Power On Reset (POR).
*
* @param __RTC_CLKSOURCE__ specifies the RTC clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_RTCCLKSOURCE_NONE No clock selected as RTC clock.
* @arg @ref RCC_RTCCLKSOURCE_LSE LSE selected as RTC clock.
* @arg @ref RCC_RTCCLKSOURCE_LSI LSI selected as RTC clock.
* @arg @ref RCC_RTCCLKSOURCE_HSE_DIV32 HSE clock divided by 32 selected
*
* @note If the LSE or LSI is used as RTC clock source, the RTC continues to
* work in STOP and STANDBY modes, and can be used as wakeup source.
* However, when the HSE clock is used as RTC clock source, the RTC
* cannot be used in STOP and STANDBY modes.
* @note The maximum input clock frequency for RTC is 1MHz (when using HSE as
* RTC clock source).
* @retval None
*/
#define __HAL_RCC_RTC_CONFIG(__RTC_CLKSOURCE__) \
MODIFY_REG( RCC->BDCR, RCC_BDCR_RTCSEL, (__RTC_CLKSOURCE__))
/** @brief Macro to get the RTC clock source.
* @retval The returned value can be one of the following:
* @arg @ref RCC_RTCCLKSOURCE_NONE No clock selected as RTC clock.
* @arg @ref RCC_RTCCLKSOURCE_LSE LSE selected as RTC clock.
* @arg @ref RCC_RTCCLKSOURCE_LSI LSI selected as RTC clock.
* @arg @ref RCC_RTCCLKSOURCE_HSE_DIV32 HSE clock divided by 32 selected
*/
#define __HAL_RCC_GET_RTC_SOURCE() (READ_BIT(RCC->BDCR, RCC_BDCR_RTCSEL))
/** @brief Macros to enable or disable the main PLL.
* @note After enabling the main PLL, the application software should wait on
* PLLRDY flag to be set indicating that PLL clock is stable and can
* be used as system clock source.
* @note The main PLL can not be disabled if it is used as system clock source
* @note The main PLL is disabled by hardware when entering STOP and STANDBY modes.
* @retval None
*/
#define __HAL_RCC_PLL_ENABLE() SET_BIT(RCC->CR, RCC_CR_PLLON)
#define __HAL_RCC_PLL_DISABLE() CLEAR_BIT(RCC->CR, RCC_CR_PLLON)
/** @brief Macro to configure the PLL clock source.
* @note This function must be used only when the main PLL is disabled.
* @param __PLLSOURCE__ specifies the PLL entry clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_PLLSOURCE_NONE No clock selected as PLL clock entry
* @arg @ref RCC_PLLSOURCE_HSI HSI oscillator clock selected as PLL clock entry
* @arg @ref RCC_PLLSOURCE_HSE HSE oscillator clock selected as PLL clock entry
* @retval None
*
*/
#define __HAL_RCC_PLL_PLLSOURCE_CONFIG(__PLLSOURCE__) \
MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC, (__PLLSOURCE__))
/** @brief Macro to configure the PLL source division factor M.
* @note This function must be used only when the main PLL is disabled.
* @param __PLLM__ specifies the division factor for PLL VCO input clock
* This parameter must be a value of @ref RCC_PLLM_Clock_Divider.
* @note You have to set the PLLM parameter correctly to ensure that the VCO input
* frequency ranges from 2.66 to 8 MHz. It is recommended to select a frequency
* of 8 MHz to limit PLL jitter.
* @retval None
*
*/
#define __HAL_RCC_PLL_PLLM_CONFIG(__PLLM__) \
MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLM, ((__PLLM__) - 1) << RCC_PLLCFGR_PLLM_Pos)
/**
* @brief Macro to configure the main PLL clock source, multiplication and division factors.
* @note This macro must be used only when the main PLL is disabled.
* @note This macro preserves the PLL's output clocks enable state.
*
* @param __PLLSOURCE__ specifies the PLL entry clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_PLLSOURCE_NONE No clock selected as PLL clock entry
* @arg @ref RCC_PLLSOURCE_HSI HSI oscillator clock selected as PLL clock entry
* @arg @ref RCC_PLLSOURCE_HSE HSE oscillator clock selected as PLL clock entry
*
* @param __PLLM__ specifies the division factor for PLL VCO input clock.
* This parameter must be a value of @ref RCC_PLLM_Clock_Divider
* @note You have to set the PLLM parameter correctly to ensure that the VCO input
* frequency ranges from 2.66 to 8 MHz. It is recommended to select a frequency
* of 8 MHz to limit PLL jitter.
*
* @param __PLLN__ specifies the multiplication factor for PLL VCO output clock.
* This parameter must be a number between 8 and 127.
* @note You have to set the PLLN parameter correctly to ensure that the VCO
* output frequency is between 64 and 344 MHz.
*
* @param __PLLP__ specifies the division factor for SAI clock.
* This parameter must be a number in the range (2 to 31).
*
* @param __PLLQ__ specifies the division factor for OTG FS, SDMMC1 and RNG clocks.
* This parameter must be in the range (2, 4, 6 or 8).
* @note If the USB OTG FS is used in your application, you have to set the
* PLLQ parameter correctly to have 48 MHz clock for the USB. However,
* the SDMMC1 and RNG need a frequency lower than or equal to 48 MHz to work
* correctly.
* @param __PLLR__ specifies the division factor for the main system clock.
* @note You have to set the PLLR parameter correctly to not exceed 170MHZ.
* This parameter must be in the range (2, 4, 6 or 8).
* @retval None
*/
#define __HAL_RCC_PLL_CONFIG(__PLLSOURCE__, __PLLM__, __PLLN__, __PLLP__, __PLLQ__,__PLLR__ ) \
MODIFY_REG(RCC->PLLCFGR, \
(RCC_PLLCFGR_PLLSRC | RCC_PLLCFGR_PLLM | RCC_PLLCFGR_PLLN | \
RCC_PLLCFGR_PLLQ | RCC_PLLCFGR_PLLR | RCC_PLLCFGR_PLLPDIV), \
((__PLLSOURCE__) | \
(((__PLLM__) - 1U) << RCC_PLLCFGR_PLLM_Pos) | \
((__PLLN__) << RCC_PLLCFGR_PLLN_Pos) | \
((((__PLLQ__) >> 1U) - 1U) << RCC_PLLCFGR_PLLQ_Pos) | \
((((__PLLR__) >> 1U) - 1U) << RCC_PLLCFGR_PLLR_Pos) | \
((__PLLP__) << RCC_PLLCFGR_PLLPDIV_Pos)))
/** @brief Macro to get the oscillator used as PLL clock source.
* @retval The oscillator used as PLL clock source. The returned value can be one
* of the following:
* - RCC_PLLSOURCE_NONE: No oscillator is used as PLL clock source.
* - RCC_PLLSOURCE_HSI: HSI oscillator is used as PLL clock source.
* - RCC_PLLSOURCE_HSE: HSE oscillator is used as PLL clock source.
*/
#define __HAL_RCC_GET_PLL_OSCSOURCE() (READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC))
/**
* @brief Enable or disable each clock output (RCC_PLL_SYSCLK, RCC_PLL_48M1CLK, RCC_PLL_ADCCLK)
* @note Enabling/disabling clock outputs RCC_PLL_ADCCLK and RCC_PLL_48M1CLK can be done at anytime
* without the need to stop the PLL in order to save power. But RCC_PLL_SYSCLK cannot
* be stopped if used as System Clock.
* @param __PLLCLOCKOUT__ specifies the PLL clock to be output.
* This parameter can be one or a combination of the following values:
* @arg @ref RCC_PLL_ADCCLK This clock is used to generate a clock on ADC.
* @arg @ref RCC_PLL_48M1CLK This Clock is used to generate the clock for the USB (48 MHz),
* FDCAN (<=48 MHz) and QSPI (<=48 MHz).
* @arg @ref RCC_PLL_SYSCLK This Clock is used to generate the high speed system clock (up to 170MHz)
* @retval None
*/
#define __HAL_RCC_PLLCLKOUT_ENABLE(__PLLCLOCKOUT__) SET_BIT(RCC->PLLCFGR, (__PLLCLOCKOUT__))
#define __HAL_RCC_PLLCLKOUT_DISABLE(__PLLCLOCKOUT__) CLEAR_BIT(RCC->PLLCFGR, (__PLLCLOCKOUT__))
/**
* @brief Get clock output enable status (RCC_PLL_SYSCLK, RCC_PLL_48M1CLK, RCC_PLL_SAI3CLK)
* @param __PLLCLOCKOUT__ specifies the output PLL clock to be checked.
* This parameter can be one of the following values:
* @arg @ref RCC_PLL_ADCCLK This clock is used to generate a clock on ADC.
* @arg @ref RCC_PLL_48M1CLK This Clock is used to generate the clock for the USB (48 MHz),
* FDCAN (<=48 MHz) and QSPI (<=48 MHz).
* @arg @ref RCC_PLL_SYSCLK This Clock is used to generate the high speed system clock (up to 170MHz)
* @retval SET / RESET
*/
#define __HAL_RCC_GET_PLLCLKOUT_CONFIG(__PLLCLOCKOUT__) READ_BIT(RCC->PLLCFGR, (__PLLCLOCKOUT__))
/**
* @brief Macro to configure the system clock source.
* @param __SYSCLKSOURCE__ specifies the system clock source.
* This parameter can be one of the following values:
* - RCC_SYSCLKSOURCE_HSI: HSI oscillator is used as system clock source.
* - RCC_SYSCLKSOURCE_HSE: HSE oscillator is used as system clock source.
* - RCC_SYSCLKSOURCE_PLLCLK: PLL output is used as system clock source.
* @retval None
*/
#define __HAL_RCC_SYSCLK_CONFIG(__SYSCLKSOURCE__) \
MODIFY_REG(RCC->CFGR, RCC_CFGR_SW, (__SYSCLKSOURCE__))
/** @brief Macro to get the clock source used as system clock.
* @retval The clock source used as system clock. The returned value can be one
* of the following:
* - RCC_SYSCLKSOURCE_STATUS_HSI: HSI used as system clock.
* - RCC_SYSCLKSOURCE_STATUS_HSE: HSE used as system clock.
* - RCC_SYSCLKSOURCE_STATUS_PLLCLK: PLL used as system clock.
*/
#define __HAL_RCC_GET_SYSCLK_SOURCE() (READ_BIT(RCC->CFGR, RCC_CFGR_SWS))
/**
* @brief Macro to configure the External Low Speed oscillator (LSE) drive capability.
* @note As the LSE is in the Backup domain and write access is denied to
* this domain after reset, you have to enable write access using
* HAL_PWR_EnableBkUpAccess() function before to configure the LSE
* (to be done once after reset).
* @param __LSEDRIVE__ specifies the new state of the LSE drive capability.
* This parameter can be one of the following values:
* @arg @ref RCC_LSEDRIVE_LOW LSE oscillator low drive capability.
* @arg @ref RCC_LSEDRIVE_MEDIUMLOW LSE oscillator medium low drive capability.
* @arg @ref RCC_LSEDRIVE_MEDIUMHIGH LSE oscillator medium high drive capability.
* @arg @ref RCC_LSEDRIVE_HIGH LSE oscillator high drive capability.
* @retval None
*/
#define __HAL_RCC_LSEDRIVE_CONFIG(__LSEDRIVE__) \
MODIFY_REG(RCC->BDCR, RCC_BDCR_LSEDRV, (__LSEDRIVE__))
/** @brief Macro to configure the MCO clock.
* @param __MCOCLKSOURCE__ specifies the MCO clock source.
* This parameter can be one of the following values:
* @arg @ref RCC_MCO1SOURCE_NOCLOCK MCO output disabled
* @arg @ref RCC_MCO1SOURCE_SYSCLK System clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSI HSI clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSE HSE clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_PLLCLK Main PLL clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_LSI LSI clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_LSE LSE clock selected as MCO source
* @arg @ref RCC_MCO1SOURCE_HSI48 HSI48 clock selected as MCO source for devices with HSI48
* @param __MCODIV__ specifies the MCO clock prescaler.
* This parameter can be one of the following values:
* @arg @ref RCC_MCODIV_1 MCO clock source is divided by 1
* @arg @ref RCC_MCODIV_2 MCO clock source is divided by 2
* @arg @ref RCC_MCODIV_4 MCO clock source is divided by 4
* @arg @ref RCC_MCODIV_8 MCO clock source is divided by 8
* @arg @ref RCC_MCODIV_16 MCO clock source is divided by 16
*/
#define __HAL_RCC_MCO1_CONFIG(__MCOCLKSOURCE__, __MCODIV__) \
MODIFY_REG(RCC->CFGR, (RCC_CFGR_MCOSEL | RCC_CFGR_MCOPRE), ((__MCOCLKSOURCE__) | (__MCODIV__)))
/** @defgroup RCC_Flags_Interrupts_Management Flags Interrupts Management
* @brief macros to manage the specified RCC Flags and interrupts.
* @{
*/
/** @brief Enable RCC interrupt (Perform Byte access to RCC_CIR[14:8] bits to enable
* the selected interrupts).
* @param __INTERRUPT__ specifies the RCC interrupt sources to be enabled.
* This parameter can be any combination of the following values:
* @arg @ref RCC_IT_LSIRDY LSI ready interrupt
* @arg @ref RCC_IT_LSERDY LSE ready interrupt
* @arg @ref RCC_IT_HSIRDY HSI ready interrupt
* @arg @ref RCC_IT_HSERDY HSE ready interrupt
* @arg @ref RCC_IT_PLLRDY Main PLL ready interrupt
* @arg @ref RCC_IT_LSECSS LSE Clock security system interrupt
* @arg @ref RCC_IT_HSI48RDY HSI48 ready interrupt for devices with HSI48
* @retval None
*/
#define __HAL_RCC_ENABLE_IT(__INTERRUPT__) SET_BIT(RCC->CIER, (__INTERRUPT__))
/** @brief Disable RCC interrupt (Perform Byte access to RCC_CIR[14:8] bits to disable
* the selected interrupts).
* @param __INTERRUPT__ specifies the RCC interrupt sources to be disabled.
* This parameter can be any combination of the following values:
* @arg @ref RCC_IT_LSIRDY LSI ready interrupt
* @arg @ref RCC_IT_LSERDY LSE ready interrupt
* @arg @ref RCC_IT_HSIRDY HSI ready interrupt
* @arg @ref RCC_IT_HSERDY HSE ready interrupt
* @arg @ref RCC_IT_PLLRDY Main PLL ready interrupt
* @arg @ref RCC_IT_LSECSS LSE Clock security system interrupt
* @arg @ref RCC_IT_HSI48RDY HSI48 ready interrupt for devices with HSI48
* @retval None
*/
#define __HAL_RCC_DISABLE_IT(__INTERRUPT__) CLEAR_BIT(RCC->CIER, (__INTERRUPT__))
/** @brief Clear the RCC's interrupt pending bits (Perform Byte access to RCC_CIR[23:16]
* bits to clear the selected interrupt pending bits.
* @param __INTERRUPT__ specifies the interrupt pending bit to clear.
* This parameter can be any combination of the following values:
* @arg @ref RCC_IT_LSIRDY LSI ready interrupt
* @arg @ref RCC_IT_LSERDY LSE ready interrupt
* @arg @ref RCC_IT_HSIRDY HSI ready interrupt
* @arg @ref RCC_IT_HSERDY HSE ready interrupt
* @arg @ref RCC_IT_PLLRDY Main PLL ready interrupt
* @arg @ref RCC_IT_CSS HSE Clock security system interrupt
* @arg @ref RCC_IT_LSECSS LSE Clock security system interrupt
* @arg @ref RCC_IT_HSI48RDY HSI48 ready interrupt for devices with HSI48
* @retval None
*/
#define __HAL_RCC_CLEAR_IT(__INTERRUPT__) (RCC->CICR = (__INTERRUPT__))
/** @brief Check whether the RCC interrupt has occurred or not.
* @param __INTERRUPT__ specifies the RCC interrupt source to check.
* This parameter can be one of the following values:
* @arg @ref RCC_IT_LSIRDY LSI ready interrupt
* @arg @ref RCC_IT_LSERDY LSE ready interrupt
* @arg @ref RCC_IT_HSIRDY HSI ready interrupt
* @arg @ref RCC_IT_HSERDY HSE ready interrupt
* @arg @ref RCC_IT_PLLRDY Main PLL ready interrupt
* @arg @ref RCC_IT_CSS HSE Clock security system interrupt
* @arg @ref RCC_IT_LSECSS LSE Clock security system interrupt
* @arg @ref RCC_IT_HSI48RDY HSI48 ready interrupt for devices with HSI48
* @retval The new state of __INTERRUPT__ (TRUE or FALSE).
*/
#define __HAL_RCC_GET_IT(__INTERRUPT__) ((RCC->CIFR & (__INTERRUPT__)) == (__INTERRUPT__))
/** @brief Set RMVF bit to clear the reset flags.
* The reset flags are: RCC_FLAG_FWRRST, RCC_FLAG_OBLRST, RCC_FLAG_PINRST, RCC_FLAG_BORRST,
* RCC_FLAG_SFTRST, RCC_FLAG_IWDGRST, RCC_FLAG_WWDGRST and RCC_FLAG_LPWRRST.
* @retval None
*/
#define __HAL_RCC_CLEAR_RESET_FLAGS() (RCC->CSR |= RCC_CSR_RMVF)
/** @brief Check whether the selected RCC flag is set or not.
* @param __FLAG__ specifies the flag to check.
* This parameter can be one of the following values:
* @arg @ref RCC_FLAG_HSIRDY HSI oscillator clock ready
* @arg @ref RCC_FLAG_HSERDY HSE oscillator clock ready
* @arg @ref RCC_FLAG_PLLRDY Main PLL clock ready
* @arg @ref RCC_FLAG_HSI48RDY HSI48 clock ready for devices with HSI48
* @arg @ref RCC_FLAG_LSERDY LSE oscillator clock ready
* @arg @ref RCC_FLAG_LSECSSD Clock security system failure on LSE oscillator detection
* @arg @ref RCC_FLAG_LSIRDY LSI oscillator clock ready
* @arg @ref RCC_FLAG_BORRST BOR reset
* @arg @ref RCC_FLAG_OBLRST OBLRST reset
* @arg @ref RCC_FLAG_PINRST Pin reset
* @arg @ref RCC_FLAG_SFTRST Software reset
* @arg @ref RCC_FLAG_IWDGRST Independent Watchdog reset
* @arg @ref RCC_FLAG_WWDGRST Window Watchdog reset
* @arg @ref RCC_FLAG_LPWRRST Low Power reset
* @retval The new state of __FLAG__ (TRUE or FALSE).
*/
#define __HAL_RCC_GET_FLAG(__FLAG__) (((((((__FLAG__) >> 5U) == 1U) ? RCC->CR : \
((((__FLAG__) >> 5U) == 4U) ? RCC->CRRCR : \
((((__FLAG__) >> 5U) == 2U) ? RCC->BDCR : \
((((__FLAG__) >> 5U) == 3U) ? RCC->CSR : RCC->CIFR)))) & \
((uint32_t)1U << ((__FLAG__) & RCC_FLAG_MASK))) != 0U) \
? 1U : 0U)
/**
* @}
*/
/**
* @}
*/
/* Private constants ---------------------------------------------------------*/
/** @addtogroup RCC_Private_Constants
* @{
*/
/* Defines used for Flags */
#define CR_REG_INDEX 1U
#define BDCR_REG_INDEX 2U
#define CSR_REG_INDEX 3U
#define CRRCR_REG_INDEX 4U
#define RCC_FLAG_MASK 0x1FU
/* Define used for IS_RCC_CLOCKTYPE() */
#define RCC_CLOCKTYPE_ALL (RCC_CLOCKTYPE_SYSCLK | RCC_CLOCKTYPE_HCLK | RCC_CLOCKTYPE_PCLK1 | RCC_CLOCKTYPE_PCLK2) /*!< All clcoktype to configure */
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @addtogroup RCC_Private_Macros
* @{
*/
#define IS_RCC_OSCILLATORTYPE(__OSCILLATOR__) (((__OSCILLATOR__) == RCC_OSCILLATORTYPE_NONE) || \
(((__OSCILLATOR__) & RCC_OSCILLATORTYPE_HSE) == RCC_OSCILLATORTYPE_HSE) || \
(((__OSCILLATOR__) & RCC_OSCILLATORTYPE_HSI) == RCC_OSCILLATORTYPE_HSI) || \
(((__OSCILLATOR__) & RCC_OSCILLATORTYPE_HSI48) == RCC_OSCILLATORTYPE_HSI48) || \
(((__OSCILLATOR__) & RCC_OSCILLATORTYPE_LSI) == RCC_OSCILLATORTYPE_LSI) || \
(((__OSCILLATOR__) & RCC_OSCILLATORTYPE_LSE) == RCC_OSCILLATORTYPE_LSE))
#define IS_RCC_HSE(__HSE__) (((__HSE__) == RCC_HSE_OFF) || ((__HSE__) == RCC_HSE_ON) || \
((__HSE__) == RCC_HSE_BYPASS))
#define IS_RCC_LSE(__LSE__) (((__LSE__) == RCC_LSE_OFF) || ((__LSE__) == RCC_LSE_ON) || \
((__LSE__) == RCC_LSE_BYPASS))
#define IS_RCC_HSI(__HSI__) (((__HSI__) == RCC_HSI_OFF) || ((__HSI__) == RCC_HSI_ON))
#define IS_RCC_HSI_CALIBRATION_VALUE(__VALUE__) ((__VALUE__) <= (RCC_ICSCR_HSITRIM >> RCC_ICSCR_HSITRIM_Pos))
#define IS_RCC_LSI(__LSI__) (((__LSI__) == RCC_LSI_OFF) || ((__LSI__) == RCC_LSI_ON))
#define IS_RCC_HSI48(__HSI48__) (((__HSI48__) == RCC_HSI48_OFF) || ((__HSI48__) == RCC_HSI48_ON))
#define IS_RCC_PLL(__PLL__) (((__PLL__) == RCC_PLL_NONE) ||((__PLL__) == RCC_PLL_OFF) || \
((__PLL__) == RCC_PLL_ON))
#define IS_RCC_PLLSOURCE(__SOURCE__) (((__SOURCE__) == RCC_PLLSOURCE_NONE) || \
((__SOURCE__) == RCC_PLLSOURCE_HSI) || \
((__SOURCE__) == RCC_PLLSOURCE_HSE))
#define IS_RCC_PLLM_VALUE(__VALUE__) ((1U <= (__VALUE__)) && ((__VALUE__) <= 16U))
#define IS_RCC_PLLN_VALUE(__VALUE__) ((8U <= (__VALUE__)) && ((__VALUE__) <= 127U))
#define IS_RCC_PLLP_VALUE(__VALUE__) (((__VALUE__) >= 2U) && ((__VALUE__) <= 31U))
#define IS_RCC_PLLQ_VALUE(__VALUE__) (((__VALUE__) == 2U) || ((__VALUE__) == 4U) || \
((__VALUE__) == 6U) || ((__VALUE__) == 8U))
#define IS_RCC_PLLR_VALUE(__VALUE__) (((__VALUE__) == 2U) || ((__VALUE__) == 4U) || \
((__VALUE__) == 6U) || ((__VALUE__) == 8U))
#define IS_RCC_CLOCKTYPE(__CLK__) ((((__CLK__) & RCC_CLOCKTYPE_ALL) != 0x00UL) && (((__CLK__) & ~RCC_CLOCKTYPE_ALL) == 0x00UL))
#define IS_RCC_SYSCLKSOURCE(__SOURCE__) (((__SOURCE__) == RCC_SYSCLKSOURCE_HSI) || \
((__SOURCE__) == RCC_SYSCLKSOURCE_HSE) || \
((__SOURCE__) == RCC_SYSCLKSOURCE_PLLCLK))
#define IS_RCC_HCLK(__HCLK__) (((__HCLK__) == RCC_SYSCLK_DIV1) || ((__HCLK__) == RCC_SYSCLK_DIV2) || \
((__HCLK__) == RCC_SYSCLK_DIV4) || ((__HCLK__) == RCC_SYSCLK_DIV8) || \
((__HCLK__) == RCC_SYSCLK_DIV16) || ((__HCLK__) == RCC_SYSCLK_DIV64) || \
((__HCLK__) == RCC_SYSCLK_DIV128) || ((__HCLK__) == RCC_SYSCLK_DIV256) || \
((__HCLK__) == RCC_SYSCLK_DIV512))
#define IS_RCC_PCLK(__PCLK__) (((__PCLK__) == RCC_HCLK_DIV1) || ((__PCLK__) == RCC_HCLK_DIV2) || \
((__PCLK__) == RCC_HCLK_DIV4) || ((__PCLK__) == RCC_HCLK_DIV8) || \
((__PCLK__) == RCC_HCLK_DIV16))
#define IS_RCC_RTCCLKSOURCE(__SOURCE__) (((__SOURCE__) == RCC_RTCCLKSOURCE_NONE) || \
((__SOURCE__) == RCC_RTCCLKSOURCE_LSE) || \
((__SOURCE__) == RCC_RTCCLKSOURCE_LSI) || \
((__SOURCE__) == RCC_RTCCLKSOURCE_HSE_DIV32))
#define IS_RCC_MCO(__MCOX__) (((__MCOX__) == RCC_MCO_PA8) || \
((__MCOX__) == RCC_MCO_PG10))
#define IS_RCC_MCO1SOURCE(__SOURCE__) (((__SOURCE__) == RCC_MCO1SOURCE_NOCLOCK) || \
((__SOURCE__) == RCC_MCO1SOURCE_SYSCLK) || \
((__SOURCE__) == RCC_MCO1SOURCE_HSI) || \
((__SOURCE__) == RCC_MCO1SOURCE_HSE) || \
((__SOURCE__) == RCC_MCO1SOURCE_PLLCLK) || \
((__SOURCE__) == RCC_MCO1SOURCE_LSI) || \
((__SOURCE__) == RCC_MCO1SOURCE_LSE) || \
((__SOURCE__) == RCC_MCO1SOURCE_HSI48))
#define IS_RCC_MCODIV(__DIV__) (((__DIV__) == RCC_MCODIV_1) || ((__DIV__) == RCC_MCODIV_2) || \
((__DIV__) == RCC_MCODIV_4) || ((__DIV__) == RCC_MCODIV_8) || \
((__DIV__) == RCC_MCODIV_16))
#define IS_RCC_LSE_DRIVE(__DRIVE__) (((__DRIVE__) == RCC_LSEDRIVE_LOW) || \
((__DRIVE__) == RCC_LSEDRIVE_MEDIUMLOW) || \
((__DRIVE__) == RCC_LSEDRIVE_MEDIUMHIGH) || \
((__DRIVE__) == RCC_LSEDRIVE_HIGH))
/**
* @}
*/
/* Include RCC HAL Extended module */
#include "stm32g4xx_hal_rcc_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @addtogroup RCC_Exported_Functions
* @{
*/
/** @addtogroup RCC_Exported_Functions_Group1
* @{
*/
/* Initialization and de-initialization functions ******************************/
HAL_StatusTypeDef HAL_RCC_DeInit(void);
HAL_StatusTypeDef HAL_RCC_OscConfig(RCC_OscInitTypeDef *RCC_OscInitStruct);
HAL_StatusTypeDef HAL_RCC_ClockConfig(RCC_ClkInitTypeDef *RCC_ClkInitStruct, uint32_t FLatency);
/**
* @}
*/
/** @addtogroup RCC_Exported_Functions_Group2
* @{
*/
/* Peripheral Control functions ************************************************/
void HAL_RCC_MCOConfig(uint32_t RCC_MCOx, uint32_t RCC_MCOSource, uint32_t RCC_MCODiv);
void HAL_RCC_EnableCSS(void);
void HAL_RCC_EnableLSECSS(void);
void HAL_RCC_DisableLSECSS(void);
uint32_t HAL_RCC_GetSysClockFreq(void);
uint32_t HAL_RCC_GetHCLKFreq(void);
uint32_t HAL_RCC_GetPCLK1Freq(void);
uint32_t HAL_RCC_GetPCLK2Freq(void);
void HAL_RCC_GetOscConfig(RCC_OscInitTypeDef *RCC_OscInitStruct);
void HAL_RCC_GetClockConfig(RCC_ClkInitTypeDef *RCC_ClkInitStruct, uint32_t *pFLatency);
/* CSS NMI IRQ handler */
void HAL_RCC_NMI_IRQHandler(void);
/* User Callbacks in non blocking mode (IT mode) */
void HAL_RCC_CSSCallback(void);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_RCC_H */
| 166,550 | C | 47.884943 | 162 | 0.555947 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_exti.h | /**
******************************************************************************
* @file stm32g4xx_ll_exti.h
* @author MCD Application Team
* @brief Header file of EXTI LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_LL_EXTI_H
#define __STM32G4xx_LL_EXTI_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined (EXTI)
/** @defgroup EXTI_LL EXTI
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private Macros ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup EXTI_LL_Private_Macros EXTI Private Macros
* @{
*/
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported types ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup EXTI_LL_ES_INIT EXTI Exported Init structure
* @{
*/
typedef struct
{
uint32_t Line_0_31; /*!< Specifies the EXTI lines to be enabled or disabled for Lines in range 0 to 31
This parameter can be any combination of @ref EXTI_LL_EC_LINE */
uint32_t Line_32_63; /*!< Specifies the EXTI lines to be enabled or disabled for Lines in range 32 to 63
This parameter can be any combination of @ref EXTI_LL_EC_LINE */
FunctionalState LineCommand; /*!< Specifies the new state of the selected EXTI lines.
This parameter can be set either to ENABLE or DISABLE */
uint8_t Mode; /*!< Specifies the mode for the EXTI lines.
This parameter can be a value of @ref EXTI_LL_EC_MODE. */
uint8_t Trigger; /*!< Specifies the trigger signal active edge for the EXTI lines.
This parameter can be a value of @ref EXTI_LL_EC_TRIGGER. */
} LL_EXTI_InitTypeDef;
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup EXTI_LL_Exported_Constants EXTI Exported Constants
* @{
*/
/** @defgroup EXTI_LL_EC_LINE LINE
* @{
*/
#define LL_EXTI_LINE_0 EXTI_IMR1_IM0 /*!< Extended line 0 */
#define LL_EXTI_LINE_1 EXTI_IMR1_IM1 /*!< Extended line 1 */
#define LL_EXTI_LINE_2 EXTI_IMR1_IM2 /*!< Extended line 2 */
#define LL_EXTI_LINE_3 EXTI_IMR1_IM3 /*!< Extended line 3 */
#define LL_EXTI_LINE_4 EXTI_IMR1_IM4 /*!< Extended line 4 */
#define LL_EXTI_LINE_5 EXTI_IMR1_IM5 /*!< Extended line 5 */
#define LL_EXTI_LINE_6 EXTI_IMR1_IM6 /*!< Extended line 6 */
#define LL_EXTI_LINE_7 EXTI_IMR1_IM7 /*!< Extended line 7 */
#define LL_EXTI_LINE_8 EXTI_IMR1_IM8 /*!< Extended line 8 */
#define LL_EXTI_LINE_9 EXTI_IMR1_IM9 /*!< Extended line 9 */
#define LL_EXTI_LINE_10 EXTI_IMR1_IM10 /*!< Extended line 10 */
#define LL_EXTI_LINE_11 EXTI_IMR1_IM11 /*!< Extended line 11 */
#define LL_EXTI_LINE_12 EXTI_IMR1_IM12 /*!< Extended line 12 */
#define LL_EXTI_LINE_13 EXTI_IMR1_IM13 /*!< Extended line 13 */
#define LL_EXTI_LINE_14 EXTI_IMR1_IM14 /*!< Extended line 14 */
#define LL_EXTI_LINE_15 EXTI_IMR1_IM15 /*!< Extended line 15 */
#if defined(EXTI_IMR1_IM16)
#define LL_EXTI_LINE_16 EXTI_IMR1_IM16 /*!< Extended line 16 */
#endif /* EXTI_IMR1_IM16 */
#define LL_EXTI_LINE_17 EXTI_IMR1_IM17 /*!< Extended line 17 */
#if defined(EXTI_IMR1_IM18)
#define LL_EXTI_LINE_18 EXTI_IMR1_IM18 /*!< Extended line 18 */
#endif /* EXTI_IMR1_IM18 */
#define LL_EXTI_LINE_19 EXTI_IMR1_IM19 /*!< Extended line 19 */
#if defined(EXTI_IMR1_IM20)
#define LL_EXTI_LINE_20 EXTI_IMR1_IM20 /*!< Extended line 20 */
#endif /* EXTI_IMR1_IM20 */
#if defined(EXTI_IMR1_IM21)
#define LL_EXTI_LINE_21 EXTI_IMR1_IM21 /*!< Extended line 21 */
#endif /* EXTI_IMR1_IM21 */
#if defined(EXTI_IMR1_IM22)
#define LL_EXTI_LINE_22 EXTI_IMR1_IM22 /*!< Extended line 22 */
#endif /* EXTI_IMR1_IM22 */
#define LL_EXTI_LINE_23 EXTI_IMR1_IM23 /*!< Extended line 23 */
#if defined(EXTI_IMR1_IM24)
#define LL_EXTI_LINE_24 EXTI_IMR1_IM24 /*!< Extended line 24 */
#endif /* EXTI_IMR1_IM24 */
#if defined(EXTI_IMR1_IM25)
#define LL_EXTI_LINE_25 EXTI_IMR1_IM25 /*!< Extended line 25 */
#endif /* EXTI_IMR1_IM25 */
#if defined(EXTI_IMR1_IM26)
#define LL_EXTI_LINE_26 EXTI_IMR1_IM26 /*!< Extended line 26 */
#endif /* EXTI_IMR1_IM26 */
#if defined(EXTI_IMR1_IM27)
#define LL_EXTI_LINE_27 EXTI_IMR1_IM27 /*!< Extended line 27 */
#endif /* EXTI_IMR1_IM27 */
#if defined(EXTI_IMR1_IM28)
#define LL_EXTI_LINE_28 EXTI_IMR1_IM28 /*!< Extended line 28 */
#endif /* EXTI_IMR1_IM28 */
#if defined(EXTI_IMR1_IM29)
#define LL_EXTI_LINE_29 EXTI_IMR1_IM29 /*!< Extended line 29 */
#endif /* EXTI_IMR1_IM29 */
#if defined(EXTI_IMR1_IM30)
#define LL_EXTI_LINE_30 EXTI_IMR1_IM30 /*!< Extended line 30 */
#endif /* EXTI_IMR1_IM30 */
#if defined(EXTI_IMR1_IM31)
#define LL_EXTI_LINE_31 EXTI_IMR1_IM31 /*!< Extended line 31 */
#endif /* EXTI_IMR1_IM31 */
#define LL_EXTI_LINE_ALL_0_31 EXTI_IMR1_IM /*!< All Extended line not reserved*/
#if defined(EXTI_IMR2_IM32)
#define LL_EXTI_LINE_32 EXTI_IMR2_IM32 /*!< Extended line 32 */
#endif /* EXTI_IMR2_IM32 */
#if defined(EXTI_IMR2_IM33)
#define LL_EXTI_LINE_33 EXTI_IMR2_IM33 /*!< Extended line 33 */
#endif /* EXTI_IMR2_IM33 */
#if defined(EXTI_IMR2_IM34)
#define LL_EXTI_LINE_34 EXTI_IMR2_IM34 /*!< Extended line 34 */
#endif /* EXTI_IMR2_IM34 */
#if defined(EXTI_IMR2_IM35)
#define LL_EXTI_LINE_35 EXTI_IMR2_IM35 /*!< Extended line 35 */
#endif /* EXTI_IMR2_IM35 */
#if defined(EXTI_IMR2_IM36)
#define LL_EXTI_LINE_36 EXTI_IMR2_IM36 /*!< Extended line 36 */
#endif /* EXTI_IMR2_IM36 */
#if defined(EXTI_IMR2_IM37)
#define LL_EXTI_LINE_37 EXTI_IMR2_IM37 /*!< Extended line 37 */
#endif /* EXTI_IMR2_IM37 */
#if defined(EXTI_IMR2_IM38)
#define LL_EXTI_LINE_38 EXTI_IMR2_IM38 /*!< Extended line 38 */
#endif /* EXTI_IMR2_IM38 */
#if defined(EXTI_IMR2_IM39)
#define LL_EXTI_LINE_39 EXTI_IMR2_IM39 /*!< Extended line 39 */
#endif /* EXTI_IMR2_IM39 */
#if defined(EXTI_IMR2_IM40)
#define LL_EXTI_LINE_40 EXTI_IMR2_IM40 /*!< Extended line 40 */
#endif /* EXTI_IMR2_IM40 */
#if defined(EXTI_IMR2_IM41)
#define LL_EXTI_LINE_41 EXTI_IMR2_IM41 /*!< Extended line 41 */
#endif /* EXTI_IMR2_IM41 */
#if defined(EXTI_IMR2_IM42)
#define LL_EXTI_LINE_42 EXTI_IMR2_IM42 /*!< Extended line 42 */
#endif /* EXTI_IMR2_IM42 */
#define LL_EXTI_LINE_ALL_32_63 EXTI_IMR2_IM /*!< All Extended line not reserved*/
#define LL_EXTI_LINE_ALL (0xFFFFFFFFU) /*!< All Extended line */
#if defined(USE_FULL_LL_DRIVER)
#define LL_EXTI_LINE_NONE 0x00000000U /*!< None Extended line */
#endif /*USE_FULL_LL_DRIVER*/
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup EXTI_LL_EC_MODE Mode
* @{
*/
#define LL_EXTI_MODE_IT ((uint8_t)0x00U) /*!< Interrupt Mode */
#define LL_EXTI_MODE_EVENT ((uint8_t)0x01U) /*!< Event Mode */
#define LL_EXTI_MODE_IT_EVENT ((uint8_t)0x02U) /*!< Interrupt & Event Mode */
/**
* @}
*/
/** @defgroup EXTI_LL_EC_TRIGGER Edge Trigger
* @{
*/
#define LL_EXTI_TRIGGER_NONE ((uint8_t)0x00U) /*!< No Trigger Mode */
#define LL_EXTI_TRIGGER_RISING ((uint8_t)0x01U) /*!< Trigger Rising Mode */
#define LL_EXTI_TRIGGER_FALLING ((uint8_t)0x02U) /*!< Trigger Falling Mode */
#define LL_EXTI_TRIGGER_RISING_FALLING ((uint8_t)0x03U) /*!< Trigger Rising & Falling Mode */
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup EXTI_LL_Exported_Macros EXTI Exported Macros
* @{
*/
/** @defgroup EXTI_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in EXTI register
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_EXTI_WriteReg(__REG__, __VALUE__) WRITE_REG(EXTI->__REG__, (__VALUE__))
/**
* @brief Read a value in EXTI register
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_EXTI_ReadReg(__REG__) READ_REG(EXTI->__REG__)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup EXTI_LL_Exported_Functions EXTI Exported Functions
* @{
*/
/** @defgroup EXTI_LL_EF_IT_Management IT_Management
* @{
*/
/**
* @brief Enable ExtiLine Interrupt request for Lines in range 0 to 31
* @note The reset value for the direct or internal lines (see RM)
* is set to 1 in order to enable the interrupt by default.
* Bits are set automatically at Power on.
* @rmtoll IMR1 IMx LL_EXTI_EnableIT_0_31
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_17
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_23
* @arg @ref LL_EXTI_LINE_24
* @arg @ref LL_EXTI_LINE_25
* @arg @ref LL_EXTI_LINE_26
* @arg @ref LL_EXTI_LINE_27
* @arg @ref LL_EXTI_LINE_28
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @arg @ref LL_EXTI_LINE_ALL_0_31
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableIT_0_31(uint32_t ExtiLine)
{
SET_BIT(EXTI->IMR1, ExtiLine);
}
/**
* @brief Enable ExtiLine Interrupt request for Lines in range 32 to 63
* @note The reset value for the direct lines (lines from 32 to 34, line
* 39) is set to 1 in order to enable the interrupt by default.
* Bits are set automatically at Power on.
* @rmtoll IMR2 IMx LL_EXTI_EnableIT_32_63
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_34
* @arg @ref LL_EXTI_LINE_35 (*)
* @arg @ref LL_EXTI_LINE_36
* @arg @ref LL_EXTI_LINE_37
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @arg @ref LL_EXTI_LINE_42(*)
* @arg @ref LL_EXTI_LINE_ALL_32_63
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableIT_32_63(uint32_t ExtiLine)
{
SET_BIT(EXTI->IMR2, ExtiLine);
}
/**
* @brief Disable ExtiLine Interrupt request for Lines in range 0 to 31
* @note The reset value for the direct or internal lines (see RM)
* is set to 1 in order to enable the interrupt by default.
* Bits are set automatically at Power on.
* @rmtoll IMR1 IMx LL_EXTI_DisableIT_0_31
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_17
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_23
* @arg @ref LL_EXTI_LINE_24
* @arg @ref LL_EXTI_LINE_25
* @arg @ref LL_EXTI_LINE_26
* @arg @ref LL_EXTI_LINE_27
* @arg @ref LL_EXTI_LINE_28
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31
* @arg @ref LL_EXTI_LINE_ALL_0_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableIT_0_31(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->IMR1, ExtiLine);
}
/**
* @brief Disable ExtiLine Interrupt request for Lines in range 32 to 63
* @note The reset value for the direct lines (lines from 32 to 34, line
* 39) is set to 1 in order to enable the interrupt by default.
* Bits are set automatically at Power on.
* @rmtoll IMR2 IMx LL_EXTI_DisableIT_32_63
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_34
* @arg @ref LL_EXTI_LINE_35 (*)
* @arg @ref LL_EXTI_LINE_36
* @arg @ref LL_EXTI_LINE_37
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @arg @ref LL_EXTI_LINE_42(*)
* @arg @ref LL_EXTI_LINE_ALL_32_63
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableIT_32_63(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->IMR2, ExtiLine);
}
/**
* @brief Indicate if ExtiLine Interrupt request is enabled for Lines in range 0 to 31
* @note The reset value for the direct or internal lines (see RM)
* is set to 1 in order to enable the interrupt by default.
* Bits are set automatically at Power on.
* @rmtoll IMR1 IMx LL_EXTI_IsEnabledIT_0_31
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_17
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_23
* @arg @ref LL_EXTI_LINE_24
* @arg @ref LL_EXTI_LINE_25
* @arg @ref LL_EXTI_LINE_26
* @arg @ref LL_EXTI_LINE_27
* @arg @ref LL_EXTI_LINE_28
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @arg @ref LL_EXTI_LINE_ALL_0_31
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledIT_0_31(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->IMR1, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @brief Indicate if ExtiLine Interrupt request is enabled for Lines in range 32 to 63
* @note The reset value for the direct lines (lines from 32 to 34, line
* 39) is set to 1 in order to enable the interrupt by default.
* Bits are set automatically at Power on.
* @rmtoll IMR2 IMx LL_EXTI_IsEnabledIT_32_63
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_34
* @arg @ref LL_EXTI_LINE_35 (*)
* @arg @ref LL_EXTI_LINE_36
* @arg @ref LL_EXTI_LINE_37
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @arg @ref LL_EXTI_LINE_42(*)
* @arg @ref LL_EXTI_LINE_ALL_32_63
* @note (*): Available in some devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledIT_32_63(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->IMR2, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup EXTI_LL_EF_Event_Management Event_Management
* @{
*/
/**
* @brief Enable ExtiLine Event request for Lines in range 0 to 31
* @rmtoll EMR1 EMx LL_EXTI_EnableEvent_0_31
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_17
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_23
* @arg @ref LL_EXTI_LINE_24
* @arg @ref LL_EXTI_LINE_25
* @arg @ref LL_EXTI_LINE_26
* @arg @ref LL_EXTI_LINE_27
* @arg @ref LL_EXTI_LINE_28
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31
* @arg @ref LL_EXTI_LINE_ALL_0_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableEvent_0_31(uint32_t ExtiLine)
{
SET_BIT(EXTI->EMR1, ExtiLine);
}
/**
* @brief Enable ExtiLine Event request for Lines in range 32 to 63
* @rmtoll EMR2 EMx LL_EXTI_EnableEvent_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_34
* @arg @ref LL_EXTI_LINE_35 (*)
* @arg @ref LL_EXTI_LINE_36
* @arg @ref LL_EXTI_LINE_37
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @arg @ref LL_EXTI_LINE_42(*)
* @arg @ref LL_EXTI_LINE_ALL_32_63
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableEvent_32_63(uint32_t ExtiLine)
{
SET_BIT(EXTI->EMR2, ExtiLine);
}
/**
* @brief Disable ExtiLine Event request for Lines in range 0 to 31
* @rmtoll EMR1 EMx LL_EXTI_DisableEvent_0_31
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_17
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_23
* @arg @ref LL_EXTI_LINE_24
* @arg @ref LL_EXTI_LINE_25
* @arg @ref LL_EXTI_LINE_26
* @arg @ref LL_EXTI_LINE_27
* @arg @ref LL_EXTI_LINE_28
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @arg @ref LL_EXTI_LINE_ALL_0_31
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableEvent_0_31(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->EMR1, ExtiLine);
}
/**
* @brief Disable ExtiLine Event request for Lines in range 32 to 63
* @rmtoll EMR2 EMx LL_EXTI_DisableEvent_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_34
* @arg @ref LL_EXTI_LINE_35 (*)
* @arg @ref LL_EXTI_LINE_36
* @arg @ref LL_EXTI_LINE_37
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @arg @ref LL_EXTI_LINE_42(*)
* @arg @ref LL_EXTI_LINE_ALL_32_63
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableEvent_32_63(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->EMR2, ExtiLine);
}
/**
* @brief Indicate if ExtiLine Event request is enabled for Lines in range 0 to 31
* @rmtoll EMR1 EMx LL_EXTI_IsEnabledEvent_0_31
* @param ExtiLine This parameter can be one of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_17
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_23
* @arg @ref LL_EXTI_LINE_24
* @arg @ref LL_EXTI_LINE_25
* @arg @ref LL_EXTI_LINE_26
* @arg @ref LL_EXTI_LINE_27
* @arg @ref LL_EXTI_LINE_28
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31
* @arg @ref LL_EXTI_LINE_ALL_0_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledEvent_0_31(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->EMR1, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @brief Indicate if ExtiLine Event request is enabled for Lines in range 32 to 63
* @rmtoll EMR2 EMx LL_EXTI_IsEnabledEvent_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_34
* @arg @ref LL_EXTI_LINE_35 (*)
* @arg @ref LL_EXTI_LINE_36
* @arg @ref LL_EXTI_LINE_37
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @arg @ref LL_EXTI_LINE_42(*)
* @arg @ref LL_EXTI_LINE_ALL_32_63
* @note (*): Available in some devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledEvent_32_63(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->EMR2, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup EXTI_LL_EF_Rising_Trigger_Management Rising_Trigger_Management
* @{
*/
/**
* @brief Enable ExtiLine Rising Edge Trigger for Lines in range 0 to 31
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a rising edge on a configurable interrupt
* line occurs during a write operation in the EXTI_RTSR register, the
* pending bit is not set.
* Rising and falling edge triggers can be set for
* the same interrupt line. In this case, both generate a trigger
* condition.
* @rmtoll RTSR1 RTx LL_EXTI_EnableRisingTrig_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableRisingTrig_0_31(uint32_t ExtiLine)
{
SET_BIT(EXTI->RTSR1, ExtiLine);
}
/**
* @brief Enable ExtiLine Rising Edge Trigger for Lines in range 32 to 63
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a rising edge on a configurable interrupt
* line occurs during a write operation in the EXTI_RTSR register, the
* pending bit is not set.Rising and falling edge triggers can be set for
* the same interrupt line. In this case, both generate a trigger
* condition.
* @rmtoll RTSR2 RTx LL_EXTI_EnableRisingTrig_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableRisingTrig_32_63(uint32_t ExtiLine)
{
SET_BIT(EXTI->RTSR2, ExtiLine);
}
/**
* @brief Disable ExtiLine Rising Edge Trigger for Lines in range 0 to 31
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a rising edge on a configurable interrupt
* line occurs during a write operation in the EXTI_RTSR register, the
* pending bit is not set.
* Rising and falling edge triggers can be set for
* the same interrupt line. In this case, both generate a trigger
* condition.
* @rmtoll RTSR1 RTx LL_EXTI_DisableRisingTrig_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableRisingTrig_0_31(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->RTSR1, ExtiLine);
}
/**
* @brief Disable ExtiLine Rising Edge Trigger for Lines in range 32 to 63
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a rising edge on a configurable interrupt
* line occurs during a write operation in the EXTI_RTSR register, the
* pending bit is not set.
* Rising and falling edge triggers can be set for
* the same interrupt line. In this case, both generate a trigger
* condition.
* @rmtoll RTSR2 RTx LL_EXTI_DisableRisingTrig_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableRisingTrig_32_63(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->RTSR2, ExtiLine);
}
/**
* @brief Check if rising edge trigger is enabled for Lines in range 0 to 31
* @rmtoll RTSR1 RTx LL_EXTI_IsEnabledRisingTrig_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledRisingTrig_0_31(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->RTSR1, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @brief Check if rising edge trigger is enabled for Lines in range 32 to 63
* @rmtoll RTSR2 RTx LL_EXTI_IsEnabledRisingTrig_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledRisingTrig_32_63(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->RTSR2, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup EXTI_LL_EF_Falling_Trigger_Management Falling_Trigger_Management
* @{
*/
/**
* @brief Enable ExtiLine Falling Edge Trigger for Lines in range 0 to 31
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a falling edge on a configurable interrupt
* line occurs during a write operation in the EXTI_FTSR register, the
* pending bit is not set.
* Rising and falling edge triggers can be set for
* the same interrupt line. In this case, both generate a trigger
* condition.
* @rmtoll FTSR1 FTx LL_EXTI_EnableFallingTrig_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableFallingTrig_0_31(uint32_t ExtiLine)
{
SET_BIT(EXTI->FTSR1, ExtiLine);
}
/**
* @brief Enable ExtiLine Falling Edge Trigger for Lines in range 32 to 63
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a Falling edge on a configurable interrupt
* line occurs during a write operation in the EXTI_FTSR register, the
* pending bit is not set.
* Rising and falling edge triggers can be set for
* the same interrupt line. In this case, both generate a trigger
* condition.
* @rmtoll FTSR2 FTx LL_EXTI_EnableFallingTrig_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_EnableFallingTrig_32_63(uint32_t ExtiLine)
{
SET_BIT(EXTI->FTSR2, ExtiLine);
}
/**
* @brief Disable ExtiLine Falling Edge Trigger for Lines in range 0 to 31
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a Falling edge on a configurable interrupt
* line occurs during a write operation in the EXTI_FTSR register, the
* pending bit is not set.
* Rising and falling edge triggers can be set for the same interrupt line.
* In this case, both generate a trigger condition.
* @rmtoll FTSR1 FTx LL_EXTI_DisableFallingTrig_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableFallingTrig_0_31(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->FTSR1, ExtiLine);
}
/**
* @brief Disable ExtiLine Falling Edge Trigger for Lines in range 32 to 63
* @note The configurable wakeup lines are edge-triggered. No glitch must be
* generated on these lines. If a Falling edge on a configurable interrupt
* line occurs during a write operation in the EXTI_FTSR register, the
* pending bit is not set.
* Rising and falling edge triggers can be set for the same interrupt line.
* In this case, both generate a trigger condition.
* @rmtoll FTSR2 FTx LL_EXTI_DisableFallingTrig_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_DisableFallingTrig_32_63(uint32_t ExtiLine)
{
CLEAR_BIT(EXTI->FTSR2, ExtiLine);
}
/**
* @brief Check if falling edge trigger is enabled for Lines in range 0 to 31
* @rmtoll FTSR1 FTx LL_EXTI_IsEnabledFallingTrig_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledFallingTrig_0_31(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->FTSR1, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @brief Check if falling edge trigger is enabled for Lines in range 32 to 63
* @rmtoll FTSR2 FTx LL_EXTI_IsEnabledFallingTrig_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsEnabledFallingTrig_32_63(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->FTSR2, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup EXTI_LL_EF_Software_Interrupt_Management Software_Interrupt_Management
* @{
*/
/**
* @brief Generate a software Interrupt Event for Lines in range 0 to 31
* @note If the interrupt is enabled on this line in the EXTI_IMR1, writing a 1 to
* this bit when it is at '0' sets the corresponding pending bit in EXTI_PR1
* resulting in an interrupt request generation.
* This bit is cleared by clearing the corresponding bit in the EXTI_PR1
* register (by writing a 1 into the bit)
* @rmtoll SWIER1 SWIx LL_EXTI_GenerateSWI_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_GenerateSWI_0_31(uint32_t ExtiLine)
{
SET_BIT(EXTI->SWIER1, ExtiLine);
}
/**
* @brief Generate a software Interrupt Event for Lines in range 32 to 63
* @note If the interrupt is enabled on this line in the EXTI_IMR2, writing a 1 to
* this bit when it is at '0' sets the corresponding pending bit in EXTI_PR2
* resulting in an interrupt request generation.
* This bit is cleared by clearing the corresponding bit in the EXTI_PR2
* register (by writing a 1 into the bit)
* @rmtoll SWIER2 SWIx LL_EXTI_GenerateSWI_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_GenerateSWI_32_63(uint32_t ExtiLine)
{
SET_BIT(EXTI->SWIER2, ExtiLine);
}
/**
* @}
*/
/** @defgroup EXTI_LL_EF_Flag_Management Flag_Management
* @{
*/
/**
* @brief Check if the ExtLine Flag is set or not for Lines in range 0 to 31
* @note This bit is set when the selected edge event arrives on the interrupt
* line. This bit is cleared by writing a 1 to the bit.
* @rmtoll PR1 PIFx LL_EXTI_IsActiveFlag_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsActiveFlag_0_31(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->PR1, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @brief Check if the ExtLine Flag is set or not for Lines in range 32 to 63
* @note This bit is set when the selected edge event arrives on the interrupt
* line. This bit is cleared by writing a 1 to the bit.
* @rmtoll PR2 PIFx LL_EXTI_IsActiveFlag_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_EXTI_IsActiveFlag_32_63(uint32_t ExtiLine)
{
return ((READ_BIT(EXTI->PR2, ExtiLine) == (ExtiLine)) ? 1UL : 0UL);
}
/**
* @brief Read ExtLine Combination Flag for Lines in range 0 to 31
* @note This bit is set when the selected edge event arrives on the interrupt
* line. This bit is cleared by writing a 1 to the bit.
* @rmtoll PR1 PIFx LL_EXTI_ReadFlag_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval @note This bit is set when the selected edge event arrives on the interrupt
*/
__STATIC_INLINE uint32_t LL_EXTI_ReadFlag_0_31(uint32_t ExtiLine)
{
return (uint32_t)(READ_BIT(EXTI->PR1, ExtiLine));
}
/**
* @brief Read ExtLine Combination Flag for Lines in range 32 to 63
* @note This bit is set when the selected edge event arrives on the interrupt
* line. This bit is cleared by writing a 1 to the bit.
* @rmtoll PR2 PIFx LL_EXTI_ReadFlag_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval @note This bit is set when the selected edge event arrives on the interrupt
*/
__STATIC_INLINE uint32_t LL_EXTI_ReadFlag_32_63(uint32_t ExtiLine)
{
return (uint32_t)(READ_BIT(EXTI->PR2, ExtiLine));
}
/**
* @brief Clear ExtLine Flags for Lines in range 0 to 31
* @note This bit is set when the selected edge event arrives on the interrupt
* line. This bit is cleared by writing a 1 to the bit.
* @rmtoll PR1 PIFx LL_EXTI_ClearFlag_0_31
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_0
* @arg @ref LL_EXTI_LINE_1
* @arg @ref LL_EXTI_LINE_2
* @arg @ref LL_EXTI_LINE_3
* @arg @ref LL_EXTI_LINE_4
* @arg @ref LL_EXTI_LINE_5
* @arg @ref LL_EXTI_LINE_6
* @arg @ref LL_EXTI_LINE_7
* @arg @ref LL_EXTI_LINE_8
* @arg @ref LL_EXTI_LINE_9
* @arg @ref LL_EXTI_LINE_10
* @arg @ref LL_EXTI_LINE_11
* @arg @ref LL_EXTI_LINE_12
* @arg @ref LL_EXTI_LINE_13
* @arg @ref LL_EXTI_LINE_14
* @arg @ref LL_EXTI_LINE_15
* @arg @ref LL_EXTI_LINE_16
* @arg @ref LL_EXTI_LINE_18
* @arg @ref LL_EXTI_LINE_19
* @arg @ref LL_EXTI_LINE_20
* @arg @ref LL_EXTI_LINE_21
* @arg @ref LL_EXTI_LINE_22
* @arg @ref LL_EXTI_LINE_29
* @arg @ref LL_EXTI_LINE_30
* @arg @ref LL_EXTI_LINE_31 (*)
* @note (*): Available in some devices
* @note Please check each device line mapping for EXTI Line availability
* @retval None
*/
__STATIC_INLINE void LL_EXTI_ClearFlag_0_31(uint32_t ExtiLine)
{
WRITE_REG(EXTI->PR1, ExtiLine);
}
/**
* @brief Clear ExtLine Flags for Lines in range 32 to 63
* @note This bit is set when the selected edge event arrives on the interrupt
* line. This bit is cleared by writing a 1 to the bit.
* @rmtoll PR2 PIFx LL_EXTI_ClearFlag_32_63
* @param ExtiLine This parameter can be a combination of the following values:
* @arg @ref LL_EXTI_LINE_32 (*)
* @arg @ref LL_EXTI_LINE_33 (*)
* @arg @ref LL_EXTI_LINE_38
* @arg @ref LL_EXTI_LINE_39
* @arg @ref LL_EXTI_LINE_40
* @arg @ref LL_EXTI_LINE_41
* @note (*): Available in some devices
* @retval None
*/
__STATIC_INLINE void LL_EXTI_ClearFlag_32_63(uint32_t ExtiLine)
{
WRITE_REG(EXTI->PR2, ExtiLine);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup EXTI_LL_EF_Init Initialization and de-initialization functions
* @{
*/
uint32_t LL_EXTI_Init(LL_EXTI_InitTypeDef *EXTI_InitStruct);
uint32_t LL_EXTI_DeInit(void);
void LL_EXTI_StructInit(LL_EXTI_InitTypeDef *EXTI_InitStruct);
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
#endif /* EXTI */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_LL_EXTI_H */
| 54,310 | C | 37.16655 | 115 | 0.559363 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_tim_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_tim_ex.h
* @author MCD Application Team
* @brief Header file of TIM HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_TIM_EX_H
#define STM32G4xx_HAL_TIM_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup TIMEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup TIMEx_Exported_Types TIM Extended Exported Types
* @{
*/
/**
* @brief TIM Hall sensor Configuration Structure definition
*/
typedef struct
{
uint32_t IC1Polarity; /*!< Specifies the active edge of the input signal.
This parameter can be a value of @ref TIM_Input_Capture_Polarity */
uint32_t IC1Prescaler; /*!< Specifies the Input Capture Prescaler.
This parameter can be a value of @ref TIM_Input_Capture_Prescaler */
uint32_t IC1Filter; /*!< Specifies the input capture filter.
This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
uint32_t Commutation_Delay; /*!< Specifies the pulse value to be loaded into the Capture Compare Register.
This parameter can be a number between Min_Data = 0x0000 and Max_Data = 0xFFFF */
} TIM_HallSensor_InitTypeDef;
/**
* @brief TIM Break/Break2 input configuration
*/
typedef struct
{
uint32_t Source; /*!< Specifies the source of the timer break input.
This parameter can be a value of @ref TIMEx_Break_Input_Source */
uint32_t Enable; /*!< Specifies whether or not the break input source is enabled.
This parameter can be a value of @ref TIMEx_Break_Input_Source_Enable */
uint32_t Polarity; /*!< Specifies the break input source polarity.
This parameter can be a value of @ref TIMEx_Break_Input_Source_Polarity */
} TIMEx_BreakInputConfigTypeDef;
/**
* @brief TIM Encoder index configuration
*/
typedef struct
{
uint32_t Polarity; /*!< TIM Encoder index polarity.This parameter can be a value of @ref TIMEx_Encoder_Index_Polarity */
uint32_t Prescaler; /*!< TIM Encoder index prescaler.This parameter can be a value of @ref TIMEx_Encoder_Index_Prescaler */
uint32_t Filter; /*!< TIM Encoder index filter.This parameter can be a number between Min_Data = 0x0 and Max_Data = 0xF */
FunctionalState FirstIndexEnable; /*!< Specifies whether or not the encoder first index is enabled.This parameter value can be ENABLE or DISABLE. */
uint32_t Position; /*!< Specifies in which AB input configuration the index event resets the counter.This parameter can be a value of @ref TIMEx_Encoder_Index_Position */
uint32_t Direction; /*!< Specifies in which counter direction the index event resets the counter.This parameter can be a value of @ref TIMEx_Encoder_Index_Direction */
} TIMEx_EncoderIndexConfigTypeDef;
/**
* @}
*/
/* End of exported types -----------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup TIMEx_Exported_Constants TIM Extended Exported Constants
* @{
*/
/** @defgroup TIMEx_Remap TIM Extended Remapping
* @{
*/
#define TIM_TIM1_ETR_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define TIM_TIM1_ETR_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define TIM_TIM1_ETR_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define TIM_TIM1_ETR_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define TIM_TIM1_ETR_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM1_ETR_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM1_ETR_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM1_ETR_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM1_ETR_ADC1_AWD1 TIM1_AF1_ETRSEL_3 /*!< ADC1 analog watchdog 1 */
#define TIM_TIM1_ETR_ADC1_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ADC1 analog watchdog 2 */
#define TIM_TIM1_ETR_ADC1_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ADC1 analog watchdog 3 */
#if defined (ADC4)
#define TIM_TIM1_ETR_ADC4_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC4 analog watchdog 1 */
#define TIM_TIM1_ETR_ADC4_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC4 analog watchdog 2 */
#define TIM_TIM1_ETR_ADC4_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC4 analog watchdog 3 */
#endif /* ADC4 */
#define TIM_TIM2_ETR_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define TIM_TIM2_ETR_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define TIM_TIM2_ETR_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define TIM_TIM2_ETR_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define TIM_TIM2_ETR_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM2_ETR_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM2_ETR_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM2_ETR_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0)/*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM2_ETR_TIM3_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM3 ETR */
#define TIM_TIM2_ETR_TIM4_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM4 ETR */
#if defined (TIM5)
#define TIM_TIM2_ETR_TIM5_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to TIM5 ETR */
#endif /* TIM5 */
#define TIM_TIM2_ETR_LSE (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to LSE */
#define TIM_TIM3_ETR_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define TIM_TIM3_ETR_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define TIM_TIM3_ETR_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define TIM_TIM3_ETR_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define TIM_TIM3_ETR_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM3_ETR_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM3_ETR_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM3_ETR_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM3_ETR_TIM2_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM2 ETR */
#define TIM_TIM3_ETR_TIM4_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM4 ETR */
#define TIM_TIM3_ETR_ADC2_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC2 analog watchdog 1 */
#define TIM_TIM3_ETR_ADC2_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC2 analog watchdog 2 */
#define TIM_TIM3_ETR_ADC2_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC2 analog watchdog 3 */
#define TIM_TIM4_ETR_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define TIM_TIM4_ETR_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define TIM_TIM4_ETR_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define TIM_TIM4_ETR_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define TIM_TIM4_ETR_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM4_ETR_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM4_ETR_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM4_ETR_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM4_ETR_TIM3_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM3 ETR */
#if defined (TIM5)
#define TIM_TIM4_ETR_TIM5_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM5 ETR */
#endif /* TIM5 */
#if defined (TIM5)
#define TIM_TIM5_ETR_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define TIM_TIM5_ETR_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define TIM_TIM5_ETR_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define TIM_TIM5_ETR_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define TIM_TIM5_ETR_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM5_ETR_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM5_ETR_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM5_ETR_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM5_ETR_TIM2_ETR TIM1_AF1_ETRSEL_3 /*!< ETR input is connected to TIM2 ETR */
#define TIM_TIM5_ETR_TIM3_ETR (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to TIM3 ETR */
#endif /* TIM5 */
#define TIM_TIM8_ETR_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define TIM_TIM8_ETR_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define TIM_TIM8_ETR_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define TIM_TIM8_ETR_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define TIM_TIM8_ETR_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM8_ETR_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM8_ETR_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM8_ETR_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM8_ETR_ADC2_AWD1 TIM1_AF1_ETRSEL_3 /*!< ADC2 analog watchdog 1 */
#define TIM_TIM8_ETR_ADC2_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ADC2 analog watchdog 2 */
#define TIM_TIM8_ETR_ADC2_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ADC2 analog watchdog 3 */
#if defined (ADC3)
#define TIM_TIM8_ETR_ADC3_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC3 analog watchdog 1 */
#define TIM_TIM8_ETR_ADC3_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC3 analog watchdog 2 */
#define TIM_TIM8_ETR_ADC3_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC3 analog watchdog 3 */
#endif /* ADC3 */
#if defined (TIM20)
#define TIM_TIM20_ETR_GPIO 0x00000000U /*!< ETR input is connected to GPIO */
#define TIM_TIM20_ETR_COMP1 TIM1_AF1_ETRSEL_0 /*!< ETR input is connected to COMP1_OUT */
#define TIM_TIM20_ETR_COMP2 TIM1_AF1_ETRSEL_1 /*!< ETR input is connected to COMP2_OUT */
#define TIM_TIM20_ETR_COMP3 (TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP3_OUT */
#define TIM_TIM20_ETR_COMP4 TIM1_AF1_ETRSEL_2 /*!< ETR input is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM20_ETR_COMP5 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM20_ETR_COMP6 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1) /*!< ETR input is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM20_ETR_COMP7 (TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ETR input is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM20_ETR_ADC3_AWD1 TIM1_AF1_ETRSEL_3 /*!< ADC3 analog watchdog 1 */
#define TIM_TIM20_ETR_ADC3_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_0) /*!< ADC3 analog watchdog 2 */
#define TIM_TIM20_ETR_ADC3_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1) /*!< ADC3 analog watchdog 3 */
#if defined (ADC5)
#define TIM_TIM20_ETR_ADC5_AWD1 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_1 | TIM1_AF1_ETRSEL_0) /*!< ADC5 analog watchdog 1 */
#define TIM_TIM20_ETR_ADC5_AWD2 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2) /*!< ADC5 analog watchdog 2 */
#define TIM_TIM20_ETR_ADC5_AWD3 (TIM1_AF1_ETRSEL_3 | TIM1_AF1_ETRSEL_2 | TIM1_AF1_ETRSEL_0) /*!< ADC5 analog watchdog 3 */
#endif /* ADC5 */
#endif /* TIM20 */
/**
* @}
*/
/** @defgroup TIMEx_Break_Input TIM Extended Break input
* @{
*/
#define TIM_BREAKINPUT_BRK 0x00000001U /*!< Timer break input */
#define TIM_BREAKINPUT_BRK2 0x00000002U /*!< Timer break2 input */
/**
* @}
*/
/** @defgroup TIMEx_Break_Input_Source TIM Extended Break input source
* @{
*/
#define TIM_BREAKINPUTSOURCE_BKIN 0x00000001U /*!< An external source (GPIO) is connected to the BKIN pin */
#define TIM_BREAKINPUTSOURCE_COMP1 0x00000002U /*!< The COMP1 output is connected to the break input */
#define TIM_BREAKINPUTSOURCE_COMP2 0x00000004U /*!< The COMP2 output is connected to the break input */
#define TIM_BREAKINPUTSOURCE_COMP3 0x00000008U /*!< The COMP3 output is connected to the break input */
#define TIM_BREAKINPUTSOURCE_COMP4 0x00000010U /*!< The COMP4 output is connected to the break input */
#if defined(COMP5)
#define TIM_BREAKINPUTSOURCE_COMP5 0x00000020U /*!< The COMP5 output is connected to the break input */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_BREAKINPUTSOURCE_COMP6 0x00000040U /*!< The COMP6 output is connected to the break input */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_BREAKINPUTSOURCE_COMP7 0x00000080U /*!< The COMP7 output is connected to the break input */
#endif /* COMP7 */
/**
* @}
*/
/** @defgroup TIMEx_Break_Input_Source_Enable TIM Extended Break input source enabling
* @{
*/
#define TIM_BREAKINPUTSOURCE_DISABLE 0x00000000U /*!< Break input source is disabled */
#define TIM_BREAKINPUTSOURCE_ENABLE 0x00000001U /*!< Break input source is enabled */
/**
* @}
*/
/** @defgroup TIMEx_Break_Input_Source_Polarity TIM Extended Break input polarity
* @{
*/
#define TIM_BREAKINPUTSOURCE_POLARITY_LOW 0x00000001U /*!< Break input source is active low */
#define TIM_BREAKINPUTSOURCE_POLARITY_HIGH 0x00000000U /*!< Break input source is active_high */
/**
* @}
*/
/** @defgroup TIMEx_Timer_Input_Selection TIM Extended Timer input selection
* @{
*/
#define TIM_TIM1_TI1_GPIO 0x00000000U /*!< TIM1 input 1 is connected to GPIO */
#define TIM_TIM1_TI1_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM1 input 1 is connected to COMP1_OUT */
#define TIM_TIM1_TI1_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM1 input 1 is connected to COMP2_OUT */
#define TIM_TIM1_TI1_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM1 input 1 is connected to COMP3_OUT */
#define TIM_TIM1_TI1_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM1 input 1 is connected to COMP4_OUT */
#define TIM_TIM2_TI1_GPIO 0x00000000U /*!< TIM2 input 1 is connected to GPIO */
#define TIM_TIM2_TI1_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM2 input 1 is connected to COMP1_OUT */
#define TIM_TIM2_TI1_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM2 input 1 is connected to COMP2_OUT */
#define TIM_TIM2_TI1_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM2 input 1 is connected to COMP3_OUT */
#define TIM_TIM2_TI1_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM2 input 1 is connected to COMP4_OUT */
#if defined (COMP5)
#define TIM_TIM2_TI1_COMP5 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM2 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#define TIM_TIM2_TI2_GPIO 0x00000000U /*!< TIM2 input 2 is connected to GPIO */
#define TIM_TIM2_TI2_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM2 input 2 is connected to COMP1_OUT */
#define TIM_TIM2_TI2_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM2 input 2 is connected to COMP2_OUT */
#define TIM_TIM2_TI2_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM2 input 2 is connected to COMP3_OUT */
#define TIM_TIM2_TI2_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM2 input 2 is connected to COMP4_OUT */
#if defined (COMP6)
#define TIM_TIM2_TI2_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM2 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#define TIM_TIM2_TI3_GPIO 0x00000000U /*!< TIM2 input 3 is connected to GPIO */
#define TIM_TIM2_TI3_COMP4 TIM_TISEL_TI3SEL_0 /*!< TIM2 input 3 is connected to COMP4_OUT */
#define TIM_TIM2_TI4_GPIO 0x00000000U /*!< TIM2 input 4 is connected to GPIO */
#define TIM_TIM2_TI4_COMP1 TIM_TISEL_TI4SEL_0 /*!< TIM2 input 4 is connected to COMP1_OUT */
#define TIM_TIM2_TI4_COMP2 TIM_TISEL_TI4SEL_1 /*!< TIM2 input 4 is connected to COMP2_OUT */
#define TIM_TIM3_TI1_GPIO 0x00000000U /*!< TIM3 input 1 is connected to GPIO */
#define TIM_TIM3_TI1_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM3 input 1 is connected to COMP1_OUT */
#define TIM_TIM3_TI1_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM3 input 1 is connected to COMP2_OUT */
#define TIM_TIM3_TI1_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM3 input 1 is connected to COMP3_OUT */
#define TIM_TIM3_TI1_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM3 input 1 is connected to COMP4_OUT */
#if defined (COMP5)
#define TIM_TIM3_TI1_COMP5 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM3 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined (COMP6)
#define TIM_TIM3_TI1_COMP6 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM3 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined (COMP7)
#define TIM_TIM3_TI1_COMP7 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM3 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM3_TI2_GPIO 0x00000000U /*!< TIM3 input 2 is connected to GPIO */
#define TIM_TIM3_TI2_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM3 input 2 is connected to COMP1_OUT */
#define TIM_TIM3_TI2_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM3 input 2 is connected to COMP2_OUT */
#define TIM_TIM3_TI2_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM3 input 2 is connected to COMP3_OUT */
#define TIM_TIM3_TI2_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM3 input 2 is connected to COMP4_OUT */
#if defined (COMP5)
#define TIM_TIM3_TI2_COMP5 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM3 input 2 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined (COMP6)
#define TIM_TIM3_TI2_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1) /*!< TIM3 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined (COMP7)
#define TIM_TIM3_TI2_COMP7 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM3 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM3_TI3_GPIO 0x00000000U /*!< TIM3 input 3 is connected to GPIO */
#define TIM_TIM3_TI3_COMP3 TIM_TISEL_TI3SEL_0 /*!< TIM3 input 3 is connected to COMP3_OUT */
#define TIM_TIM4_TI1_GPIO 0x00000000U /*!< TIM4 input 1 is connected to GPIO */
#define TIM_TIM4_TI1_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM4 input 1 is connected to COMP1_OUT */
#define TIM_TIM4_TI1_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM4 input 1 is connected to COMP2_OUT */
#define TIM_TIM4_TI1_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM4 input 1 is connected to COMP3_OUT */
#define TIM_TIM4_TI1_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM4 input 1 is connected to COMP4_OUT */
#if defined (COMP5)
#define TIM_TIM4_TI1_COMP5 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM4 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined (COMP6)
#define TIM_TIM4_TI1_COMP6 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM4 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined (COMP7)
#define TIM_TIM4_TI1_COMP7 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM4 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM4_TI2_GPIO 0x00000000U /*!< TIM4 input 2 is connected to GPIO */
#define TIM_TIM4_TI2_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM4 input 2 is connected to COMP1_OUT */
#define TIM_TIM4_TI2_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM4 input 2 is connected to COMP2_OUT */
#define TIM_TIM4_TI2_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM4 input 2 is connected to COMP3_OUT */
#define TIM_TIM4_TI2_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM4 input 2 is connected to COMP4_OUT */
#if defined (COMP5)
#define TIM_TIM4_TI2_COMP5 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM4 input 2 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined (COMP6)
#define TIM_TIM4_TI2_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1) /*!< TIM4 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined (COMP7)
#define TIM_TIM4_TI2_COMP7 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM4 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM4_TI3_GPIO 0x00000000U /*!< TIM4 input 3 is connected to GPIO */
#if defined (COMP5)
#define TIM_TIM4_TI3_COMP5 TIM_TISEL_TI3SEL_0 /*!< TIM4 input 3 is connected to COMP5_OUT */
#endif /* COMP5 */
#define TIM_TIM4_TI4_GPIO 0x00000000U /*!< TIM4 input 4 is connected to GPIO */
#if defined (COMP6)
#define TIM_TIM4_TI4_COMP6 TIM_TISEL_TI4SEL_0 /*!< TIM4 input 4 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(TIM5)
#define TIM_TIM5_TI1_GPIO 0x00000000U /*!< TIM5 input 1 is connected to GPIO */
#define TIM_TIM5_TI1_LSI TIM_TISEL_TI1SEL_0 /*!< TIM5 input 1 is connected to LSI */
#define TIM_TIM5_TI1_LSE TIM_TISEL_TI1SEL_1 /*!< TIM5 input 1 is connected to LSE */
#define TIM_TIM5_TI1_RTC_WK (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to RTC_WAKEUP */
#define TIM_TIM5_TI1_COMP1 TIM_TISEL_TI1SEL_2 /*!< TIM5 input 1 is connected to COMP1_OUT */
#define TIM_TIM5_TI1_COMP2 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to COMP2_OUT */
#define TIM_TIM5_TI1_COMP3 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM5 input 1 is connected to COMP3_OUT */
#define TIM_TIM5_TI1_COMP4 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM5_TI1_COMP5 TIM_TISEL_TI1SEL_3 /*!< TIM5 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM5_TI1_COMP6 (TIM_TISEL_TI1SEL_3 | TIM_TISEL_TI1SEL_0) /*!< TIM5 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM5_TI1_COMP7 (TIM_TISEL_TI1SEL_3 | TIM_TISEL_TI1SEL_1) /*!< TIM5 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM5_TI2_GPIO 0x00000000U /*!< TIM5 input 2 is connected to GPIO */
#define TIM_TIM5_TI2_COMP1 TIM_TISEL_TI2SEL_0 /*!< TIM5 input 2 is connected to COMP1_OUT */
#define TIM_TIM5_TI2_COMP2 TIM_TISEL_TI2SEL_1 /*!< TIM5 input 2 is connected to COMP2_OUT */
#define TIM_TIM5_TI2_COMP3 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM5 input 2 is connected to COMP3_OUT */
#define TIM_TIM5_TI2_COMP4 TIM_TISEL_TI2SEL_2 /*!< TIM5 input 2 is connected to COMP4_OUT */
#if defined(COMP5)
#define TIM_TIM5_TI2_COMP5 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_0) /*!< TIM5 input 2 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP6)
#define TIM_TIM5_TI2_COMP6 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1) /*!< TIM5 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM5_TI2_COMP7 (TIM_TISEL_TI2SEL_2 | TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM5 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
#endif /* TIM5 */
#define TIM_TIM8_TI1_GPIO 0x00000000U /*!< TIM8 input 1 is connected to GPIO */
#define TIM_TIM8_TI1_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM8 input 1 is connected to COMP1_OUT */
#define TIM_TIM8_TI1_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM8 input 1 is connected to COMP2_OUT */
#define TIM_TIM8_TI1_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM8 input 1 is connected to COMP3_OUT */
#define TIM_TIM8_TI1_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM8 input 1 is connected to COMP4_OUT */
#define TIM_TIM15_TI1_GPIO 0x00000000U /*!< TIM15 input 1 is connected to GPIO */
#define TIM_TIM15_TI1_LSE TIM_TISEL_TI1SEL_0 /*!< TIM15 input 1 is connected to LSE */
#define TIM_TIM15_TI1_COMP1 TIM_TISEL_TI1SEL_1 /*!< TIM15 input 1 is connected to COMP1_OUT */
#define TIM_TIM15_TI1_COMP2 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM15 input 1 is connected to COMP2_OUT */
#if defined (COMP5)
#define TIM_TIM15_TI1_COMP5 TIM_TISEL_TI1SEL_2 /*!< TIM15 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#if defined(COMP7)
#define TIM_TIM15_TI1_COMP7 (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM15 input 1 is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM15_TI2_GPIO 0x00000000U /*!< TIM15 input 2 is connected to GPIO */
#define TIM_TIM15_TI2_COMP2 TIM_TISEL_TI2SEL_0 /*!< TIM15 input 2 is connected to COMP2_OUT */
#define TIM_TIM15_TI2_COMP3 TIM_TISEL_TI2SEL_1 /*!< TIM15 input 2 is connected to COMP3_OUT */
#if defined (COMP6)
#define TIM_TIM15_TI2_COMP6 (TIM_TISEL_TI2SEL_1 | TIM_TISEL_TI2SEL_0) /*!< TIM15 input 2 is connected to COMP6_OUT */
#endif /* COMP6 */
#if defined(COMP7)
#define TIM_TIM15_TI2_COMP7 TIM_TISEL_TI2SEL_2 /*!< TIM15 input 2 is connected to COMP7_OUT */
#endif /* COMP7 */
#define TIM_TIM16_TI1_GPIO 0x00000000U /*!< TIM16 input 1 is connected to GPIO */
#if defined (COMP6)
#define TIM_TIM16_TI1_COMP6 TIM_TISEL_TI1SEL_0 /*!< TIM16 input 1 is connected to COMP6_OUT */
#endif /* COMP6 */
#define TIM_TIM16_TI1_MCO TIM_TISEL_TI1SEL_1 /*!< TIM16 input 1 is connected to MCO */
#define TIM_TIM16_TI1_HSE_32 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM16 input 1 is connected to HSE/32 */
#define TIM_TIM16_TI1_RTC_WK TIM_TISEL_TI1SEL_2 /*!< TIM16 input 1 is connected to RTC_WAKEUP */
#define TIM_TIM16_TI1_LSE (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM16 input 1 is connected to LSE */
#define TIM_TIM16_TI1_LSI (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM16 input 1 is connected to LSI */
#define TIM_TIM17_TI1_GPIO 0x00000000U /*!< TIM17 input 1 is connected to GPIO */
#if defined (COMP5)
#define TIM_TIM17_TI1_COMP5 TIM_TISEL_TI1SEL_0 /*!< TIM17 input 1 is connected to COMP5_OUT */
#endif /* COMP5 */
#define TIM_TIM17_TI1_MCO TIM_TISEL_TI1SEL_1 /*!< TIM17 input 1 is connected to MCO */
#define TIM_TIM17_TI1_HSE_32 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM17 input 1 is connected to HSE/32 */
#define TIM_TIM17_TI1_RTC_WK TIM_TISEL_TI1SEL_2 /*!< TIM17 input 1 is connected to RTC_WAKEUP */
#define TIM_TIM17_TI1_LSE (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_0) /*!< TIM17 input 1 is connected to LSE */
#define TIM_TIM17_TI1_LSI (TIM_TISEL_TI1SEL_2 | TIM_TISEL_TI1SEL_1) /*!< TIM17 input 1 is connected to LSI */
#if defined (TIM20)
#define TIM_TIM20_TI1_GPIO 0x00000000U /*!< TIM20 input 1 is connected to GPIO */
#define TIM_TIM20_TI1_COMP1 TIM_TISEL_TI1SEL_0 /*!< TIM20 input 1 is connected to COMP1_OUT */
#define TIM_TIM20_TI1_COMP2 TIM_TISEL_TI1SEL_1 /*!< TIM20 input 1 is connected to COMP2_OUT */
#define TIM_TIM20_TI1_COMP3 (TIM_TISEL_TI1SEL_1 | TIM_TISEL_TI1SEL_0) /*!< TIM20 input 1 is connected to COMP3_OUT */
#define TIM_TIM20_TI1_COMP4 TIM_TISEL_TI1SEL_2 /*!< TIM20 input 1 is connected to COMP4_OUT */
#endif /* TIM20 */
/**
* @}
*/
/** @defgroup TIMEx_SMS_Preload_Enable TIM Extended Bitfield SMS preload enabling
* @{
*/
#define TIM_SMS_PRELOAD_SOURCE_UPDATE 0x00000000U /*!< Prelaod of SMS bitfield is disabled */
#define TIM_SMS_PRELOAD_SOURCE_INDEX TIM_SMCR_SMSPS /*!< Preload of SMS bitfield is enabled */
/**
* @}
*/
/** @defgroup TIMEx_Encoder_Index_Position TIM Extended Encoder index position
* @{
*/
#define TIM_ENCODERINDEX_POSITION_00 0x00000000U /*!< Encoder index position is AB=00 */
#define TIM_ENCODERINDEX_POSITION_01 TIM_ECR_IPOS_0 /*!< Encoder index position is AB=01 */
#define TIM_ENCODERINDEX_POSITION_10 TIM_ECR_IPOS_1 /*!< Encoder index position is AB=10 */
#define TIM_ENCODERINDEX_POSITION_11 (TIM_ECR_IPOS_1 | TIM_ECR_IPOS_0) /*!< Encoder index position is AB=11 */
#define TIM_ENCODERINDEX_POSITION_0 0x00000000U /*!< In directional clock mode or clock plus direction mode, index resets the counter when clock is 0 */
#define TIM_ENCODERINDEX_POSITION_1 TIM_ECR_IPOS_0 /*!< In directional clock mode or clock plus direction mode, index resets the counter when clock is 1 */
/**
* @}
*/
/** @defgroup TIMEx_Encoder_Index_Direction TIM Extended Encoder index direction
* @{
*/
#define TIM_ENCODERINDEX_DIRECTION_UP_DOWN 0x00000000U /*!< Index resets the counter whatever the direction */
#define TIM_ENCODERINDEX_DIRECTION_UP TIM_ECR_IDIR_0 /*!< Index resets the counter when up-counting only */
#define TIM_ENCODERINDEX_DIRECTION_DOWN TIM_ECR_IDIR_1 /*!< Index resets the counter when down-counting only */
/**
* @}
*/
/** @defgroup TIMEx_Encoder_Index_Polarity TIM Extended Encoder index polarity
* @{
*/
#define TIM_ENCODERINDEX_POLARITY_INVERTED TIM_ETRPOLARITY_INVERTED /*!< Polarity for ETRx pin */
#define TIM_ENCODERINDEX_POLARITY_NONINVERTED TIM_ETRPOLARITY_NONINVERTED /*!< Polarity for ETRx pin */
/**
* @}
*/
/** @defgroup TIMEx_Encoder_Index_Prescaler TIM Extended Encodder index prescaler
* @{
*/
#define TIM_ENCODERINDEX_PRESCALER_DIV1 TIM_ETRPRESCALER_DIV1 /*!< No prescaler is used */
#define TIM_ENCODERINDEX_PRESCALER_DIV2 TIM_ETRPRESCALER_DIV2 /*!< Prescaler for External ETR pin: Capture performed once every 2 events. */
#define TIM_ENCODERINDEX_PRESCALER_DIV4 TIM_ETRPRESCALER_DIV4 /*!< Prescaler for External ETR pin: Capture performed once every 4 events. */
#define TIM_ENCODERINDEX_PRESCALER_DIV8 TIM_ETRPRESCALER_DIV8 /*!< Prescaler for External ETR pin: Capture performed once every 8 events. */
/**
* @}
*/
/**
* @}
*/
/* End of exported constants -------------------------------------------------*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup TIMEx_Exported_Macros TIM Extended Exported Macros
* @{
*/
/**
* @brief HELPER macro calculating the prescaler value to achieve the required counter clock frequency.
* @note ex: @ref __HAL_TIM_CALC_PSC(80000000, 1000000);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __CNTCLK__ counter clock frequency (in Hz)
* @retval Prescaler value (between Min_Data=0 and Max_Data=65535)
*/
#define __HAL_TIM_CALC_PSC(__TIMCLK__, __CNTCLK__) \
((__TIMCLK__) >= (__CNTCLK__)) ? (uint32_t)((__TIMCLK__)/(__CNTCLK__) - 1U) : 0U
/**
* @brief HELPER macro calculating the auto-reload value to achieve the required output signal frequency.
* @note ex: @ref __HAL_TIM_CALC_PERIOD(1000000, 0, 10000);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __FREQ__ output signal frequency (in Hz)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65535)
*/
#define __HAL_TIM_CALC_PERIOD(__TIMCLK__, __PSC__, __FREQ__) \
(((__TIMCLK__)/((__PSC__) + 1U)) >= (__FREQ__)) ? ((__TIMCLK__)/((__FREQ__) * ((__PSC__) + 1U)) - 1U) : 0U
/**
* @brief HELPER macro calculating the auto-reload value, with dithering feature enabled, to achieve the required
* output signal frequency.
* @note ex: @ref __HAL_TIM_CALC_PERIOD_DITHER(1000000, 0, 10000);
* @note This macro should be used only if dithering is already enabled
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __FREQ__ output signal frequency (in Hz)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65519)
*/
#define __HAL_TIM_CALC_PERIOD_DITHER(__TIMCLK__, __PSC__, __FREQ__) \
(((__TIMCLK__)/((__PSC__) + 1U)) >= (__FREQ__)) ? \
(uint32_t)(((uint64_t)(__TIMCLK__)*16/((__FREQ__) * ((__PSC__) + 1U)) - 16U)) : 0U
/**
* @brief HELPER macro calculating the compare value required to achieve the required timer output compare
* active/inactive delay.
* @note ex: @ref __HAL_TIM_CALC_PULSE(1000000, 0, 10);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @retval Compare value (between Min_Data=0 and Max_Data=65535)
*/
#define __HAL_TIM_CALC_PULSE(__TIMCLK__, __PSC__, __DELAY__) \
((uint32_t)(((uint64_t)(__TIMCLK__) * (uint64_t)(__DELAY__)) \
/ ((uint64_t)1000000U * (uint64_t)((__PSC__) + 1U))))
/**
* @brief HELPER macro calculating the compare value, with dithering feature enabled, to achieve the required timer
* output compare active/inactive delay.
* @note ex: @ref __HAL_TIM_CALC_PULSE_DITHER(1000000, 0, 10);
* @note This macro should be used only if dithering is already enabled
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @retval Compare value (between Min_Data=0 and Max_Data=65519)
*/
#define __HAL_TIM_CALC_PULSE_DITHER(__TIMCLK__, __PSC__, __DELAY__) \
((uint32_t)(((uint64_t)(__TIMCLK__) * (uint64_t)(__DELAY__) * 16U) \
/ ((uint64_t)1000000U * (uint64_t)((__PSC__) + 1U))))
/**
* @brief HELPER macro calculating the auto-reload value to achieve the required pulse duration
* (when the timer operates in one pulse mode).
* @note ex: @ref __HAL_TIM_CALC_PERIOD_BY_DELAY(1000000, 0, 10, 20);
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @param __PULSE__ pulse duration (in us)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65535)
*/
#define __HAL_TIM_CALC_PERIOD_BY_DELAY(__TIMCLK__, __PSC__, __DELAY__, __PULSE__) \
((uint32_t)(__HAL_TIM_CALC_PULSE((__TIMCLK__), (__PSC__), (__PULSE__)) \
+ __HAL_TIM_CALC_PULSE((__TIMCLK__), (__PSC__), (__DELAY__))))
/**
* @brief HELPER macro calculating the auto-reload value, with dithering feature enabled, to achieve the required
* pulse duration (when the timer operates in one pulse mode).
* @note ex: @ref __HAL_TIM_CALC_PERIOD_DITHER_BY_DELAY(1000000, 0, 10, 20);
* @note This macro should be used only if dithering is already enabled
* @param __TIMCLK__ timer input clock frequency (in Hz)
* @param __PSC__ prescaler
* @param __DELAY__ timer output compare active/inactive delay (in us)
* @param __PULSE__ pulse duration (in us)
* @retval Auto-reload value (between Min_Data=0 and Max_Data=65519)
*/
#define __HAL_TIM_CALC_PERIOD_DITHER_BY_DELAY(__TIMCLK__, __PSC__, __DELAY__, __PULSE__) \
((uint32_t)(__HAL_TIM_CALC_PULSE_DITHER((__TIMCLK__), (__PSC__), (__PULSE__)) \
+ __HAL_TIM_CALC_PULSE_DITHER((__TIMCLK__), (__PSC__), (__DELAY__))))
/**
* @}
*/
/* End of exported macro -----------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/** @defgroup TIMEx_Private_Macros TIM Extended Private Macros
* @{
*/
#define IS_TIM_REMAP(__REMAP__) ((((__REMAP__) & 0xFFFC3FFFU) == 0x00000000U))
#define IS_TIM_BREAKINPUT(__BREAKINPUT__) (((__BREAKINPUT__) == TIM_BREAKINPUT_BRK) || \
((__BREAKINPUT__) == TIM_BREAKINPUT_BRK2))
#if defined (COMP5) && defined (COMP6) && defined (COMP7)
#define IS_TIM_BREAKINPUTSOURCE(__SOURCE__) (((__SOURCE__) == TIM_BREAKINPUTSOURCE_BKIN) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP1) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP2) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP3) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP4) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP5) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP6) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP7))
#else
#define IS_TIM_BREAKINPUTSOURCE(__SOURCE__) (((__SOURCE__) == TIM_BREAKINPUTSOURCE_BKIN) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP1) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP2) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP3) || \
((__SOURCE__) == TIM_BREAKINPUTSOURCE_COMP4))
#endif /* COMP5 && COMP6 && COMP7 */
#define IS_TIM_BREAKINPUTSOURCE_STATE(__STATE__) (((__STATE__) == TIM_BREAKINPUTSOURCE_DISABLE) || \
((__STATE__) == TIM_BREAKINPUTSOURCE_ENABLE))
#define IS_TIM_BREAKINPUTSOURCE_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_BREAKINPUTSOURCE_POLARITY_LOW) || \
((__POLARITY__) == TIM_BREAKINPUTSOURCE_POLARITY_HIGH))
#define IS_TIM_TISEL(__TISEL__) ((((__TISEL__) & 0xF0F0F0F0U) == 0x00000000U))
#define IS_TIM_TISEL_TIX_INSTANCE(INSTANCE, CHANNEL) \
(IS_TIM_CCX_INSTANCE(INSTANCE, CHANNEL) && ((CHANNEL) < TIM_CHANNEL_5))
#if defined(TIM5) && defined(TIM20)
#define IS_TIM_CLOCKSOURCE_INSTANCE(INSTANCE, __CLOCK__) \
((((INSTANCE) == TIM1) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10))) \
|| \
(((INSTANCE) == TIM2) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10))) \
|| \
(((INSTANCE) == TIM4) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10))) \
|| \
(((INSTANCE) == TIM5) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10))) \
|| \
(((INSTANCE) == TIM8) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10))) \
|| \
(((INSTANCE) == TIM15) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10))) \
|| \
(((INSTANCE) == TIM20) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR10))))
#define IS_TIM_TRIGGER_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10) || \
((__SELECTION__) == TIM_TS_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10))) \
|| \
(((INSTANCE) == TIM5) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10))) \
|| \
(((INSTANCE) == TIM20) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR10))))
#define IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_ITR11)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM5) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM20) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR10)|| \
((__SELECTION__) == TIM_TS_NONE))))
#elif defined(TIM5)
#define IS_TIM_CLOCKSOURCE_INSTANCE(INSTANCE, __CLOCK__) \
((((INSTANCE) == TIM1) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM2) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM4) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM5) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM8) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM15) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR4) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))))
#define IS_TIM_TRIGGER_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM5) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))))
#define IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR11)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM5) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR4) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))))
#elif defined(TIM20)
#define IS_TIM_CLOCKSOURCE_INSTANCE(INSTANCE, __CLOCK__) \
((((INSTANCE) == TIM1) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9))) \
|| \
(((INSTANCE) == TIM2) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9))) \
|| \
(((INSTANCE) == TIM4) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9))) \
|| \
(((INSTANCE) == TIM8) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9))) \
|| \
(((INSTANCE) == TIM15) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR9))) \
|| \
(((INSTANCE) == TIM20) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))))
#define IS_TIM_TRIGGER_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9))) \
|| \
(((INSTANCE) == TIM20) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))))
#define IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_ITR11)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR9) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM20) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))))
#else
#define IS_TIM_CLOCKSOURCE_INSTANCE(INSTANCE, __CLOCK__) \
((((INSTANCE) == TIM1) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM2) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM4) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM8) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ETRMODE1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR6) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))) \
|| \
(((INSTANCE) == TIM15) && \
(((__CLOCK__) == TIM_CLOCKSOURCE_INTERNAL) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1ED) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_TI2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR0) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR1) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR2) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR3) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR5) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR7) || \
((__CLOCK__) == TIM_CLOCKSOURCE_ITR8))))
#define IS_TIM_TRIGGER_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR11))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ETRF) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_TI1F_ED) || \
((__SELECTION__) == TIM_TS_TI1FP1) || \
((__SELECTION__) == TIM_TS_TI2FP2) || \
((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8))))
#define IS_TIM_INTERNAL_TRIGGEREVENT_INSTANCE(INSTANCE, __SELECTION__) \
((((INSTANCE) == TIM1) && \
(((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM2) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_ITR11)|| \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM3) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM4) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM8) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR6) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))) \
|| \
(((INSTANCE) == TIM15) && \
(((__SELECTION__) == TIM_TS_ITR0) || \
((__SELECTION__) == TIM_TS_ITR1) || \
((__SELECTION__) == TIM_TS_ITR2) || \
((__SELECTION__) == TIM_TS_ITR3) || \
((__SELECTION__) == TIM_TS_ITR5) || \
((__SELECTION__) == TIM_TS_ITR7) || \
((__SELECTION__) == TIM_TS_ITR8) || \
((__SELECTION__) == TIM_TS_NONE))))
#endif /* TIM5 && TIM20 */
#define IS_TIM_OC_CHANNEL_MODE(__MODE__, __CHANNEL__) \
(IS_TIM_OC_MODE(__MODE__) \
&& ((((__MODE__) == TIM_OCMODE_DIRECTION_OUTPUT) || ((__MODE__) == TIM_OCMODE_PULSE_ON_COMPARE)) \
? (((__CHANNEL__) == TIM_CHANNEL_3) || ((__CHANNEL__) == TIM_CHANNEL_4)) : (1 == 1)))
#define IS_TIM_PULSEONCOMPARE_CHANNEL(__CHANNEL__) \
(((__CHANNEL__) == TIM_CHANNEL_3) || \
((__CHANNEL__) == TIM_CHANNEL_4))
#define IS_TIM_PULSEONCOMPARE_INSTANCE(INSTANCE) IS_TIM_CC3_INSTANCE(INSTANCE)
#define IS_TIM_PULSEONCOMPARE_WIDTH(__WIDTH__) ((__WIDTH__) <= 0xFFU)
#define IS_TIM_PULSEONCOMPARE_WIDTHPRESCALER(__PRESCALER__) ((__PRESCALER__) <= 0x7U)
#define IS_TIM_SLAVE_PRELOAD_SOURCE(__SOURCE__) (((__SOURCE__) == TIM_SMS_PRELOAD_SOURCE_UPDATE) \
|| ((__SOURCE__) == TIM_SMS_PRELOAD_SOURCE_INDEX))
#define IS_TIM_ENCODERINDEX_POLARITY(__POLARITY__) (((__POLARITY__) == TIM_ENCODERINDEX_POLARITY_INVERTED) || \
((__POLARITY__) == TIM_ENCODERINDEX_POLARITY_NONINVERTED))
#define IS_TIM_ENCODERINDEX_PRESCALER(__PRESCALER__) (((__PRESCALER__) == TIM_ENCODERINDEX_PRESCALER_DIV1) || \
((__PRESCALER__) == TIM_ENCODERINDEX_PRESCALER_DIV2) || \
((__PRESCALER__) == TIM_ENCODERINDEX_PRESCALER_DIV4) || \
((__PRESCALER__) == TIM_ENCODERINDEX_PRESCALER_DIV8))
#define IS_TIM_ENCODERINDEX_FILTER(__FILTER__) ((__FILTER__) <= 0xFUL)
#define IS_TIM_ENCODERINDEX_POSITION(__POSITION__) (((__POSITION__) == TIM_ENCODERINDEX_POSITION_00) || \
((__POSITION__) == TIM_ENCODERINDEX_POSITION_01) || \
((__POSITION__) == TIM_ENCODERINDEX_POSITION_10) || \
((__POSITION__) == TIM_ENCODERINDEX_POSITION_11) || \
((__POSITION__) == TIM_ENCODERINDEX_POSITION_0) || \
((__POSITION__) == TIM_ENCODERINDEX_POSITION_1))
#define IS_TIM_ENCODERINDEX_DIRECTION(__DIRECTION__) (((__DIRECTION__) == TIM_ENCODERINDEX_DIRECTION_UP_DOWN) || \
((__DIRECTION__) == TIM_ENCODERINDEX_DIRECTION_UP) || \
((__DIRECTION__) == TIM_ENCODERINDEX_DIRECTION_DOWN))
/**
* @}
*/
/* End of private macro ------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup TIMEx_Exported_Functions TIM Extended Exported Functions
* @{
*/
/** @addtogroup TIMEx_Exported_Functions_Group1 Extended Timer Hall Sensor functions
* @brief Timer Hall Sensor functions
* @{
*/
/* Timer Hall Sensor functions **********************************************/
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Init(TIM_HandleTypeDef *htim, const TIM_HallSensor_InitTypeDef *sConfig);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_DeInit(TIM_HandleTypeDef *htim);
void HAL_TIMEx_HallSensor_MspInit(TIM_HandleTypeDef *htim);
void HAL_TIMEx_HallSensor_MspDeInit(TIM_HandleTypeDef *htim);
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop(TIM_HandleTypeDef *htim);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start_IT(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop_IT(TIM_HandleTypeDef *htim);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Start_DMA(TIM_HandleTypeDef *htim, uint32_t *pData, uint16_t Length);
HAL_StatusTypeDef HAL_TIMEx_HallSensor_Stop_DMA(TIM_HandleTypeDef *htim);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group2 Extended Timer Complementary Output Compare functions
* @brief Timer Complementary Output Compare functions
* @{
*/
/* Timer Complementary Output Compare functions *****************************/
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_OCN_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_OCN_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIMEx_OCN_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length);
HAL_StatusTypeDef HAL_TIMEx_OCN_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group3 Extended Timer Complementary PWM functions
* @brief Timer Complementary PWM functions
* @{
*/
/* Timer Complementary PWM functions ****************************************/
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t Channel);
/* Non-Blocking mode: DMA */
HAL_StatusTypeDef HAL_TIMEx_PWMN_Start_DMA(TIM_HandleTypeDef *htim, uint32_t Channel, const uint32_t *pData,
uint16_t Length);
HAL_StatusTypeDef HAL_TIMEx_PWMN_Stop_DMA(TIM_HandleTypeDef *htim, uint32_t Channel);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group4 Extended Timer Complementary One Pulse functions
* @brief Timer Complementary One Pulse functions
* @{
*/
/* Timer Complementary One Pulse functions **********************************/
/* Blocking mode: Polling */
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Start(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Stop(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
/* Non-Blocking mode: Interrupt */
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Start_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
HAL_StatusTypeDef HAL_TIMEx_OnePulseN_Stop_IT(TIM_HandleTypeDef *htim, uint32_t OutputChannel);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group5 Extended Peripheral Control functions
* @brief Peripheral Control functions
* @{
*/
/* Extended Control functions ************************************************/
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource);
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent_IT(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource);
HAL_StatusTypeDef HAL_TIMEx_ConfigCommutEvent_DMA(TIM_HandleTypeDef *htim, uint32_t InputTrigger,
uint32_t CommutationSource);
HAL_StatusTypeDef HAL_TIMEx_MasterConfigSynchronization(TIM_HandleTypeDef *htim,
const TIM_MasterConfigTypeDef *sMasterConfig);
HAL_StatusTypeDef HAL_TIMEx_ConfigBreakDeadTime(TIM_HandleTypeDef *htim,
const TIM_BreakDeadTimeConfigTypeDef *sBreakDeadTimeConfig);
HAL_StatusTypeDef HAL_TIMEx_ConfigBreakInput(TIM_HandleTypeDef *htim, uint32_t BreakInput,
const TIMEx_BreakInputConfigTypeDef *sBreakInputConfig);
HAL_StatusTypeDef HAL_TIMEx_GroupChannel5(TIM_HandleTypeDef *htim, uint32_t Channels);
HAL_StatusTypeDef HAL_TIMEx_RemapConfig(TIM_HandleTypeDef *htim, uint32_t Remap);
HAL_StatusTypeDef HAL_TIMEx_TISelection(TIM_HandleTypeDef *htim, uint32_t TISelection, uint32_t Channel);
HAL_StatusTypeDef HAL_TIMEx_DisarmBreakInput(TIM_HandleTypeDef *htim, uint32_t BreakInput);
HAL_StatusTypeDef HAL_TIMEx_ReArmBreakInput(const TIM_HandleTypeDef *htim, uint32_t BreakInput);
HAL_StatusTypeDef HAL_TIMEx_DitheringEnable(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_DitheringDisable(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_OC_ConfigPulseOnCompare(TIM_HandleTypeDef *htim, uint32_t PulseWidthPrescaler,
uint32_t PulseWidth);
HAL_StatusTypeDef HAL_TIMEx_ConfigSlaveModePreload(TIM_HandleTypeDef *htim, uint32_t Source);
HAL_StatusTypeDef HAL_TIMEx_EnableSlaveModePreload(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_DisableSlaveModePreload(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_EnableDeadTimePreload(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_DisableDeadTimePreload(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_ConfigDeadTime(TIM_HandleTypeDef *htim, uint32_t Deadtime);
HAL_StatusTypeDef HAL_TIMEx_ConfigAsymmetricalDeadTime(TIM_HandleTypeDef *htim, uint32_t FallingDeadtime);
HAL_StatusTypeDef HAL_TIMEx_EnableAsymmetricalDeadTime(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_DisableAsymmetricalDeadTime(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_ConfigEncoderIndex(TIM_HandleTypeDef *htim,
TIMEx_EncoderIndexConfigTypeDef *sEncoderIndexConfig);
HAL_StatusTypeDef HAL_TIMEx_EnableEncoderIndex(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_DisableEncoderIndex(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_EnableEncoderFirstIndex(TIM_HandleTypeDef *htim);
HAL_StatusTypeDef HAL_TIMEx_DisableEncoderFirstIndex(TIM_HandleTypeDef *htim);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group6 Extended Callbacks functions
* @brief Extended Callbacks functions
* @{
*/
/* Extended Callback **********************************************************/
void HAL_TIMEx_CommutCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_CommutHalfCpltCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_BreakCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_Break2Callback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_EncoderIndexCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_DirectionChangeCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_IndexErrorCallback(TIM_HandleTypeDef *htim);
void HAL_TIMEx_TransitionErrorCallback(TIM_HandleTypeDef *htim);
/**
* @}
*/
/** @addtogroup TIMEx_Exported_Functions_Group7 Extended Peripheral State functions
* @brief Extended Peripheral State functions
* @{
*/
/* Extended Peripheral State functions ***************************************/
HAL_TIM_StateTypeDef HAL_TIMEx_HallSensor_GetState(const TIM_HandleTypeDef *htim);
HAL_TIM_ChannelStateTypeDef HAL_TIMEx_GetChannelNState(const TIM_HandleTypeDef *htim, uint32_t ChannelN);
/**
* @}
*/
/**
* @}
*/
/* End of exported functions -------------------------------------------------*/
/* Private functions----------------------------------------------------------*/
/** @addtogroup TIMEx_Private_Functions TIM Extended Private Functions
* @{
*/
void TIMEx_DMACommutationCplt(DMA_HandleTypeDef *hdma);
void TIMEx_DMACommutationHalfCplt(DMA_HandleTypeDef *hdma);
/**
* @}
*/
/* End of private functions --------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_TIM_EX_H */
| 122,240 | C | 56.095283 | 189 | 0.453125 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_dmamux.h | /**
******************************************************************************
* @file stm32g4xx_ll_dmamux.h
* @author MCD Application Team
* @brief Header file of DMAMUX LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_LL_DMAMUX_H
#define __STM32G4xx_LL_DMAMUX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined (DMAMUX1)
/** @defgroup DMAMUX_LL DMAMUX
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup DMAMUX_LL_Private_Constants DMAMUX Private Constants
* @{
*/
/* Define used to get DMAMUX CCR register size */
#define DMAMUX_CCR_SIZE 0x00000004U
/* Define used to get DMAMUX RGCR register size */
#define DMAMUX_RGCR_SIZE 0x00000004U
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup DMAMUX_LL_Private_Macros DMAMUX Private Macros
* @{
*/
#define UNUSED(X) (void)X
/**
* @}
*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup DMAMUX_LL_Exported_Constants DMAMUX Exported Constants
* @{
*/
/** @defgroup DMAMUX_LL_EC_CLEAR_FLAG Clear Flags Defines
* @brief Flags defines which can be used with LL_DMAMUX_WriteReg function
* @{
*/
#define LL_DMAMUX_CFR_CSOF0 DMAMUX_CFR_CSOF0 /*!< Synchronization Event Overrun Flag Channel 0 */
#define LL_DMAMUX_CFR_CSOF1 DMAMUX_CFR_CSOF1 /*!< Synchronization Event Overrun Flag Channel 1 */
#define LL_DMAMUX_CFR_CSOF2 DMAMUX_CFR_CSOF2 /*!< Synchronization Event Overrun Flag Channel 2 */
#define LL_DMAMUX_CFR_CSOF3 DMAMUX_CFR_CSOF3 /*!< Synchronization Event Overrun Flag Channel 3 */
#define LL_DMAMUX_CFR_CSOF4 DMAMUX_CFR_CSOF4 /*!< Synchronization Event Overrun Flag Channel 4 */
#define LL_DMAMUX_CFR_CSOF5 DMAMUX_CFR_CSOF5 /*!< Synchronization Event Overrun Flag Channel 5 */
#define LL_DMAMUX_CFR_CSOF6 DMAMUX_CFR_CSOF6 /*!< Synchronization Event Overrun Flag Channel 6 */
#define LL_DMAMUX_CFR_CSOF7 DMAMUX_CFR_CSOF7 /*!< Synchronization Event Overrun Flag Channel 7 */
#define LL_DMAMUX_CFR_CSOF8 DMAMUX_CFR_CSOF8 /*!< Synchronization Event Overrun Flag Channel 8 */
#define LL_DMAMUX_CFR_CSOF9 DMAMUX_CFR_CSOF9 /*!< Synchronization Event Overrun Flag Channel 9 */
#define LL_DMAMUX_CFR_CSOF10 DMAMUX_CFR_CSOF10 /*!< Synchronization Event Overrun Flag Channel 10 */
#define LL_DMAMUX_CFR_CSOF11 DMAMUX_CFR_CSOF11 /*!< Synchronization Event Overrun Flag Channel 11 */
#define LL_DMAMUX_CFR_CSOF12 DMAMUX_CFR_CSOF12 /*!< Synchronization Event Overrun Flag Channel 12 */
#define LL_DMAMUX_CFR_CSOF13 DMAMUX_CFR_CSOF13 /*!< Synchronization Event Overrun Flag Channel 13 */
#define LL_DMAMUX_CFR_CSOF14 DMAMUX_CFR_CSOF14 /*!< Synchronization Event Overrun Flag Channel 14 */
#define LL_DMAMUX_CFR_CSOF15 DMAMUX_CFR_CSOF15 /*!< Synchronization Event Overrun Flag Channel 15 */
#define LL_DMAMUX_RGCFR_RGCOF0 DMAMUX_RGCFR_COF0 /*!< Request Generator 0 Trigger Event Overrun Flag */
#define LL_DMAMUX_RGCFR_RGCOF1 DMAMUX_RGCFR_COF1 /*!< Request Generator 1 Trigger Event Overrun Flag */
#define LL_DMAMUX_RGCFR_RGCOF2 DMAMUX_RGCFR_COF2 /*!< Request Generator 2 Trigger Event Overrun Flag */
#define LL_DMAMUX_RGCFR_RGCOF3 DMAMUX_RGCFR_COF3 /*!< Request Generator 3 Trigger Event Overrun Flag */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_DMAMUX_ReadReg function
* @{
*/
#define LL_DMAMUX_CSR_SOF0 DMAMUX_CSR_SOF0 /*!< Synchronization Event Overrun Flag Channel 0 */
#define LL_DMAMUX_CSR_SOF1 DMAMUX_CSR_SOF1 /*!< Synchronization Event Overrun Flag Channel 1 */
#define LL_DMAMUX_CSR_SOF2 DMAMUX_CSR_SOF2 /*!< Synchronization Event Overrun Flag Channel 2 */
#define LL_DMAMUX_CSR_SOF3 DMAMUX_CSR_SOF3 /*!< Synchronization Event Overrun Flag Channel 3 */
#define LL_DMAMUX_CSR_SOF4 DMAMUX_CSR_SOF4 /*!< Synchronization Event Overrun Flag Channel 4 */
#define LL_DMAMUX_CSR_SOF5 DMAMUX_CSR_SOF5 /*!< Synchronization Event Overrun Flag Channel 5 */
#define LL_DMAMUX_CSR_SOF6 DMAMUX_CSR_SOF6 /*!< Synchronization Event Overrun Flag Channel 6 */
#define LL_DMAMUX_CSR_SOF7 DMAMUX_CSR_SOF7 /*!< Synchronization Event Overrun Flag Channel 7 */
#define LL_DMAMUX_CSR_SOF8 DMAMUX_CSR_SOF8 /*!< Synchronization Event Overrun Flag Channel 8 */
#define LL_DMAMUX_CSR_SOF9 DMAMUX_CSR_SOF9 /*!< Synchronization Event Overrun Flag Channel 9 */
#define LL_DMAMUX_CSR_SOF10 DMAMUX_CSR_SOF10 /*!< Synchronization Event Overrun Flag Channel 10 */
#define LL_DMAMUX_CSR_SOF11 DMAMUX_CSR_SOF11 /*!< Synchronization Event Overrun Flag Channel 11 */
#define LL_DMAMUX_CSR_SOF12 DMAMUX_CSR_SOF12 /*!< Synchronization Event Overrun Flag Channel 12 */
#define LL_DMAMUX_CSR_SOF13 DMAMUX_CSR_SOF13 /*!< Synchronization Event Overrun Flag Channel 13 */
#define LL_DMAMUX_CSR_SOF14 DMAMUX_CSR_SOF14 /*!< Synchronization Event Overrun Flag Channel 14 */
#define LL_DMAMUX_CSR_SOF15 DMAMUX_CSR_SOF15 /*!< Synchronization Event Overrun Flag Channel 15 */
#define LL_DMAMUX_RGSR_RGOF0 DMAMUX_RGSR_OF0 /*!< Request Generator 0 Trigger Event Overrun Flag */
#define LL_DMAMUX_RGSR_RGOF1 DMAMUX_RGSR_OF1 /*!< Request Generator 1 Trigger Event Overrun Flag */
#define LL_DMAMUX_RGSR_RGOF2 DMAMUX_RGSR_OF2 /*!< Request Generator 2 Trigger Event Overrun Flag */
#define LL_DMAMUX_RGSR_RGOF3 DMAMUX_RGSR_OF3 /*!< Request Generator 3 Trigger Event Overrun Flag */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_IT IT Defines
* @brief IT defines which can be used with LL_DMA_ReadReg and LL_DMAMUX_WriteReg functions
* @{
*/
#define LL_DMAMUX_CCR_SOIE DMAMUX_CxCR_SOIE /*!< Synchronization Event Overrun Interrupt */
#define LL_DMAMUX_RGCR_RGOIE DMAMUX_RGxCR_OIE /*!< Request Generation Trigger Event Overrun Interrupt */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_REQUEST Transfer request
* @{
*/
#define LL_DMAMUX_REQ_MEM2MEM 0x00000000U /*!< Memory to memory transfer */
#define LL_DMAMUX_REQ_GENERATOR0 0x00000001U /*!< DMAMUX request generator 0 */
#define LL_DMAMUX_REQ_GENERATOR1 0x00000002U /*!< DMAMUX request generator 1 */
#define LL_DMAMUX_REQ_GENERATOR2 0x00000003U /*!< DMAMUX request generator 2 */
#define LL_DMAMUX_REQ_GENERATOR3 0x00000004U /*!< DMAMUX request generator 3 */
#define LL_DMAMUX_REQ_ADC1 0x00000005U /*!< DMAMUX ADC1 request */
#define LL_DMAMUX_REQ_DAC1_CH1 0x00000006U /*!< DMAMUX DAC1 CH1 request */
#define LL_DMAMUX_REQ_DAC1_CH2 0x00000007U /*!< DMAMUX DAC1 CH2 request */
#define LL_DMAMUX_REQ_TIM6_UP 0x00000008U /*!< DMAMUX TIM6 UP request */
#define LL_DMAMUX_REQ_TIM7_UP 0x00000009U /*!< DMAMUX TIM7 UP request */
#define LL_DMAMUX_REQ_SPI1_RX 0x0000000AU /*!< DMAMUX SPI1 RX request */
#define LL_DMAMUX_REQ_SPI1_TX 0x0000000BU /*!< DMAMUX SPI1 TX request */
#define LL_DMAMUX_REQ_SPI2_RX 0x0000000CU /*!< DMAMUX SPI2 RX request */
#define LL_DMAMUX_REQ_SPI2_TX 0x0000000DU /*!< DMAMUX SPI2 TX request */
#define LL_DMAMUX_REQ_SPI3_RX 0x0000000EU /*!< DMAMUX SPI3 RX request */
#define LL_DMAMUX_REQ_SPI3_TX 0x0000000FU /*!< DMAMUX SPI3 TX request */
#define LL_DMAMUX_REQ_I2C1_RX 0x00000010U /*!< DMAMUX I2C1 RX request */
#define LL_DMAMUX_REQ_I2C1_TX 0x00000011U /*!< DMAMUX I2C1 TX request */
#define LL_DMAMUX_REQ_I2C2_RX 0x00000012U /*!< DMAMUX I2C2 RX request */
#define LL_DMAMUX_REQ_I2C2_TX 0x00000013U /*!< DMAMUX I2C2 TX request */
#define LL_DMAMUX_REQ_I2C3_RX 0x00000014U /*!< DMAMUX I2C3 RX request */
#define LL_DMAMUX_REQ_I2C3_TX 0x00000015U /*!< DMAMUX I2C3 TX request */
#define LL_DMAMUX_REQ_I2C4_RX 0x00000016U /*!< DMAMUX I2C4 RX request */
#define LL_DMAMUX_REQ_I2C4_TX 0x00000017U /*!< DMAMUX I2C4 TX request */
#define LL_DMAMUX_REQ_USART1_RX 0x00000018U /*!< DMAMUX USART1 RX request */
#define LL_DMAMUX_REQ_USART1_TX 0x00000019U /*!< DMAMUX USART1 TX request */
#define LL_DMAMUX_REQ_USART2_RX 0x0000001AU /*!< DMAMUX USART2 RX request */
#define LL_DMAMUX_REQ_USART2_TX 0x0000001BU /*!< DMAMUX USART2 TX request */
#define LL_DMAMUX_REQ_USART3_RX 0x0000001CU /*!< DMAMUX USART3 RX request */
#define LL_DMAMUX_REQ_USART3_TX 0x0000001DU /*!< DMAMUX USART3 TX request */
#define LL_DMAMUX_REQ_UART4_RX 0x0000001EU /*!< DMAMUX UART4 RX request */
#define LL_DMAMUX_REQ_UART4_TX 0x0000001FU /*!< DMAMUX UART4 TX request */
#define LL_DMAMUX_REQ_UART5_RX 0x00000020U /*!< DMAMUX UART5 RX request */
#define LL_DMAMUX_REQ_UART5_TX 0x00000021U /*!< DMAMUX UART5 TX request */
#define LL_DMAMUX_REQ_LPUART1_RX 0x00000022U /*!< DMAMUX LPUART1 RX request */
#define LL_DMAMUX_REQ_LPUART1_TX 0x00000023U /*!< DMAMUX LPUART1 TX request */
#define LL_DMAMUX_REQ_ADC2 0x00000024U /*!< DMAMUX ADC2 request */
#define LL_DMAMUX_REQ_ADC3 0x00000025U /*!< DMAMUX ADC3 request */
#define LL_DMAMUX_REQ_ADC4 0x00000026U /*!< DMAMUX ADC4 request */
#define LL_DMAMUX_REQ_ADC5 0x00000027U /*!< DMAMUX ADC5 request */
#define LL_DMAMUX_REQ_QSPI 0x00000028U /*!< DMAMUX QSPI request */
#define LL_DMAMUX_REQ_DAC2_CH1 0x00000029U /*!< DMAMUX DAC2 CH1 request */
#define LL_DMAMUX_REQ_TIM1_CH1 0x0000002AU /*!< DMAMUX TIM1 CH1 request */
#define LL_DMAMUX_REQ_TIM1_CH2 0x0000002BU /*!< DMAMUX TIM1 CH2 request */
#define LL_DMAMUX_REQ_TIM1_CH3 0x0000002CU /*!< DMAMUX TIM1 CH3 request */
#define LL_DMAMUX_REQ_TIM1_CH4 0x0000002DU /*!< DMAMUX TIM1 CH4 request */
#define LL_DMAMUX_REQ_TIM1_UP 0x0000002EU /*!< DMAMUX TIM1 UP request */
#define LL_DMAMUX_REQ_TIM1_TRIG 0x0000002FU /*!< DMAMUX TIM1 TRIG request */
#define LL_DMAMUX_REQ_TIM1_COM 0x00000030U /*!< DMAMUX TIM1 COM request */
#define LL_DMAMUX_REQ_TIM8_CH1 0x00000031U /*!< DMAMUX TIM8 CH1 request */
#define LL_DMAMUX_REQ_TIM8_CH2 0x00000032U /*!< DMAMUX TIM8 CH2 request */
#define LL_DMAMUX_REQ_TIM8_CH3 0x00000033U /*!< DMAMUX TIM8 CH3 request */
#define LL_DMAMUX_REQ_TIM8_CH4 0x00000034U /*!< DMAMUX TIM8 CH4 request */
#define LL_DMAMUX_REQ_TIM8_UP 0x00000035U /*!< DMAMUX TIM8 UP request */
#define LL_DMAMUX_REQ_TIM8_TRIG 0x00000036U /*!< DMAMUX TIM8 TRIG request */
#define LL_DMAMUX_REQ_TIM8_COM 0x00000037U /*!< DMAMUX TIM8 COM request */
#define LL_DMAMUX_REQ_TIM2_CH1 0x00000038U /*!< DMAMUX TIM2 CH1 request */
#define LL_DMAMUX_REQ_TIM2_CH2 0x00000039U /*!< DMAMUX TIM2 CH2 request */
#define LL_DMAMUX_REQ_TIM2_CH3 0x0000003AU /*!< DMAMUX TIM2 CH3 request */
#define LL_DMAMUX_REQ_TIM2_CH4 0x0000003BU /*!< DMAMUX TIM2 CH4 request */
#define LL_DMAMUX_REQ_TIM2_UP 0x0000003CU /*!< DMAMUX TIM2 UP request */
#define LL_DMAMUX_REQ_TIM3_CH1 0x0000003DU /*!< DMAMUX TIM3 CH1 request */
#define LL_DMAMUX_REQ_TIM3_CH2 0x0000003EU /*!< DMAMUX TIM3 CH2 request */
#define LL_DMAMUX_REQ_TIM3_CH3 0x0000003FU /*!< DMAMUX TIM3 CH3 request */
#define LL_DMAMUX_REQ_TIM3_CH4 0x00000040U /*!< DMAMUX TIM3 CH4 request */
#define LL_DMAMUX_REQ_TIM3_UP 0x00000041U /*!< DMAMUX TIM3 UP request */
#define LL_DMAMUX_REQ_TIM3_TRIG 0x00000042U /*!< DMAMUX TIM3 TRIG request */
#define LL_DMAMUX_REQ_TIM4_CH1 0x00000043U /*!< DMAMUX TIM4 CH1 request */
#define LL_DMAMUX_REQ_TIM4_CH2 0x00000044U /*!< DMAMUX TIM4 CH2 request */
#define LL_DMAMUX_REQ_TIM4_CH3 0x00000045U /*!< DMAMUX TIM4 CH3 request */
#define LL_DMAMUX_REQ_TIM4_CH4 0x00000046U /*!< DMAMUX TIM4 CH4 request */
#define LL_DMAMUX_REQ_TIM4_UP 0x00000047U /*!< DMAMUX TIM4 UP request */
#define LL_DMAMUX_REQ_TIM5_CH1 0x00000048U /*!< DMAMUX TIM5 CH1 request */
#define LL_DMAMUX_REQ_TIM5_CH2 0x00000049U /*!< DMAMUX TIM5 CH2 request */
#define LL_DMAMUX_REQ_TIM5_CH3 0x0000004AU /*!< DMAMUX TIM5 CH3 request */
#define LL_DMAMUX_REQ_TIM5_CH4 0x0000004BU /*!< DMAMUX TIM5 CH4 request */
#define LL_DMAMUX_REQ_TIM5_UP 0x0000004CU /*!< DMAMUX TIM5 UP request */
#define LL_DMAMUX_REQ_TIM5_TRIG 0x0000004DU /*!< DMAMUX TIM5 TRIG request */
#define LL_DMAMUX_REQ_TIM15_CH1 0x0000004EU /*!< DMAMUX TIM15 CH1 request */
#define LL_DMAMUX_REQ_TIM15_UP 0x0000004FU /*!< DMAMUX TIM15 UP request */
#define LL_DMAMUX_REQ_TIM15_TRIG 0x00000050U /*!< DMAMUX TIM15 TRIG request */
#define LL_DMAMUX_REQ_TIM15_COM 0x00000051U /*!< DMAMUX TIM15 COM request */
#define LL_DMAMUX_REQ_TIM16_CH1 0x00000052U /*!< DMAMUX TIM16 CH1 request */
#define LL_DMAMUX_REQ_TIM16_UP 0x00000053U /*!< DMAMUX TIM16 UP request */
#define LL_DMAMUX_REQ_TIM17_CH1 0x00000054U /*!< DMAMUX TIM17 CH1 request */
#define LL_DMAMUX_REQ_TIM17_UP 0x00000055U /*!< DMAMUX TIM17 UP request */
#define LL_DMAMUX_REQ_TIM20_CH1 0x00000056U /*!< DMAMUX TIM20 CH1 request */
#define LL_DMAMUX_REQ_TIM20_CH2 0x00000057U /*!< DMAMUX TIM20 CH2 request */
#define LL_DMAMUX_REQ_TIM20_CH3 0x00000058U /*!< DMAMUX TIM20 CH3 request */
#define LL_DMAMUX_REQ_TIM20_CH4 0x00000059U /*!< DMAMUX TIM20 CH4 request */
#define LL_DMAMUX_REQ_TIM20_UP 0x0000005AU /*!< DMAMUX TIM20 UP request */
#define LL_DMAMUX_REQ_AES_IN 0x0000005BU /*!< DMAMUX AES_IN request */
#define LL_DMAMUX_REQ_AES_OUT 0x0000005CU /*!< DMAMUX AES_OUT request */
#define LL_DMAMUX_REQ_TIM20_TRIG 0x0000005DU /*!< DMAMUX TIM20 TRIG request */
#define LL_DMAMUX_REQ_TIM20_COM 0x0000005EU /*!< DMAMUX TIM20 COM request */
#define LL_DMAMUX_REQ_HRTIM1_M 0x0000005FU /*!< DMAMUX HRTIM M request */
#define LL_DMAMUX_REQ_HRTIM1_A 0x00000060U /*!< DMAMUX HRTIM A request */
#define LL_DMAMUX_REQ_HRTIM1_B 0x00000061U /*!< DMAMUX HRTIM B request */
#define LL_DMAMUX_REQ_HRTIM1_C 0x00000062U /*!< DMAMUX HRTIM C request */
#define LL_DMAMUX_REQ_HRTIM1_D 0x00000063U /*!< DMAMUX HRTIM D request */
#define LL_DMAMUX_REQ_HRTIM1_E 0x00000064U /*!< DMAMUX HRTIM E request */
#define LL_DMAMUX_REQ_HRTIM1_F 0x00000065U /*!< DMAMUX HRTIM F request */
#define LL_DMAMUX_REQ_DAC3_CH1 0x00000066U /*!< DMAMUX DAC3 CH1 request */
#define LL_DMAMUX_REQ_DAC3_CH2 0x00000067U /*!< DMAMUX DAC3 CH2 request */
#define LL_DMAMUX_REQ_DAC4_CH1 0x00000068U /*!< DMAMUX DAC4 CH1 request */
#define LL_DMAMUX_REQ_DAC4_CH2 0x00000069U /*!< DMAMUX DAC4 CH2 request */
#define LL_DMAMUX_REQ_SPI4_RX 0x0000006AU /*!< DMAMUX SPI4 RX request */
#define LL_DMAMUX_REQ_SPI4_TX 0x0000006BU /*!< DMAMUX SPI4 TX request */
#define LL_DMAMUX_REQ_SAI1_A 0x0000006CU /*!< DMAMUX SAI1 A request */
#define LL_DMAMUX_REQ_SAI1_B 0x0000006DU /*!< DMAMUX SAI1 B request */
#define LL_DMAMUX_REQ_FMAC_READ 0x0000006EU /*!< DMAMUX FMAC READ request */
#define LL_DMAMUX_REQ_FMAC_WRITE 0x0000006FU /*!< DMAMUX FMAC WRITE request */
#define LL_DMAMUX_REQ_CORDIC_READ 0x00000070U /*!< DMAMUX CORDIC READ request */
#define LL_DMAMUX_REQ_CORDIC_WRITE 0x00000071U /*!< DMAMUX CORDIC WRITE request*/
#define LL_DMAMUX_REQ_UCPD1_RX 0x00000072U /*!< DMAMUX USBPD1_RX request */
#define LL_DMAMUX_REQ_UCPD1_TX 0x00000073U /*!< DMAMUX USBPD1_TX request */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_CHANNEL DMAMUX Channel
* @{
*/
#define LL_DMAMUX_CHANNEL_0 0x00000000U /*!< DMAMUX Channel 0 connected to DMA1 Channel 1 */
#define LL_DMAMUX_CHANNEL_1 0x00000001U /*!< DMAMUX Channel 1 connected to DMA1 Channel 2 */
#define LL_DMAMUX_CHANNEL_2 0x00000002U /*!< DMAMUX Channel 2 connected to DMA1 Channel 3 */
#define LL_DMAMUX_CHANNEL_3 0x00000003U /*!< DMAMUX Channel 3 connected to DMA1 Channel 4 */
#define LL_DMAMUX_CHANNEL_4 0x00000004U /*!< DMAMUX Channel 4 connected to DMA1 Channel 5 */
#define LL_DMAMUX_CHANNEL_5 0x00000005U /*!< DMAMUX Channel 5 connected to DMA1 Channel 6 */
#define LL_DMAMUX_CHANNEL_6 0x00000006U /*!< DMAMUX Channel 6 connected to DMA1 Channel 7 */
#define LL_DMAMUX_CHANNEL_7 0x00000007U /*!< DMAMUX Channel 7 connected to DMA1 Channel 8 */
#define LL_DMAMUX_CHANNEL_8 0x00000008U /*!< DMAMUX Channel 8 connected to DMA2 Channel 1 */
#define LL_DMAMUX_CHANNEL_9 0x00000009U /*!< DMAMUX Channel 9 connected to DMA2 Channel 2 */
#define LL_DMAMUX_CHANNEL_10 0x0000000AU /*!< DMAMUX Channel 10 connected to DMA2 Channel 3 */
#define LL_DMAMUX_CHANNEL_11 0x0000000BU /*!< DMAMUX Channel 11 connected to DMA2 Channel 4 */
#define LL_DMAMUX_CHANNEL_12 0x0000000CU /*!< DMAMUX Channel 12 connected to DMA2 Channel 5 */
#define LL_DMAMUX_CHANNEL_13 0x0000000DU /*!< DMAMUX Channel 13 connected to DMA2 Channel 6 */
#define LL_DMAMUX_CHANNEL_14 0x0000000EU /*!< DMAMUX Channel 14 connected to DMA2 Channel 7 */
#define LL_DMAMUX_CHANNEL_15 0x0000000FU /*!< DMAMUX Channel 15 connected to DMA2 Channel 8 */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_SYNC_NO Synchronization Signal Polarity
* @{
*/
#define LL_DMAMUX_SYNC_NO_EVENT 0x00000000U /*!< All requests are blocked */
#define LL_DMAMUX_SYNC_POL_RISING DMAMUX_CxCR_SPOL_0 /*!< Synchronization on event on rising edge */
#define LL_DMAMUX_SYNC_POL_FALLING DMAMUX_CxCR_SPOL_1 /*!< Synchronization on event on falling edge */
#define LL_DMAMUX_SYNC_POL_RISING_FALLING (DMAMUX_CxCR_SPOL_0 | DMAMUX_CxCR_SPOL_1) /*!< Synchronization on event on rising and falling edge */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_SYNC_EVT Synchronization Signal Event
* @{
*/
#define LL_DMAMUX_SYNC_EXTI_LINE0 0x00000000U /*!< Synchronization signal from EXTI Line0 */
#define LL_DMAMUX_SYNC_EXTI_LINE1 DMAMUX_CxCR_SYNC_ID_0 /*!< Synchronization signal from EXTI Line1 */
#define LL_DMAMUX_SYNC_EXTI_LINE2 DMAMUX_CxCR_SYNC_ID_1 /*!< Synchronization signal from EXTI Line2 */
#define LL_DMAMUX_SYNC_EXTI_LINE3 (DMAMUX_CxCR_SYNC_ID_1 |DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from EXTI Line3 */
#define LL_DMAMUX_SYNC_EXTI_LINE4 DMAMUX_CxCR_SYNC_ID_2 /*!< Synchronization signal from EXTI Line4 */
#define LL_DMAMUX_SYNC_EXTI_LINE5 (DMAMUX_CxCR_SYNC_ID_2 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from EXTI Line5 */
#define LL_DMAMUX_SYNC_EXTI_LINE6 (DMAMUX_CxCR_SYNC_ID_2 | DMAMUX_CxCR_SYNC_ID_1) /*!< Synchronization signal from EXTI Line6 */
#define LL_DMAMUX_SYNC_EXTI_LINE7 (DMAMUX_CxCR_SYNC_ID_2 | DMAMUX_CxCR_SYNC_ID_1 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from EXTI Line7 */
#define LL_DMAMUX_SYNC_EXTI_LINE8 DMAMUX_CxCR_SYNC_ID_3 /*!< Synchronization signal from EXTI Line8 */
#define LL_DMAMUX_SYNC_EXTI_LINE9 (DMAMUX_CxCR_SYNC_ID_3 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from EXTI Line9 */
#define LL_DMAMUX_SYNC_EXTI_LINE10 (DMAMUX_CxCR_SYNC_ID_3 | DMAMUX_CxCR_SYNC_ID_1) /*!< Synchronization signal from EXTI Line10 */
#define LL_DMAMUX_SYNC_EXTI_LINE11 (DMAMUX_CxCR_SYNC_ID_3 | DMAMUX_CxCR_SYNC_ID_1 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from EXTI Line11 */
#define LL_DMAMUX_SYNC_EXTI_LINE12 (DMAMUX_CxCR_SYNC_ID_3 | DMAMUX_CxCR_SYNC_ID_2) /*!< Synchronization signal from EXTI Line12 */
#define LL_DMAMUX_SYNC_EXTI_LINE13 (DMAMUX_CxCR_SYNC_ID_3 | DMAMUX_CxCR_SYNC_ID_2 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from EXTI Line13 */
#define LL_DMAMUX_SYNC_EXTI_LINE14 (DMAMUX_CxCR_SYNC_ID_3 | DMAMUX_CxCR_SYNC_ID_2 | DMAMUX_CxCR_SYNC_ID_1) /*!< Synchronization signal from EXTI Line14 */
#define LL_DMAMUX_SYNC_EXTI_LINE15 (DMAMUX_CxCR_SYNC_ID_3 | DMAMUX_CxCR_SYNC_ID_2 | DMAMUX_CxCR_SYNC_ID_1 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from EXTI Line15 */
#define LL_DMAMUX_SYNC_DMAMUX_CH0 DMAMUX_CxCR_SYNC_ID_4 /*!< Synchronization signal from DMAMUX channel0 Event */
#define LL_DMAMUX_SYNC_DMAMUX_CH1 (DMAMUX_CxCR_SYNC_ID_4 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from DMAMUX channel1 Event */
#define LL_DMAMUX_SYNC_DMAMUX_CH2 (DMAMUX_CxCR_SYNC_ID_4 | DMAMUX_CxCR_SYNC_ID_1) /*!< Synchronization signal from DMAMUX channel2 Event */
#define LL_DMAMUX_SYNC_DMAMUX_CH3 (DMAMUX_CxCR_SYNC_ID_4 | DMAMUX_CxCR_SYNC_ID_1 | DMAMUX_CxCR_SYNC_ID_0) /*!< Synchronization signal from DMAMUX channel3 Event */
#define LL_DMAMUX_SYNC_LPTIM1_OUT (DMAMUX_CxCR_SYNC_ID_4 | DMAMUX_CxCR_SYNC_ID_2) /*!< Synchronization signal from LPTIM1 Output */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_REQUEST_GENERATOR Request Generator Channel
* @{
*/
#define LL_DMAMUX_REQ_GEN_0 0x00000000U
#define LL_DMAMUX_REQ_GEN_1 0x00000001U
#define LL_DMAMUX_REQ_GEN_2 0x00000002U
#define LL_DMAMUX_REQ_GEN_3 0x00000003U
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_REQUEST_GEN_POLARITY External Request Signal Generation Polarity
* @{
*/
#define LL_DMAMUX_REQ_GEN_NO_EVENT 0x00000000U /*!< No external DMA request generation */
#define LL_DMAMUX_REQ_GEN_POL_RISING DMAMUX_RGxCR_GPOL_0 /*!< External DMA request generation on event on rising edge */
#define LL_DMAMUX_REQ_GEN_POL_FALLING DMAMUX_RGxCR_GPOL_1 /*!< External DMA request generation on event on falling edge */
#define LL_DMAMUX_REQ_GEN_POL_RISING_FALLING (DMAMUX_RGxCR_GPOL_0 | DMAMUX_RGxCR_GPOL_1) /*!< External DMA request generation on rising and falling edge */
/**
* @}
*/
/** @defgroup DMAMUX_LL_EC_REQUEST_GEN External Request Signal Generation
* @{
*/
#define LL_DMAMUX_REQ_GEN_EXTI_LINE0 0x00000000U /*!< Request signal generation from EXTI Line0 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE1 DMAMUX_RGxCR_SIG_ID_0 /*!< Request signal generation from EXTI Line1 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE2 DMAMUX_RGxCR_SIG_ID_1 /*!< Request signal generation from EXTI Line2 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE3 (DMAMUX_RGxCR_SIG_ID_1 |DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from EXTI Line3 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE4 DMAMUX_RGxCR_SIG_ID_2 /*!< Request signal generation from EXTI Line4 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE5 (DMAMUX_RGxCR_SIG_ID_2 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from EXTI Line5 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE6 (DMAMUX_RGxCR_SIG_ID_2 | DMAMUX_RGxCR_SIG_ID_1) /*!< Request signal generation from EXTI Line6 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE7 (DMAMUX_RGxCR_SIG_ID_2 | DMAMUX_RGxCR_SIG_ID_1 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from EXTI Line7 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE8 DMAMUX_RGxCR_SIG_ID_3 /*!< Request signal generation from EXTI Line8 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE9 (DMAMUX_RGxCR_SIG_ID_3 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from EXTI Line9 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE10 (DMAMUX_RGxCR_SIG_ID_3 | DMAMUX_RGxCR_SIG_ID_1) /*!< Request signal generation from EXTI Line10 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE11 (DMAMUX_RGxCR_SIG_ID_3 | DMAMUX_RGxCR_SIG_ID_1 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from EXTI Line11 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE12 (DMAMUX_RGxCR_SIG_ID_3 | DMAMUX_RGxCR_SIG_ID_2) /*!< Request signal generation from EXTI Line12 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE13 (DMAMUX_RGxCR_SIG_ID_3 | DMAMUX_RGxCR_SIG_ID_2 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from EXTI Line13 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE14 (DMAMUX_RGxCR_SIG_ID_3 | DMAMUX_RGxCR_SIG_ID_2 | DMAMUX_RGxCR_SIG_ID_1) /*!< Request signal generation from EXTI Line14 */
#define LL_DMAMUX_REQ_GEN_EXTI_LINE15 (DMAMUX_RGxCR_SIG_ID_3 | DMAMUX_RGxCR_SIG_ID_2 | DMAMUX_RGxCR_SIG_ID_1 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from EXTI Line15 */
#define LL_DMAMUX_REQ_GEN_DMAMUX_CH0 DMAMUX_RGxCR_SIG_ID_4 /*!< Request signal generation from DMAMUX channel0 Event */
#define LL_DMAMUX_REQ_GEN_DMAMUX_CH1 (DMAMUX_RGxCR_SIG_ID_4 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from DMAMUX channel1 Event */
#define LL_DMAMUX_REQ_GEN_DMAMUX_CH2 (DMAMUX_RGxCR_SIG_ID_4 | DMAMUX_RGxCR_SIG_ID_1) /*!< Request signal generation from DMAMUX channel2 Event */
#define LL_DMAMUX_REQ_GEN_DMAMUX_CH3 (DMAMUX_RGxCR_SIG_ID_4 | DMAMUX_RGxCR_SIG_ID_1 | DMAMUX_RGxCR_SIG_ID_0) /*!< Request signal generation from DMAMUX channel3 Event */
#define LL_DMAMUX_REQ_GEN_LPTIM1_OUT (DMAMUX_RGxCR_SIG_ID_4 | DMAMUX_RGxCR_SIG_ID_2) /*!< Request signal generation from LPTIM1 Output */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup DMAMUX_LL_Exported_Macros DMAMUX Exported Macros
* @{
*/
/** @defgroup DMAMUX_LL_EM_WRITE_READ Common Write and read registers macros
* @{
*/
/**
* @brief Write a value in DMAMUX register
* @param __INSTANCE__ DMAMUX Instance
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_DMAMUX_WriteReg(__INSTANCE__, __REG__, __VALUE__) WRITE_REG(__INSTANCE__->__REG__, (__VALUE__))
/**
* @brief Read a value in DMAMUX register
* @param __INSTANCE__ DMAMUX Instance
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_DMAMUX_ReadReg(__INSTANCE__, __REG__) READ_REG(__INSTANCE__->__REG__)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup DMAMUX_LL_Exported_Functions DMAMUX Exported Functions
* @{
*/
/** @defgroup DMAMUX_LL_EF_Configuration Configuration
* @{
*/
/**
* @brief Set DMAMUX request ID for DMAMUX Channel x.
* @note DMAMUX channel 0 to 7 are mapped to DMA1 channel 1 to 8.
* DMAMUX channel 8 to 15 are mapped to DMA2 channel 1 to 8.
* @rmtoll CxCR DMAREQ_ID LL_DMAMUX_SetRequestID
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @param Request This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_MEM2MEM
* @arg @ref LL_DMAMUX_REQ_GENERATOR0
* @arg @ref LL_DMAMUX_REQ_GENERATOR1
* @arg @ref LL_DMAMUX_REQ_GENERATOR2
* @arg @ref LL_DMAMUX_REQ_GENERATOR3
* @arg @ref LL_DMAMUX_REQ_ADC1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM6_UP
* @arg @ref LL_DMAMUX_REQ_TIM7_UP
* @arg @ref LL_DMAMUX_REQ_SPI1_RX
* @arg @ref LL_DMAMUX_REQ_SPI1_TX
* @arg @ref LL_DMAMUX_REQ_SPI2_RX
* @arg @ref LL_DMAMUX_REQ_SPI2_TX
* @arg @ref LL_DMAMUX_REQ_SPI3_RX
* @arg @ref LL_DMAMUX_REQ_SPI3_TX
* @arg @ref LL_DMAMUX_REQ_I2C1_RX
* @arg @ref LL_DMAMUX_REQ_I2C1_TX
* @arg @ref LL_DMAMUX_REQ_I2C2_RX
* @arg @ref LL_DMAMUX_REQ_I2C2_TX
* @arg @ref LL_DMAMUX_REQ_I2C3_RX
* @arg @ref LL_DMAMUX_REQ_I2C3_TX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_RX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_TX
* @arg @ref LL_DMAMUX_REQ_USART1_RX
* @arg @ref LL_DMAMUX_REQ_USART1_TX
* @arg @ref LL_DMAMUX_REQ_USART2_RX
* @arg @ref LL_DMAMUX_REQ_USART2_TX
* @arg @ref LL_DMAMUX_REQ_USART3_RX
* @arg @ref LL_DMAMUX_REQ_USART3_TX
* @arg @ref LL_DMAMUX_REQ_UART4_RX
* @arg @ref LL_DMAMUX_REQ_UART4_TX
* @arg @ref LL_DMAMUX_REQ_UART5_RX (*)
* @arg @ref LL_DMAMUX_REQ_UART5_TX (*)
* @arg @ref LL_DMAMUX_REQ_LPUART1_RX
* @arg @ref LL_DMAMUX_REQ_LPUART1_TX
* @arg @ref LL_DMAMUX_REQ_ADC2
* @arg @ref LL_DMAMUX_REQ_ADC3 (*)
* @arg @ref LL_DMAMUX_REQ_ADC4 (*)
* @arg @ref LL_DMAMUX_REQ_ADC5 (*)
* @arg @ref LL_DMAMUX_REQ_QSPI (*)
* @arg @ref LL_DMAMUX_REQ_DAC2_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM1_CH1
* @arg @ref LL_DMAMUX_REQ_TIM1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM1_CH3
* @arg @ref LL_DMAMUX_REQ_TIM1_CH4
* @arg @ref LL_DMAMUX_REQ_TIM1_UP
* @arg @ref LL_DMAMUX_REQ_TIM1_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM1_COM
* @arg @ref LL_DMAMUX_REQ_TIM8_CH1
* @arg @ref LL_DMAMUX_REQ_TIM8_CH2
* @arg @ref LL_DMAMUX_REQ_TIM8_CH3
* @arg @ref LL_DMAMUX_REQ_TIM8_CH4
* @arg @ref LL_DMAMUX_REQ_TIM8_UP
* @arg @ref LL_DMAMUX_REQ_TIM8_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM8_COM
* @arg @ref LL_DMAMUX_REQ_TIM2_CH1
* @arg @ref LL_DMAMUX_REQ_TIM2_CH2
* @arg @ref LL_DMAMUX_REQ_TIM2_CH3
* @arg @ref LL_DMAMUX_REQ_TIM2_CH4
* @arg @ref LL_DMAMUX_REQ_TIM2_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_CH1
* @arg @ref LL_DMAMUX_REQ_TIM3_CH2
* @arg @ref LL_DMAMUX_REQ_TIM3_CH3
* @arg @ref LL_DMAMUX_REQ_TIM3_CH4
* @arg @ref LL_DMAMUX_REQ_TIM3_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM4_CH1
* @arg @ref LL_DMAMUX_REQ_TIM4_CH2
* @arg @ref LL_DMAMUX_REQ_TIM4_CH3
* @arg @ref LL_DMAMUX_REQ_TIM4_CH4
* @arg @ref LL_DMAMUX_REQ_TIM4_UP
* @arg @ref LL_DMAMUX_REQ_TIM5_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_UP (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM15_CH1
* @arg @ref LL_DMAMUX_REQ_TIM15_UP
* @arg @ref LL_DMAMUX_REQ_TIM15_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM15_COM
* @arg @ref LL_DMAMUX_REQ_TIM16_CH1
* @arg @ref LL_DMAMUX_REQ_TIM16_UP
* @arg @ref LL_DMAMUX_REQ_TIM17_CH1
* @arg @ref LL_DMAMUX_REQ_TIM17_UP
* @arg @ref LL_DMAMUX_REQ_TIM20_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_UP (*)
* @arg @ref LL_DMAMUX_REQ_AES_IN
* @arg @ref LL_DMAMUX_REQ_AES_OUT
* @arg @ref LL_DMAMUX_REQ_TIM20_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_COM (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_M (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_A (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_B (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_C (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_D (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_E (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_F (*)
* @arg @ref LL_DMAMUX_REQ_DAC3_CH1
* @arg @ref LL_DMAMUX_REQ_DAC3_CH2
* @arg @ref LL_DMAMUX_REQ_DAC4_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_DAC4_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_RX (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_TX (*)
* @arg @ref LL_DMAMUX_REQ_SAI1_A
* @arg @ref LL_DMAMUX_REQ_SAI1_B
* @arg @ref LL_DMAMUX_REQ_FMAC_WRITE
* @arg @ref LL_DMAMUX_REQ_FMAC_WRITE
* @arg @ref LL_DMAMUX_REQ_CORDIC_WRITE
* @arg @ref LL_DMAMUX_REQ_CORDIC_READ
* @arg @ref LL_DMAMUX_REQ_UCPD1_RX
* @arg @ref LL_DMAMUX_REQ_UCPD1_TX
* (*) Not on all G4 devices
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_SetRequestID(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel, uint32_t Request)
{
(void)(DMAMUXx);
MODIFY_REG((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_DMAREQ_ID, Request);
}
/**
* @brief Get DMAMUX request ID for DMAMUX Channel x.
* @note DMAMUX channel 0 to 7 are mapped to DMA1 channel 1 to 8.
* DMAMUX channel 8 to 15 are mapped to DMA2 channel 1 to 8.
* @rmtoll CxCR DMAREQ_ID LL_DMAMUX_GetRequestID
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* (*) Not on all G4 devices
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_MEM2MEM
* @arg @ref LL_DMAMUX_REQ_GENERATOR0
* @arg @ref LL_DMAMUX_REQ_GENERATOR0
* @arg @ref LL_DMAMUX_REQ_GENERATOR1
* @arg @ref LL_DMAMUX_REQ_GENERATOR2
* @arg @ref LL_DMAMUX_REQ_GENERATOR3
* @arg @ref LL_DMAMUX_REQ_ADC1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH1
* @arg @ref LL_DMAMUX_REQ_DAC1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM6_UP
* @arg @ref LL_DMAMUX_REQ_TIM7_UP
* @arg @ref LL_DMAMUX_REQ_SPI1_RX
* @arg @ref LL_DMAMUX_REQ_SPI1_TX
* @arg @ref LL_DMAMUX_REQ_SPI2_RX
* @arg @ref LL_DMAMUX_REQ_SPI2_TX
* @arg @ref LL_DMAMUX_REQ_SPI3_RX
* @arg @ref LL_DMAMUX_REQ_SPI3_TX
* @arg @ref LL_DMAMUX_REQ_I2C1_RX
* @arg @ref LL_DMAMUX_REQ_I2C1_TX
* @arg @ref LL_DMAMUX_REQ_I2C2_RX
* @arg @ref LL_DMAMUX_REQ_I2C2_TX
* @arg @ref LL_DMAMUX_REQ_I2C3_RX
* @arg @ref LL_DMAMUX_REQ_I2C3_TX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_RX (*)
* @arg @ref LL_DMAMUX_REQ_I2C4_TX
* @arg @ref LL_DMAMUX_REQ_USART1_RX
* @arg @ref LL_DMAMUX_REQ_USART1_TX
* @arg @ref LL_DMAMUX_REQ_USART2_RX
* @arg @ref LL_DMAMUX_REQ_USART2_TX
* @arg @ref LL_DMAMUX_REQ_USART3_RX
* @arg @ref LL_DMAMUX_REQ_USART3_TX
* @arg @ref LL_DMAMUX_REQ_UART4_RX
* @arg @ref LL_DMAMUX_REQ_UART4_TX
* @arg @ref LL_DMAMUX_REQ_UART5_RX (*)
* @arg @ref LL_DMAMUX_REQ_UART5_TX (*)
* @arg @ref LL_DMAMUX_REQ_LPUART1_RX
* @arg @ref LL_DMAMUX_REQ_LPUART1_TX
* @arg @ref LL_DMAMUX_REQ_ADC2
* @arg @ref LL_DMAMUX_REQ_ADC3 (*)
* @arg @ref LL_DMAMUX_REQ_ADC4 (*)
* @arg @ref LL_DMAMUX_REQ_ADC5 (*)
* @arg @ref LL_DMAMUX_REQ_QSPI (*)
* @arg @ref LL_DMAMUX_REQ_DAC2_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM1_CH1
* @arg @ref LL_DMAMUX_REQ_TIM1_CH2
* @arg @ref LL_DMAMUX_REQ_TIM1_CH3
* @arg @ref LL_DMAMUX_REQ_TIM1_CH4
* @arg @ref LL_DMAMUX_REQ_TIM1_UP
* @arg @ref LL_DMAMUX_REQ_TIM1_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM1_COM
* @arg @ref LL_DMAMUX_REQ_TIM8_CH1
* @arg @ref LL_DMAMUX_REQ_TIM8_CH2
* @arg @ref LL_DMAMUX_REQ_TIM8_CH3
* @arg @ref LL_DMAMUX_REQ_TIM8_CH4
* @arg @ref LL_DMAMUX_REQ_TIM8_UP
* @arg @ref LL_DMAMUX_REQ_TIM8_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM8_COM
* @arg @ref LL_DMAMUX_REQ_TIM2_CH1
* @arg @ref LL_DMAMUX_REQ_TIM2_CH2
* @arg @ref LL_DMAMUX_REQ_TIM2_CH3
* @arg @ref LL_DMAMUX_REQ_TIM2_CH4
* @arg @ref LL_DMAMUX_REQ_TIM2_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_CH1
* @arg @ref LL_DMAMUX_REQ_TIM3_CH2
* @arg @ref LL_DMAMUX_REQ_TIM3_CH3
* @arg @ref LL_DMAMUX_REQ_TIM3_CH4
* @arg @ref LL_DMAMUX_REQ_TIM3_UP
* @arg @ref LL_DMAMUX_REQ_TIM3_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM4_CH1
* @arg @ref LL_DMAMUX_REQ_TIM4_CH2
* @arg @ref LL_DMAMUX_REQ_TIM4_CH3
* @arg @ref LL_DMAMUX_REQ_TIM4_CH4
* @arg @ref LL_DMAMUX_REQ_TIM4_UP
* @arg @ref LL_DMAMUX_REQ_TIM5_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_UP (*)
* @arg @ref LL_DMAMUX_REQ_TIM5_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM15_CH1
* @arg @ref LL_DMAMUX_REQ_TIM15_UP
* @arg @ref LL_DMAMUX_REQ_TIM15_TRIG
* @arg @ref LL_DMAMUX_REQ_TIM15_COM
* @arg @ref LL_DMAMUX_REQ_TIM16_CH1
* @arg @ref LL_DMAMUX_REQ_TIM16_UP
* @arg @ref LL_DMAMUX_REQ_TIM17_CH1
* @arg @ref LL_DMAMUX_REQ_TIM17_UP
* @arg @ref LL_DMAMUX_REQ_TIM20_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH3 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_CH4 (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_UP (*)
* @arg @ref LL_DMAMUX_REQ_AES_IN
* @arg @ref LL_DMAMUX_REQ_AES_OUT
* @arg @ref LL_DMAMUX_REQ_TIM20_TRIG (*)
* @arg @ref LL_DMAMUX_REQ_TIM20_COM (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_M (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_A (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_B (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_C (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_D (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_E (*)
* @arg @ref LL_DMAMUX_REQ_HRTIM1_F (*)
* @arg @ref LL_DMAMUX_REQ_DAC3_CH1
* @arg @ref LL_DMAMUX_REQ_DAC3_CH2
* @arg @ref LL_DMAMUX_REQ_DAC4_CH1 (*)
* @arg @ref LL_DMAMUX_REQ_DAC4_CH2 (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_RX (*)
* @arg @ref LL_DMAMUX_REQ_SPI4_TX (*)
* @arg @ref LL_DMAMUX_REQ_SAI1_A
* @arg @ref LL_DMAMUX_REQ_SAI1_B
* @arg @ref LL_DMAMUX_REQ_FMAC_WRITE
* @arg @ref LL_DMAMUX_REQ_FMAC_WRITE
* @arg @ref LL_DMAMUX_REQ_CORDIC_WRITE
* @arg @ref LL_DMAMUX_REQ_CORDIC_READ
* @arg @ref LL_DMAMUX_REQ_UCPD1_RX
* @arg @ref LL_DMAMUX_REQ_UCPD1_TX
* (*) Not on all G4 devices
*/
__STATIC_INLINE uint32_t LL_DMAMUX_GetRequestID(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
return (uint32_t)(READ_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_DMAREQ_ID));
}
/**
* @brief Set the number of DMA request that will be autorized after a synchronization event and/or the number of DMA request needed to generate an event.
* @rmtoll CxCR NBREQ LL_DMAMUX_SetSyncRequestNb
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @param RequestNb This parameter must be a value between Min_Data = 1 and Max_Data = 32.
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_SetSyncRequestNb(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel, uint32_t RequestNb)
{
(void)(DMAMUXx);
MODIFY_REG((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_NBREQ, ((RequestNb - 1U) << DMAMUX_CxCR_NBREQ_Pos));
}
/**
* @brief Get the number of DMA request that will be autorized after a synchronization event and/or the number of DMA request needed to generate an event.
* @rmtoll CxCR NBREQ LL_DMAMUX_GetSyncRequestNb
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval Between Min_Data = 1 and Max_Data = 32
*/
__STATIC_INLINE uint32_t LL_DMAMUX_GetSyncRequestNb(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
return (uint32_t)(((READ_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_NBREQ)) >> DMAMUX_CxCR_NBREQ_Pos) + 1U);
}
/**
* @brief Set the polarity of the signal on which the DMA request is synchronized.
* @rmtoll CxCR SPOL LL_DMAMUX_SetSyncPolarity
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_SYNC_NO_EVENT
* @arg @ref LL_DMAMUX_SYNC_POL_RISING
* @arg @ref LL_DMAMUX_SYNC_POL_FALLING
* @arg @ref LL_DMAMUX_SYNC_POL_RISING_FALLING
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_SetSyncPolarity(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel, uint32_t Polarity)
{
(void)(DMAMUXx);
MODIFY_REG((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SPOL, Polarity);
}
/**
* @brief Get the polarity of the signal on which the DMA request is synchronized.
* @rmtoll CxCR SPOL LL_DMAMUX_GetSyncPolarity
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMAMUX_SYNC_NO_EVENT
* @arg @ref LL_DMAMUX_SYNC_POL_RISING
* @arg @ref LL_DMAMUX_SYNC_POL_FALLING
* @arg @ref LL_DMAMUX_SYNC_POL_RISING_FALLING
*/
__STATIC_INLINE uint32_t LL_DMAMUX_GetSyncPolarity(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
return (uint32_t)(READ_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SPOL));
}
/**
* @brief Enable the Event Generation on DMAMUX channel x.
* @rmtoll CxCR EGE LL_DMAMUX_EnableEventGeneration
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_EnableEventGeneration(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
SET_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_EGE);
}
/**
* @brief Disable the Event Generation on DMAMUX channel x.
* @rmtoll CxCR EGE LL_DMAMUX_DisableEventGeneration
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_DisableEventGeneration(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
CLEAR_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_EGE);
}
/**
* @brief Check if the Event Generation on DMAMUX channel x is enabled or disabled.
* @rmtoll CxCR EGE LL_DMAMUX_IsEnabledEventGeneration
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsEnabledEventGeneration(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
return ((READ_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_EGE) == (DMAMUX_CxCR_EGE))? 1UL : 0UL);
}
/**
* @brief Enable the synchronization mode.
* @rmtoll CxCR SE LL_DMAMUX_EnableSync
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_EnableSync(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
SET_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SE);
}
/**
* @brief Disable the synchronization mode.
* @rmtoll CxCR SE LL_DMAMUX_DisableSync
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_DisableSync(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
CLEAR_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SE);
}
/**
* @brief Check if the synchronization mode is enabled or disabled.
* @rmtoll CxCR SE LL_DMAMUX_IsEnabledSync
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsEnabledSync(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
return ((READ_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SE) == (DMAMUX_CxCR_SE))? 1UL : 0UL);
}
/**
* @brief Set DMAMUX synchronization ID on DMAMUX Channel x.
* @rmtoll CxCR SYNC_ID LL_DMAMUX_SetSyncID
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @param SyncID This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE0
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE1
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE2
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE3
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE4
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE5
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE6
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE7
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE8
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE9
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE10
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE11
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE12
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE13
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE14
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE15
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH0
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH1
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH2
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH3
* @arg @ref LL_DMAMUX_SYNC_LPTIM1_OUT
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_SetSyncID(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel, uint32_t SyncID)
{
(void)(DMAMUXx);
MODIFY_REG((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SYNC_ID, SyncID);
}
/**
* @brief Get DMAMUX synchronization ID on DMAMUX Channel x.
* @rmtoll CxCR SYNC_ID LL_DMAMUX_GetSyncID
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE0
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE1
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE2
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE3
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE4
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE5
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE6
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE7
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE8
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE9
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE10
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE11
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE12
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE13
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE14
* @arg @ref LL_DMAMUX_SYNC_EXTI_LINE15
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH0
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH1
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH2
* @arg @ref LL_DMAMUX_SYNC_DMAMUX_CH3
* @arg @ref LL_DMAMUX_SYNC_LPTIM1_OUT
*/
__STATIC_INLINE uint32_t LL_DMAMUX_GetSyncID(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
return (uint32_t)(READ_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SYNC_ID));
}
/**
* @brief Enable the Request Generator.
* @rmtoll RGxCR GE LL_DMAMUX_EnableRequestGen
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_EnableRequestGen(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
(void)(DMAMUXx);
SET_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE * (RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_GE);
}
/**
* @brief Disable the Request Generator.
* @rmtoll RGxCR GE LL_DMAMUX_DisableRequestGen
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_DisableRequestGen(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
(void)(DMAMUXx);
CLEAR_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE * (RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_GE);
}
/**
* @brief Check if the Request Generator is enabled or disabled.
* @rmtoll RGxCR GE LL_DMAMUX_IsEnabledRequestGen
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsEnabledRequestGen(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
(void)(DMAMUXx);
return ((READ_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE * (RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_GE) == (DMAMUX_RGxCR_GE))? 1UL : 0UL);
}
/**
* @brief Set the polarity of the signal on which the DMA request is generated.
* @rmtoll RGxCR GPOL LL_DMAMUX_SetRequestGenPolarity
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @param Polarity This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_NO_EVENT
* @arg @ref LL_DMAMUX_REQ_GEN_POL_RISING
* @arg @ref LL_DMAMUX_REQ_GEN_POL_FALLING
* @arg @ref LL_DMAMUX_REQ_GEN_POL_RISING_FALLING
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_SetRequestGenPolarity(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel,
uint32_t Polarity)
{
UNUSED(DMAMUXx);
MODIFY_REG(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_GPOL, Polarity);
}
/**
* @brief Get the polarity of the signal on which the DMA request is generated.
* @rmtoll RGxCR GPOL LL_DMAMUX_GetRequestGenPolarity
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_NO_EVENT
* @arg @ref LL_DMAMUX_REQ_GEN_POL_RISING
* @arg @ref LL_DMAMUX_REQ_GEN_POL_FALLING
* @arg @ref LL_DMAMUX_REQ_GEN_POL_RISING_FALLING
*/
__STATIC_INLINE uint32_t LL_DMAMUX_GetRequestGenPolarity(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
UNUSED(DMAMUXx);
return (READ_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_GPOL));
}
/**
* @brief Set the number of DMA request that will be autorized after a generation event.
* @note This field can only be written when Generator is disabled.
* @rmtoll RGxCR GNBREQ LL_DMAMUX_SetGenRequestNb
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @param RequestNb This parameter must be a value between Min_Data = 1 and Max_Data = 32.
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_SetGenRequestNb(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel,
uint32_t RequestNb)
{
UNUSED(DMAMUXx);
MODIFY_REG(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_GNBREQ, (RequestNb - 1U) << DMAMUX_RGxCR_GNBREQ_Pos);
}
/**
* @brief Get the number of DMA request that will be autorized after a generation event.
* @rmtoll RGxCR GNBREQ LL_DMAMUX_GetGenRequestNb
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval Between Min_Data = 1 and Max_Data = 32
*/
__STATIC_INLINE uint32_t LL_DMAMUX_GetGenRequestNb(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
UNUSED(DMAMUXx);
return ((READ_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_GNBREQ) >> DMAMUX_RGxCR_GNBREQ_Pos) + 1U);
}
/**
* @brief Set DMAMUX external Request Signal ID on DMAMUX Request Generation Trigger Event Channel x.
* @rmtoll RGxCR SIG_ID LL_DMAMUX_SetRequestSignalID
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @param RequestSignalID This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE0
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE1
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE2
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE3
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE4
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE5
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE6
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE7
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE8
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE9
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE10
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE11
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE12
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE13
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE14
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE15
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH0
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH1
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH2
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH3
* @arg @ref LL_DMAMUX_REQ_GEN_LPTIM1_OUT
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_SetRequestSignalID(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel,
uint32_t RequestSignalID)
{
UNUSED(DMAMUXx);
MODIFY_REG(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_SIG_ID, RequestSignalID);
}
/**
* @brief Get DMAMUX external Request Signal ID set on DMAMUX Channel x.
* @rmtoll RGxCR SIG_ID LL_DMAMUX_GetRequestSignalID
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval Returned value can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE0
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE1
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE2
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE3
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE4
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE5
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE6
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE7
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE8
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE9
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE10
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE11
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE12
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE13
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE14
* @arg @ref LL_DMAMUX_REQ_GEN_EXTI_LINE15
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH0
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH1
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH2
* @arg @ref LL_DMAMUX_REQ_GEN_DMAMUX_CH3
* @arg @ref LL_DMAMUX_REQ_GEN_LPTIM1_OUT
*/
__STATIC_INLINE uint32_t LL_DMAMUX_GetRequestSignalID(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
UNUSED(DMAMUXx);
return (READ_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_SIG_ID));
}
/**
* @}
*/
/** @defgroup DMAMUX_LL_EF_FLAG_Management FLAG_Management
* @{
*/
/**
* @brief Get Synchronization Event Overrun Flag Channel 0.
* @rmtoll CSR SOF0 LL_DMAMUX_IsActiveFlag_SO0
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO0(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF0) == (DMAMUX_CSR_SOF0)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 1.
* @rmtoll CSR SOF1 LL_DMAMUX_IsActiveFlag_SO1
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO1(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF1) == (DMAMUX_CSR_SOF1)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 2.
* @rmtoll CSR SOF2 LL_DMAMUX_IsActiveFlag_SO2
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO2(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF2) == (DMAMUX_CSR_SOF2)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 3.
* @rmtoll CSR SOF3 LL_DMAMUX_IsActiveFlag_SO3
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO3(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF3) == (DMAMUX_CSR_SOF3)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 4.
* @rmtoll CSR SOF4 LL_DMAMUX_IsActiveFlag_SO4
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO4(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF4) == (DMAMUX_CSR_SOF4)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 5.
* @rmtoll CSR SOF5 LL_DMAMUX_IsActiveFlag_SO5
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO5(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF5) == (DMAMUX_CSR_SOF5)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 6.
* @rmtoll CSR SOF6 LL_DMAMUX_IsActiveFlag_SO6
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO6(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF6) == (DMAMUX_CSR_SOF6)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 7.
* @rmtoll CSR SOF7 LL_DMAMUX_IsActiveFlag_SO7
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO7(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF7) == (DMAMUX_CSR_SOF7)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 8.
* @rmtoll CSR SOF8 LL_DMAMUX_IsActiveFlag_SO8
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO8(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF8) == (DMAMUX_CSR_SOF8)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 9.
* @rmtoll CSR SOF9 LL_DMAMUX_IsActiveFlag_SO9
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO9(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF9) == (DMAMUX_CSR_SOF9)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 10.
* @rmtoll CSR SOF10 LL_DMAMUX_IsActiveFlag_SO10
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO10(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF10) == (DMAMUX_CSR_SOF10)) ? 1UL : 0UL);
}
/**
* @brief Get Synchronization Event Overrun Flag Channel 11.
* @rmtoll CSR SOF11 LL_DMAMUX_IsActiveFlag_SO11
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO11(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF11) == (DMAMUX_CSR_SOF11)) ? 1UL : 0UL);
}
#if defined (DMAMUX_CSR_SOF12)
/**
* @brief Get Synchronization Event Overrun Flag Channel 12.
* @rmtoll CSR SOF12 LL_DMAMUX_IsActiveFlag_SO12
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO12(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF12) == (DMAMUX_CSR_SOF12)) ? 1UL : 0UL);
}
#endif /* DMAMUX_CSR_SOF12 */
#if defined (DMAMUX_CSR_SOF13)
/**
* @brief Get Synchronization Event Overrun Flag Channel 13.
* @rmtoll CSR SOF13 LL_DMAMUX_IsActiveFlag_SO13
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO13(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF13) == (DMAMUX_CSR_SOF13)) ? 1UL : 0UL);
}
#endif /* DMAMUX_CSR_SOF13 */
#if defined (DMAMUX_CSR_SOF14)
/**
* @brief Get Synchronization Event Overrun Flag Channel 14.
* @rmtoll CSR SOF13 LL_DMAMUX_IsActiveFlag_SO14
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO14(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF14) == (DMAMUX_CSR_SOF14)) ? 1UL : 0UL);
}
#endif /* DMAMUX_CSR_SOF14 */
#if defined (DMAMUX_CSR_SOF15)
/**
* @brief Get Synchronization Event Overrun Flag Channel 15.
* @rmtoll CSR SOF13 LL_DMAMUX_IsActiveFlag_SO15
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_SO15(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_ChannelStatus->CSR, DMAMUX_CSR_SOF15) == (DMAMUX_CSR_SOF15)) ? 1UL : 0UL);
}
#endif /* DMAMUX_CSR_SOF15 */
/**
* @brief Get Request Generator 0 Trigger Event Overrun Flag.
* @rmtoll RGSR OF0 LL_DMAMUX_IsActiveFlag_RGO0
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_RGO0(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_RequestGenStatus->RGSR, DMAMUX_RGSR_OF0) == (DMAMUX_RGSR_OF0)) ? 1UL : 0UL);
}
/**
* @brief Get Request Generator 1 Trigger Event Overrun Flag.
* @rmtoll RGSR OF1 LL_DMAMUX_IsActiveFlag_RGO1
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_RGO1(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_RequestGenStatus->RGSR, DMAMUX_RGSR_OF1) == (DMAMUX_RGSR_OF1)) ? 1UL : 0UL);
}
/**
* @brief Get Request Generator 2 Trigger Event Overrun Flag.
* @rmtoll RGSR OF2 LL_DMAMUX_IsActiveFlag_RGO2
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_RGO2(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_RequestGenStatus->RGSR, DMAMUX_RGSR_OF2) == (DMAMUX_RGSR_OF2)) ? 1UL : 0UL);
}
/**
* @brief Get Request Generator 3 Trigger Event Overrun Flag.
* @rmtoll RGSR OF3 LL_DMAMUX_IsActiveFlag_RGO3
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsActiveFlag_RGO3(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
return ((READ_BIT(DMAMUX1_RequestGenStatus->RGSR, DMAMUX_RGSR_OF3) == (DMAMUX_RGSR_OF3)) ? 1UL : 0UL);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 0.
* @rmtoll CFR CSOF0 LL_DMAMUX_ClearFlag_SO0
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO0(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF0);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 1.
* @rmtoll CFR CSOF1 LL_DMAMUX_ClearFlag_SO1
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO1(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF1);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 2.
* @rmtoll CFR CSOF2 LL_DMAMUX_ClearFlag_SO2
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO2(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF2);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 3.
* @rmtoll CFR CSOF3 LL_DMAMUX_ClearFlag_SO3
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO3(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF3);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 4.
* @rmtoll CFR CSOF4 LL_DMAMUX_ClearFlag_SO4
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO4(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF4);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 5.
* @rmtoll CFR CSOF5 LL_DMAMUX_ClearFlag_SO5
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO5(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF5);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 6.
* @rmtoll CFR CSOF6 LL_DMAMUX_ClearFlag_SO6
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO6(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF6);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 7.
* @rmtoll CFR CSOF7 LL_DMAMUX_ClearFlag_SO7
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO7(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF7);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 8.
* @rmtoll CFR CSOF8 LL_DMAMUX_ClearFlag_SO8
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO8(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF8);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 9.
* @rmtoll CFR CSOF9 LL_DMAMUX_ClearFlag_SO9
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO9(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF9);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 10.
* @rmtoll CFR CSOF10 LL_DMAMUX_ClearFlag_SO10
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO10(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF10);
}
/**
* @brief Clear Synchronization Event Overrun Flag Channel 11.
* @rmtoll CFR CSOF11 LL_DMAMUX_ClearFlag_SO11
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO11(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF11);
}
#if defined (DMAMUX_CFR_CSOF12)
/**
* @brief Clear Synchronization Event Overrun Flag Channel 12.
* @rmtoll CFR CSOF12 LL_DMAMUX_ClearFlag_SO12
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO12(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF12);
}
#endif /* DMAMUX_CFR_CSOF12 */
#if defined (DMAMUX_CFR_CSOF13)
/**
* @brief Clear Synchronization Event Overrun Flag Channel 13.
* @rmtoll CFR CSOF13 LL_DMAMUX_ClearFlag_SO13
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO13(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF13);
}
#endif /* DMAMUX_CFR_CSOF13 */
#if defined (DMAMUX_CFR_CSOF14)
/**
* @brief Clear Synchronization Event Overrun Flag Channel 14.
* @rmtoll CFR CSOF14 LL_DMAMUX_ClearFlag_SO14
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO14(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF14);
}
#endif /* DMAMUX_CFR_CSOF14 */
#if defined (DMAMUX_CFR_CSOF15)
/**
* @brief Clear Synchronization Event Overrun Flag Channel 15.
* @rmtoll CFR CSOF15 LL_DMAMUX_ClearFlag_SO15
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_SO15(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_ChannelStatus->CFR, DMAMUX_CFR_CSOF15);
}
#endif /* DMAMUX_CFR_CSOF15 */
/**
* @brief Clear Request Generator 0 Trigger Event Overrun Flag.
* @rmtoll RGCFR COF0 LL_DMAMUX_ClearFlag_RGO0
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_RGO0(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_RequestGenStatus->RGCFR, DMAMUX_RGCFR_COF0);
}
/**
* @brief Clear Request Generator 1 Trigger Event Overrun Flag.
* @rmtoll RGCFR COF1 LL_DMAMUX_ClearFlag_RGO1
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_RGO1(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_RequestGenStatus->RGCFR, DMAMUX_RGCFR_COF1);
}
/**
* @brief Clear Request Generator 2 Trigger Event Overrun Flag.
* @rmtoll RGCFR COF2 LL_DMAMUX_ClearFlag_RGO2
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_RGO2(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_RequestGenStatus->RGCFR, DMAMUX_RGCFR_COF2);
}
/**
* @brief Clear Request Generator 3 Trigger Event Overrun Flag.
* @rmtoll RGCFR COF3 LL_DMAMUX_ClearFlag_RGO3
* @param DMAMUXx DMAMUXx DMAMUXx Instance
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_ClearFlag_RGO3(DMAMUX_Channel_TypeDef *DMAMUXx)
{
UNUSED(DMAMUXx);
SET_BIT(DMAMUX1_RequestGenStatus->RGCFR, DMAMUX_RGCFR_COF3);
}
/**
* @}
*/
/** @defgroup DMAMUX_LL_EF_IT_Management IT_Management
* @{
*/
/**
* @brief Enable the Synchronization Event Overrun Interrupt on DMAMUX channel x.
* @rmtoll CxCR SOIE LL_DMAMUX_EnableIT_SO
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_EnableIT_SO(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
SET_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SOIE);
}
/**
* @brief Disable the Synchronization Event Overrun Interrupt on DMAMUX channel x.
* @rmtoll CxCR SOIE LL_DMAMUX_DisableIT_SO
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_DisableIT_SO(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
CLEAR_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SOIE);
}
/**
* @brief Check if the Synchronization Event Overrun Interrupt on DMAMUX channel x is enabled or disabled.
* @rmtoll CxCR SOIE LL_DMAMUX_IsEnabledIT_SO
* @param DMAMUXx DMAMUXx Instance
* @param Channel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_CHANNEL_0
* @arg @ref LL_DMAMUX_CHANNEL_1
* @arg @ref LL_DMAMUX_CHANNEL_2
* @arg @ref LL_DMAMUX_CHANNEL_3
* @arg @ref LL_DMAMUX_CHANNEL_4
* @arg @ref LL_DMAMUX_CHANNEL_5
* @arg @ref LL_DMAMUX_CHANNEL_6
* @arg @ref LL_DMAMUX_CHANNEL_7
* @arg @ref LL_DMAMUX_CHANNEL_8
* @arg @ref LL_DMAMUX_CHANNEL_9
* @arg @ref LL_DMAMUX_CHANNEL_10
* @arg @ref LL_DMAMUX_CHANNEL_11
* @arg @ref LL_DMAMUX_CHANNEL_12
* @arg @ref LL_DMAMUX_CHANNEL_13
* @arg @ref LL_DMAMUX_CHANNEL_14
* @arg @ref LL_DMAMUX_CHANNEL_15
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsEnabledIT_SO(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t Channel)
{
(void)(DMAMUXx);
return (((READ_BIT((DMAMUX1_Channel0 + Channel)->CCR, DMAMUX_CxCR_SOIE)) == (DMAMUX_CxCR_SOIE))? 1UL : 0UL);
}
/**
* @brief Enable the Request Generation Trigger Event Overrun Interrupt on DMAMUX channel x.
* @rmtoll RGxCR OIE LL_DMAMUX_EnableIT_RGO
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_EnableIT_RGO(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
UNUSED(DMAMUXx);
SET_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_OIE);
}
/**
* @brief Disable the Request Generation Trigger Event Overrun Interrupt on DMAMUX channel x.
* @rmtoll RGxCR OIE LL_DMAMUX_DisableIT_RGO
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval None
*/
__STATIC_INLINE void LL_DMAMUX_DisableIT_RGO(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
UNUSED(DMAMUXx);
CLEAR_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_OIE);
}
/**
* @brief Check if the Request Generation Trigger Event Overrun Interrupt on DMAMUX channel x is enabled or disabled.
* @rmtoll RGxCR OIE LL_DMAMUX_IsEnabledIT_RGO
* @param DMAMUXx DMAMUXx Instance
* @param RequestGenChannel This parameter can be one of the following values:
* @arg @ref LL_DMAMUX_REQ_GEN_0
* @arg @ref LL_DMAMUX_REQ_GEN_1
* @arg @ref LL_DMAMUX_REQ_GEN_2
* @arg @ref LL_DMAMUX_REQ_GEN_3
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_DMAMUX_IsEnabledIT_RGO(DMAMUX_Channel_TypeDef *DMAMUXx, uint32_t RequestGenChannel)
{
UNUSED(DMAMUXx);
return ((READ_BIT(((DMAMUX_RequestGen_TypeDef *)((uint32_t)((uint32_t)DMAMUX1_RequestGenerator0 + (DMAMUX_RGCR_SIZE *
(RequestGenChannel)))))->RGCR, DMAMUX_RGxCR_OIE) == (DMAMUX_RGxCR_OIE)) ? 1UL : 0UL);
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* DMAMUX1 */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_LL_DMAMUX_H */
| 94,191 | C | 45.931739 | 202 | 0.602499 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_system.h | /**
******************************************************************************
* @file stm32g4xx_ll_system.h
* @author MCD Application Team
* @brief Header file of SYSTEM LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
The LL SYSTEM driver contains a set of generic APIs that can be
used by user:
(+) Some of the FLASH features need to be handled in the SYSTEM file.
(+) Access to DBGCMU registers
(+) Access to SYSCFG registers
(+) Access to VREFBUF registers
@endverbatim
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_LL_SYSTEM_H
#define __STM32G4xx_LL_SYSTEM_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined (FLASH) || defined (SYSCFG) || defined (DBGMCU) || defined (VREFBUF)
/** @defgroup SYSTEM_LL SYSTEM
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup SYSTEM_LL_Private_Constants SYSTEM Private Constants
* @{
*/
/* Defines used for position in the register */
#define DBGMCU_REVID_POSITION (uint32_t)POSITION_VAL(DBGMCU_IDCODE_REV_ID)
/**
* @brief Power-down in Run mode Flash key
*/
#define FLASH_PDKEY1 0x04152637U /*!< Flash power down key1 */
#define FLASH_PDKEY2 0xFAFBFCFDU /*!< Flash power down key2: used with FLASH_PDKEY1
to unlock the RUN_PD bit in FLASH_ACR */
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup SYSTEM_LL_Exported_Constants SYSTEM Exported Constants
* @{
*/
/** @defgroup SYSTEM_LL_EC_REMAP SYSCFG REMAP
* @{
*/
#define LL_SYSCFG_REMAP_FLASH 0x00000000U /*!< Main Flash memory mapped at 0x00000000 */
#define LL_SYSCFG_REMAP_SYSTEMFLASH SYSCFG_MEMRMP_MEM_MODE_0 /*!< System Flash memory mapped at 0x00000000 */
#define LL_SYSCFG_REMAP_SRAM (SYSCFG_MEMRMP_MEM_MODE_1 | SYSCFG_MEMRMP_MEM_MODE_0) /*!< SRAM1 mapped at 0x00000000 */
#if defined(FMC_Bank1_R)
#define LL_SYSCFG_REMAP_FMC SYSCFG_MEMRMP_MEM_MODE_1 /*!< FMC bank 1 (NOR/PSRAM 1 and 2) mapped at 0x00000000 */
#endif /* FMC_Bank1_R */
#define LL_SYSCFG_REMAP_QUADSPI (SYSCFG_MEMRMP_MEM_MODE_2 | SYSCFG_MEMRMP_MEM_MODE_1) /*!< QUADSPI memory mapped at 0x00000000 */
/**
* @}
*/
#if defined(SYSCFG_MEMRMP_FB_MODE)
/** @defgroup SYSTEM_LL_EC_BANKMODE SYSCFG BANK MODE
* @{
*/
#define LL_SYSCFG_BANKMODE_BANK1 0x00000000U /*!< Flash Bank1 mapped at 0x08000000 (and aliased @0x00000000)
and Flash Bank2 mapped at 0x08040000 (and aliased at 0x00080000) */
#define LL_SYSCFG_BANKMODE_BANK2 SYSCFG_MEMRMP_FB_MODE /*!< Flash Bank2 mapped at 0x08000000 (and aliased @0x00000000)
and Flash Bank1 mapped at 0x08040000 (and aliased at 0x00080000) */
/**
* @}
*/
#endif /* SYSCFG_MEMRMP_FB_MODE */
/** @defgroup SYSTEM_LL_EC_I2C_FASTMODEPLUS SYSCFG I2C FASTMODEPLUS
* @{
*/
#define LL_SYSCFG_I2C_FASTMODEPLUS_PB6 SYSCFG_CFGR1_I2C_PB6_FMP /*!< Enable Fast Mode Plus on PB6 */
#define LL_SYSCFG_I2C_FASTMODEPLUS_PB7 SYSCFG_CFGR1_I2C_PB7_FMP /*!< Enable Fast Mode Plus on PB7 */
#if defined(SYSCFG_CFGR1_I2C_PB8_FMP)
#define LL_SYSCFG_I2C_FASTMODEPLUS_PB8 SYSCFG_CFGR1_I2C_PB8_FMP /*!< Enable Fast Mode Plus on PB8 */
#endif /* SYSCFG_CFGR1_I2C_PB8_FMP */
#if defined(SYSCFG_CFGR1_I2C_PB9_FMP)
#define LL_SYSCFG_I2C_FASTMODEPLUS_PB9 SYSCFG_CFGR1_I2C_PB9_FMP /*!< Enable Fast Mode Plus on PB9 */
#endif /* SYSCFG_CFGR1_I2C_PB9_FMP */
#define LL_SYSCFG_I2C_FASTMODEPLUS_I2C1 SYSCFG_CFGR1_I2C1_FMP /*!< Enable Fast Mode Plus on I2C1 pins */
#if defined(I2C2)
#define LL_SYSCFG_I2C_FASTMODEPLUS_I2C2 SYSCFG_CFGR1_I2C2_FMP /*!< Enable Fast Mode Plus on I2C2 pins */
#endif /* I2C2 */
#define LL_SYSCFG_I2C_FASTMODEPLUS_I2C3 SYSCFG_CFGR1_I2C3_FMP /*!< Enable Fast Mode Plus on I2C3 pins */
#if defined(I2C4)
#define LL_SYSCFG_I2C_FASTMODEPLUS_I2C4 SYSCFG_CFGR1_I2C4_FMP /*!< Enable Fast Mode Plus on I2C4 pins */
#endif /* I2C4 */
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_EXTI_PORT SYSCFG EXTI PORT
* @{
*/
#define LL_SYSCFG_EXTI_PORTA 0U /*!< EXTI PORT A */
#define LL_SYSCFG_EXTI_PORTB 1U /*!< EXTI PORT B */
#define LL_SYSCFG_EXTI_PORTC 2U /*!< EXTI PORT C */
#define LL_SYSCFG_EXTI_PORTD 3U /*!< EXTI PORT D */
#define LL_SYSCFG_EXTI_PORTE 4U /*!< EXTI PORT E */
#define LL_SYSCFG_EXTI_PORTF 5U /*!< EXTI PORT F */
#define LL_SYSCFG_EXTI_PORTG 6U /*!< EXTI PORT G */
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_EXTI_LINE SYSCFG EXTI LINE
* @{
*/
#define LL_SYSCFG_EXTI_LINE0 (uint32_t)((0x000FU << 16U) | 0U) /* !< EXTI_POSITION_0 | EXTICR[0] */
#define LL_SYSCFG_EXTI_LINE1 (uint32_t)((0x00F0U << 16U) | 0U) /* !< EXTI_POSITION_4 | EXTICR[0] */
#define LL_SYSCFG_EXTI_LINE2 (uint32_t)((0x0F00U << 16U) | 0U) /* !< EXTI_POSITION_8 | EXTICR[0] */
#define LL_SYSCFG_EXTI_LINE3 (uint32_t)((0xF000U << 16U) | 0U) /* !< EXTI_POSITION_12 | EXTICR[0] */
#define LL_SYSCFG_EXTI_LINE4 (uint32_t)((0x000FU << 16U) | 1U) /* !< EXTI_POSITION_0 | EXTICR[1] */
#define LL_SYSCFG_EXTI_LINE5 (uint32_t)((0x00F0U << 16U) | 1U) /* !< EXTI_POSITION_4 | EXTICR[1] */
#define LL_SYSCFG_EXTI_LINE6 (uint32_t)((0x0F00U << 16U) | 1U) /* !< EXTI_POSITION_8 | EXTICR[1] */
#define LL_SYSCFG_EXTI_LINE7 (uint32_t)((0xF000U << 16U) | 1U) /* !< EXTI_POSITION_12 | EXTICR[1] */
#define LL_SYSCFG_EXTI_LINE8 (uint32_t)((0x000FU << 16U) | 2U) /* !< EXTI_POSITION_0 | EXTICR[2] */
#define LL_SYSCFG_EXTI_LINE9 (uint32_t)((0x00F0U << 16U) | 2U) /* !< EXTI_POSITION_4 | EXTICR[2] */
#define LL_SYSCFG_EXTI_LINE10 (uint32_t)((0x0F00U << 16U) | 2U) /* !< EXTI_POSITION_8 | EXTICR[2] */
#define LL_SYSCFG_EXTI_LINE11 (uint32_t)((0xF000U << 16U) | 2U) /* !< EXTI_POSITION_12 | EXTICR[2] */
#define LL_SYSCFG_EXTI_LINE12 (uint32_t)((0x000FU << 16U) | 3U) /* !< EXTI_POSITION_0 | EXTICR[3] */
#define LL_SYSCFG_EXTI_LINE13 (uint32_t)((0x00F0U << 16U) | 3U) /* !< EXTI_POSITION_4 | EXTICR[3] */
#define LL_SYSCFG_EXTI_LINE14 (uint32_t)((0x0F00U << 16U) | 3U) /* !< EXTI_POSITION_8 | EXTICR[3] */
#define LL_SYSCFG_EXTI_LINE15 (uint32_t)((0xF000U << 16U) | 3U) /* !< EXTI_POSITION_12 | EXTICR[3] */
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_TIMBREAK SYSCFG TIMER BREAK
* @{
*/
#define LL_SYSCFG_TIMBREAK_ECC SYSCFG_CFGR2_ECCL /*!< Enables and locks the ECC error signal
with Break Input of TIM1/8/15/16/17 */
#define LL_SYSCFG_TIMBREAK_PVD SYSCFG_CFGR2_PVDL /*!< Enables and locks the PVD connection
with TIM1/8/15/16/17 Break Input
and also the PVDE and PLS bits of the Power Control Interface */
#define LL_SYSCFG_TIMBREAK_SRAM_PARITY SYSCFG_CFGR2_SPL /*!< Enables and locks the SRAM_PARITY error signal
with Break Input of TIM1/8/15/16/17 */
#define LL_SYSCFG_TIMBREAK_LOCKUP SYSCFG_CFGR2_CLL /*!< Enables and locks the LOCKUP output of CortexM4
with Break Input of TIM1/15/16/17 */
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_CCMSRAMWRP SYSCFG CCMSRAM WRP
* @{
*/
#define LL_SYSCFG_CCMSRAMWRP_PAGE0 SYSCFG_SWPR_PAGE0 /*!< CCMSRAM Write protection page 0 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE1 SYSCFG_SWPR_PAGE1 /*!< CCMSRAM Write protection page 1 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE2 SYSCFG_SWPR_PAGE2 /*!< CCMSRAM Write protection page 2 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE3 SYSCFG_SWPR_PAGE3 /*!< CCMSRAM Write protection page 3 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE4 SYSCFG_SWPR_PAGE4 /*!< CCMSRAM Write protection page 4 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE5 SYSCFG_SWPR_PAGE5 /*!< CCMSRAM Write protection page 5 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE6 SYSCFG_SWPR_PAGE6 /*!< CCMSRAM Write protection page 6 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE7 SYSCFG_SWPR_PAGE7 /*!< CCMSRAM Write protection page 7 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE8 SYSCFG_SWPR_PAGE8 /*!< CCMSRAM Write protection page 8 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE9 SYSCFG_SWPR_PAGE9 /*!< CCMSRAM Write protection page 9 */
#if defined(SYSCFG_SWPR_PAGE10)
#define LL_SYSCFG_CCMSRAMWRP_PAGE10 SYSCFG_SWPR_PAGE10 /*!< CCMSRAM Write protection page 10 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE11 SYSCFG_SWPR_PAGE11 /*!< CCMSRAM Write protection page 11 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE12 SYSCFG_SWPR_PAGE12 /*!< CCMSRAM Write protection page 12 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE13 SYSCFG_SWPR_PAGE13 /*!< CCMSRAM Write protection page 13 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE14 SYSCFG_SWPR_PAGE14 /*!< CCMSRAM Write protection page 14 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE15 SYSCFG_SWPR_PAGE15 /*!< CCMSRAM Write protection page 15 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE16 SYSCFG_SWPR_PAGE16 /*!< CCMSRAM Write protection page 16 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE17 SYSCFG_SWPR_PAGE17 /*!< CCMSRAM Write protection page 17 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE18 SYSCFG_SWPR_PAGE18 /*!< CCMSRAM Write protection page 18 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE19 SYSCFG_SWPR_PAGE19 /*!< CCMSRAM Write protection page 19 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE20 SYSCFG_SWPR_PAGE20 /*!< CCMSRAM Write protection page 20 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE21 SYSCFG_SWPR_PAGE21 /*!< CCMSRAM Write protection page 21 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE22 SYSCFG_SWPR_PAGE22 /*!< CCMSRAM Write protection page 22 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE23 SYSCFG_SWPR_PAGE23 /*!< CCMSRAM Write protection page 23 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE24 SYSCFG_SWPR_PAGE24 /*!< CCMSRAM Write protection page 24 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE25 SYSCFG_SWPR_PAGE25 /*!< CCMSRAM Write protection page 25 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE26 SYSCFG_SWPR_PAGE26 /*!< CCMSRAM Write protection page 26 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE27 SYSCFG_SWPR_PAGE27 /*!< CCMSRAM Write protection page 27 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE28 SYSCFG_SWPR_PAGE28 /*!< CCMSRAM Write protection page 28 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE29 SYSCFG_SWPR_PAGE29 /*!< CCMSRAM Write protection page 29 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE30 SYSCFG_SWPR_PAGE30 /*!< CCMSRAM Write protection page 30 */
#define LL_SYSCFG_CCMSRAMWRP_PAGE31 SYSCFG_SWPR_PAGE31 /*!< CCMSRAM Write protection page 31 */
#endif /* SYSCFG_SWPR_PAGE10 */
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_TRACE DBGMCU TRACE Pin Assignment
* @{
*/
#define LL_DBGMCU_TRACE_NONE 0x00000000U /*!< TRACE pins not assigned (default state) */
#define LL_DBGMCU_TRACE_ASYNCH DBGMCU_CR_TRACE_IOEN /*!< TRACE pin assignment for Asynchronous Mode */
#define LL_DBGMCU_TRACE_SYNCH_SIZE1 (DBGMCU_CR_TRACE_IOEN | DBGMCU_CR_TRACE_MODE_0) /*!< TRACE pin assignment for Synchronous Mode with a TRACEDATA size of 1 */
#define LL_DBGMCU_TRACE_SYNCH_SIZE2 (DBGMCU_CR_TRACE_IOEN | DBGMCU_CR_TRACE_MODE_1) /*!< TRACE pin assignment for Synchronous Mode with a TRACEDATA size of 2 */
#define LL_DBGMCU_TRACE_SYNCH_SIZE4 (DBGMCU_CR_TRACE_IOEN | DBGMCU_CR_TRACE_MODE) /*!< TRACE pin assignment for Synchronous Mode with a TRACEDATA size of 4 */
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_APB1_GRP1_STOP_IP DBGMCU APB1 GRP1 STOP IP
* @{
*/
#define LL_DBGMCU_APB1_GRP1_TIM2_STOP DBGMCU_APB1FZR1_DBG_TIM2_STOP /*!< The counter clock of TIM2 is stopped when the core is halted*/
#if defined(TIM3)
#define LL_DBGMCU_APB1_GRP1_TIM3_STOP DBGMCU_APB1FZR1_DBG_TIM3_STOP /*!< The counter clock of TIM3 is stopped when the core is halted*/
#endif /* TIM3 */
#if defined(TIM4)
#define LL_DBGMCU_APB1_GRP1_TIM4_STOP DBGMCU_APB1FZR1_DBG_TIM4_STOP /*!< The counter clock of TIM4 is stopped when the core is halted*/
#endif /* TIM4 */
#if defined(TIM5)
#define LL_DBGMCU_APB1_GRP1_TIM5_STOP DBGMCU_APB1FZR1_DBG_TIM5_STOP /*!< The counter clock of TIM5 is stopped when the core is halted*/
#endif /* TIM5 */
#define LL_DBGMCU_APB1_GRP1_TIM6_STOP DBGMCU_APB1FZR1_DBG_TIM6_STOP /*!< The counter clock of TIM6 is stopped when the core is halted*/
#if defined(TIM7)
#define LL_DBGMCU_APB1_GRP1_TIM7_STOP DBGMCU_APB1FZR1_DBG_TIM7_STOP /*!< The counter clock of TIM7 is stopped when the core is halted*/
#endif /* TIM7 */
#define LL_DBGMCU_APB1_GRP1_RTC_STOP DBGMCU_APB1FZR1_DBG_RTC_STOP /*!< The clock of the RTC counter is stopped when the core is halted*/
#define LL_DBGMCU_APB1_GRP1_WWDG_STOP DBGMCU_APB1FZR1_DBG_WWDG_STOP /*!< The window watchdog counter clock is stopped when the core is halted*/
#define LL_DBGMCU_APB1_GRP1_IWDG_STOP DBGMCU_APB1FZR1_DBG_IWDG_STOP /*!< The independent watchdog counter clock is stopped when the core is halted*/
#define LL_DBGMCU_APB1_GRP1_I2C1_STOP DBGMCU_APB1FZR1_DBG_I2C1_STOP /*!< The I2C1 SMBus timeout is frozen*/
#if defined(I2C2)
#define LL_DBGMCU_APB1_GRP1_I2C2_STOP DBGMCU_APB1FZR1_DBG_I2C2_STOP /*!< The I2C2 SMBus timeout is frozen*/
#endif /* I2C2 */
#define LL_DBGMCU_APB1_GRP1_I2C3_STOP DBGMCU_APB1FZR1_DBG_I2C3_STOP /*!< The I2C3 SMBus timeout is frozen*/
#define LL_DBGMCU_APB1_GRP1_LPTIM1_STOP DBGMCU_APB1FZR1_DBG_LPTIM1_STOP /*!< The counter clock of LPTIM1 is stopped when the core is halted*/
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_APB1_GRP2_STOP_IP DBGMCU APB1 GRP2 STOP IP
* @{
*/
#if defined(I2C4)
#define LL_DBGMCU_APB1_GRP2_I2C4_STOP DBGMCU_APB1FZR2_DBG_I2C4_STOP /*!< The I2C4 SMBus timeout is frozen*/
#endif /* I2C4 */
/**
* @}
*/
/** @defgroup SYSTEM_LL_EC_APB2_GRP1_STOP_IP DBGMCU APB2 GRP1 STOP IP
* @{
*/
#define LL_DBGMCU_APB2_GRP1_TIM1_STOP DBGMCU_APB2FZ_DBG_TIM1_STOP /*!< The counter clock of TIM1 is stopped when the core is halted*/
#if defined(TIM8)
#define LL_DBGMCU_APB2_GRP1_TIM8_STOP DBGMCU_APB2FZ_DBG_TIM8_STOP /*!< The counter clock of TIM8 is stopped when the core is halted*/
#endif /* TIM8 */
#define LL_DBGMCU_APB2_GRP1_TIM15_STOP DBGMCU_APB2FZ_DBG_TIM15_STOP /*!< The counter clock of TIM15 is stopped when the core is halted*/
#define LL_DBGMCU_APB2_GRP1_TIM16_STOP DBGMCU_APB2FZ_DBG_TIM16_STOP /*!< The counter clock of TIM16 is stopped when the core is halted*/
#if defined(TIM17)
#define LL_DBGMCU_APB2_GRP1_TIM17_STOP DBGMCU_APB2FZ_DBG_TIM17_STOP /*!< The counter clock of TIM17 is stopped when the core is halted*/
#endif /* TIM17 */
#if defined(TIM20)
#define LL_DBGMCU_APB2_GRP1_TIM20_STOP DBGMCU_APB2FZ_DBG_TIM20_STOP /*!< The counter clock of TIM20 is stopped when the core is halted*/
#endif /* TIM20 */
#if defined(HRTIM1)
#define LL_DBGMCU_APB2_GRP1_HRTIM1_STOP DBGMCU_APB2FZ_DBG_HRTIM1_STOP /*!< The counter clock of HRTIM1 is stopped when the core is halted*/
#endif /* HRTIM1 */
/**
* @}
*/
#if defined(VREFBUF)
/** @defgroup SYSTEM_LL_EC_VOLTAGE VREFBUF VOLTAGE
* @{
*/
#define LL_VREFBUF_VOLTAGE_SCALE0 ((uint32_t)0x00000000) /*!< Voltage reference scale 0 (VREFBUF_OUT = 2.048V) */
#define LL_VREFBUF_VOLTAGE_SCALE1 VREFBUF_CSR_VRS_0 /*!< Voltage reference scale 1 (VREFBUF_OUT = 2.5V) */
#define LL_VREFBUF_VOLTAGE_SCALE2 VREFBUF_CSR_VRS_1 /*!< Voltage reference scale 2 (VREFBUF_OUT = 2.9V) */
/**
* @}
*/
#endif /* VREFBUF */
/** @defgroup SYSTEM_LL_EC_LATENCY FLASH LATENCY
* @{
*/
#define LL_FLASH_LATENCY_0 FLASH_ACR_LATENCY_0WS /*!< FLASH Zero wait state */
#define LL_FLASH_LATENCY_1 FLASH_ACR_LATENCY_1WS /*!< FLASH One wait state */
#define LL_FLASH_LATENCY_2 FLASH_ACR_LATENCY_2WS /*!< FLASH Two wait states */
#define LL_FLASH_LATENCY_3 FLASH_ACR_LATENCY_3WS /*!< FLASH Three wait states */
#define LL_FLASH_LATENCY_4 FLASH_ACR_LATENCY_4WS /*!< FLASH Four wait states */
#if defined(FLASH_ACR_LATENCY_5WS)
#define LL_FLASH_LATENCY_5 FLASH_ACR_LATENCY_5WS /*!< FLASH five wait state */
#define LL_FLASH_LATENCY_6 FLASH_ACR_LATENCY_6WS /*!< FLASH six wait state */
#define LL_FLASH_LATENCY_7 FLASH_ACR_LATENCY_7WS /*!< FLASH seven wait states */
#define LL_FLASH_LATENCY_8 FLASH_ACR_LATENCY_8WS /*!< FLASH eight wait states */
#define LL_FLASH_LATENCY_9 FLASH_ACR_LATENCY_9WS /*!< FLASH nine wait states */
#define LL_FLASH_LATENCY_10 FLASH_ACR_LATENCY_10WS /*!< FLASH ten wait states */
#define LL_FLASH_LATENCY_11 FLASH_ACR_LATENCY_11WS /*!< FLASH eleven wait states */
#define LL_FLASH_LATENCY_12 FLASH_ACR_LATENCY_12WS /*!< FLASH twelve wait states */
#define LL_FLASH_LATENCY_13 FLASH_ACR_LATENCY_13WS /*!< FLASH thirteen wait states */
#define LL_FLASH_LATENCY_14 FLASH_ACR_LATENCY_14WS /*!< FLASH fourteen wait states */
#define LL_FLASH_LATENCY_15 FLASH_ACR_LATENCY_15WS /*!< FLASH fifteen wait states */
#endif /* FLASH_ACR_LATENCY_5WS */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup SYSTEM_LL_Exported_Functions SYSTEM Exported Functions
* @{
*/
/** @defgroup SYSTEM_LL_EF_SYSCFG SYSCFG
* @{
*/
/**
* @brief Set memory mapping at address 0x00000000
* @rmtoll SYSCFG_MEMRMP MEM_MODE LL_SYSCFG_SetRemapMemory
* @param Memory This parameter can be one of the following values:
* @arg @ref LL_SYSCFG_REMAP_FLASH
* @arg @ref LL_SYSCFG_REMAP_SYSTEMFLASH
* @arg @ref LL_SYSCFG_REMAP_SRAM
* @arg @ref LL_SYSCFG_REMAP_FMC (*)
* @arg @ref LL_SYSCFG_REMAP_QUADSPI (*)
*
* (*) value not defined in all devices
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_SetRemapMemory(uint32_t Memory)
{
MODIFY_REG(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE, Memory);
}
/**
* @brief Get memory mapping at address 0x00000000
* @rmtoll SYSCFG_MEMRMP MEM_MODE LL_SYSCFG_GetRemapMemory
* @retval Returned value can be one of the following values:
* @arg @ref LL_SYSCFG_REMAP_FLASH
* @arg @ref LL_SYSCFG_REMAP_SYSTEMFLASH
* @arg @ref LL_SYSCFG_REMAP_SRAM
* @arg @ref LL_SYSCFG_REMAP_FMC (*)
* @arg @ref LL_SYSCFG_REMAP_QUADSPI (*)
*
* (*) value not defined in all devices
*/
__STATIC_INLINE uint32_t LL_SYSCFG_GetRemapMemory(void)
{
return (uint32_t)(READ_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE));
}
#if defined(SYSCFG_MEMRMP_FB_MODE)
/**
* @brief Select Flash bank mode (Bank flashed at 0x08000000)
* @rmtoll SYSCFG_MEMRMP FB_MODE LL_SYSCFG_SetFlashBankMode
* @param Bank This parameter can be one of the following values:
* @arg @ref LL_SYSCFG_BANKMODE_BANK1
* @arg @ref LL_SYSCFG_BANKMODE_BANK2
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_SetFlashBankMode(uint32_t Bank)
{
MODIFY_REG(SYSCFG->MEMRMP, SYSCFG_MEMRMP_FB_MODE, Bank);
}
/**
* @brief Get Flash bank mode (Bank flashed at 0x08000000)
* @rmtoll SYSCFG_MEMRMP FB_MODE LL_SYSCFG_GetFlashBankMode
* @retval Returned value can be one of the following values:
* @arg @ref LL_SYSCFG_BANKMODE_BANK1
* @arg @ref LL_SYSCFG_BANKMODE_BANK2
*/
__STATIC_INLINE uint32_t LL_SYSCFG_GetFlashBankMode(void)
{
return (uint32_t)(READ_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_FB_MODE));
}
#endif /* SYSCFG_MEMRMP_FB_MODE */
/**
* @brief Enable I/O analog switch voltage booster.
* @note When voltage booster is enabled, I/O analog switches are supplied
* by a dedicated voltage booster, from VDD power domain. This is
* the recommended configuration with low VDDA voltage operation.
* @note The I/O analog switch voltage booster is relevant for peripherals
* using I/O in analog input: ADC, COMP, OPAMP.
* However, COMP and OPAMP inputs have a high impedance and
* voltage booster do not impact performance significantly.
* Therefore, the voltage booster is mainly intended for
* usage with ADC.
* @rmtoll SYSCFG_CFGR1 BOOSTEN LL_SYSCFG_EnableAnalogBooster
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableAnalogBooster(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_BOOSTEN);
}
/**
* @brief Disable I/O analog switch voltage booster.
* @note When voltage booster is enabled, I/O analog switches are supplied
* by a dedicated voltage booster, from VDD power domain. This is
* the recommended configuration with low VDDA voltage operation.
* @note The I/O analog switch voltage booster is relevant for peripherals
* using I/O in analog input: ADC, COMP, OPAMP.
* However, COMP and OPAMP inputs have a high impedance and
* voltage booster do not impact performance significantly.
* Therefore, the voltage booster is mainly intended for
* usage with ADC.
* @rmtoll SYSCFG_CFGR1 BOOSTEN LL_SYSCFG_DisableAnalogBooster
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableAnalogBooster(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_BOOSTEN);
}
/**
* @brief Enable the I2C fast mode plus driving capability.
* @rmtoll SYSCFG_CFGR1 I2C_PBx_FMP LL_SYSCFG_EnableFastModePlus\n
* SYSCFG_CFGR1 I2Cx_FMP LL_SYSCFG_EnableFastModePlus
* @param ConfigFastModePlus This parameter can be a combination of the following values:
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB6
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB7
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB8 (*)
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB9 (*)
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C1
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C2 (*)
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C3
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C4 (*)
*
* (*) value not defined in all devices
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableFastModePlus(uint32_t ConfigFastModePlus)
{
SET_BIT(SYSCFG->CFGR1, ConfigFastModePlus);
}
/**
* @brief Disable the I2C fast mode plus driving capability.
* @rmtoll SYSCFG_CFGR1 I2C_PBx_FMP LL_SYSCFG_DisableFastModePlus\n
* SYSCFG_CFGR1 I2Cx_FMP LL_SYSCFG_DisableFastModePlus
* @param ConfigFastModePlus This parameter can be a combination of the following values:
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB6
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB7
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB8 (*)
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_PB9 (*)
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C1
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C2 (*)
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C3
* @arg @ref LL_SYSCFG_I2C_FASTMODEPLUS_I2C4 (*)
*
* (*) value not defined in all devices
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableFastModePlus(uint32_t ConfigFastModePlus)
{
CLEAR_BIT(SYSCFG->CFGR1, ConfigFastModePlus);
}
/**
* @brief Enable Floating Point Unit Invalid operation Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_0 LL_SYSCFG_EnableIT_FPU_IOC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableIT_FPU_IOC(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_0);
}
/**
* @brief Enable Floating Point Unit Divide-by-zero Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_1 LL_SYSCFG_EnableIT_FPU_DZC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableIT_FPU_DZC(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_1);
}
/**
* @brief Enable Floating Point Unit Underflow Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_2 LL_SYSCFG_EnableIT_FPU_UFC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableIT_FPU_UFC(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_2);
}
/**
* @brief Enable Floating Point Unit Overflow Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_3 LL_SYSCFG_EnableIT_FPU_OFC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableIT_FPU_OFC(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_3);
}
/**
* @brief Enable Floating Point Unit Input denormal Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_4 LL_SYSCFG_EnableIT_FPU_IDC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableIT_FPU_IDC(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_4);
}
/**
* @brief Enable Floating Point Unit Inexact Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_5 LL_SYSCFG_EnableIT_FPU_IXC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableIT_FPU_IXC(void)
{
SET_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_5);
}
/**
* @brief Disable Floating Point Unit Invalid operation Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_0 LL_SYSCFG_DisableIT_FPU_IOC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableIT_FPU_IOC(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_0);
}
/**
* @brief Disable Floating Point Unit Divide-by-zero Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_1 LL_SYSCFG_DisableIT_FPU_DZC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableIT_FPU_DZC(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_1);
}
/**
* @brief Disable Floating Point Unit Underflow Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_2 LL_SYSCFG_DisableIT_FPU_UFC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableIT_FPU_UFC(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_2);
}
/**
* @brief Disable Floating Point Unit Overflow Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_3 LL_SYSCFG_DisableIT_FPU_OFC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableIT_FPU_OFC(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_3);
}
/**
* @brief Disable Floating Point Unit Input denormal Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_4 LL_SYSCFG_DisableIT_FPU_IDC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableIT_FPU_IDC(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_4);
}
/**
* @brief Disable Floating Point Unit Inexact Interrupt
* @rmtoll SYSCFG_CFGR1 FPU_IE_5 LL_SYSCFG_DisableIT_FPU_IXC
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_DisableIT_FPU_IXC(void)
{
CLEAR_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_5);
}
/**
* @brief Check if Floating Point Unit Invalid operation Interrupt source is enabled or disabled.
* @rmtoll SYSCFG_CFGR1 FPU_IE_0 LL_SYSCFG_IsEnabledIT_FPU_IOC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsEnabledIT_FPU_IOC(void)
{
return ((READ_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_0) == (SYSCFG_CFGR1_FPU_IE_0)) ? 1UL : 0UL);
}
/**
* @brief Check if Floating Point Unit Divide-by-zero Interrupt source is enabled or disabled.
* @rmtoll SYSCFG_CFGR1 FPU_IE_1 LL_SYSCFG_IsEnabledIT_FPU_DZC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsEnabledIT_FPU_DZC(void)
{
return ((READ_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_1) == (SYSCFG_CFGR1_FPU_IE_1)) ? 1UL : 0UL);
}
/**
* @brief Check if Floating Point Unit Underflow Interrupt source is enabled or disabled.
* @rmtoll SYSCFG_CFGR1 FPU_IE_2 LL_SYSCFG_IsEnabledIT_FPU_UFC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsEnabledIT_FPU_UFC(void)
{
return ((READ_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_2) == (SYSCFG_CFGR1_FPU_IE_2)) ? 1UL : 0UL);
}
/**
* @brief Check if Floating Point Unit Overflow Interrupt source is enabled or disabled.
* @rmtoll SYSCFG_CFGR1 FPU_IE_3 LL_SYSCFG_IsEnabledIT_FPU_OFC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsEnabledIT_FPU_OFC(void)
{
return ((READ_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_3) == (SYSCFG_CFGR1_FPU_IE_3)) ? 1UL : 0UL);
}
/**
* @brief Check if Floating Point Unit Input denormal Interrupt source is enabled or disabled.
* @rmtoll SYSCFG_CFGR1 FPU_IE_4 LL_SYSCFG_IsEnabledIT_FPU_IDC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsEnabledIT_FPU_IDC(void)
{
return ((READ_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_4) == (SYSCFG_CFGR1_FPU_IE_4)) ? 1UL : 0UL);
}
/**
* @brief Check if Floating Point Unit Inexact Interrupt source is enabled or disabled.
* @rmtoll SYSCFG_CFGR1 FPU_IE_5 LL_SYSCFG_IsEnabledIT_FPU_IXC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsEnabledIT_FPU_IXC(void)
{
return ((READ_BIT(SYSCFG->CFGR1, SYSCFG_CFGR1_FPU_IE_5) == (SYSCFG_CFGR1_FPU_IE_5)) ? 1UL : 0UL);
}
/**
* @brief Configure source input for the EXTI external interrupt.
* @rmtoll SYSCFG_EXTICR1 EXTIx LL_SYSCFG_SetEXTISource\n
* SYSCFG_EXTICR2 EXTIx LL_SYSCFG_SetEXTISource\n
* SYSCFG_EXTICR3 EXTIx LL_SYSCFG_SetEXTISource\n
* SYSCFG_EXTICR4 EXTIx LL_SYSCFG_SetEXTISource
* @param Port This parameter can be one of the following values:
* @arg @ref LL_SYSCFG_EXTI_PORTA
* @arg @ref LL_SYSCFG_EXTI_PORTB
* @arg @ref LL_SYSCFG_EXTI_PORTC
* @arg @ref LL_SYSCFG_EXTI_PORTD
* @arg @ref LL_SYSCFG_EXTI_PORTE
* @arg @ref LL_SYSCFG_EXTI_PORTF
* @arg @ref LL_SYSCFG_EXTI_PORTG
*
* (*) value not defined in all devices
* @param Line This parameter can be one of the following values:
* @arg @ref LL_SYSCFG_EXTI_LINE0
* @arg @ref LL_SYSCFG_EXTI_LINE1
* @arg @ref LL_SYSCFG_EXTI_LINE2
* @arg @ref LL_SYSCFG_EXTI_LINE3
* @arg @ref LL_SYSCFG_EXTI_LINE4
* @arg @ref LL_SYSCFG_EXTI_LINE5
* @arg @ref LL_SYSCFG_EXTI_LINE6
* @arg @ref LL_SYSCFG_EXTI_LINE7
* @arg @ref LL_SYSCFG_EXTI_LINE8
* @arg @ref LL_SYSCFG_EXTI_LINE9
* @arg @ref LL_SYSCFG_EXTI_LINE10
* @arg @ref LL_SYSCFG_EXTI_LINE11
* @arg @ref LL_SYSCFG_EXTI_LINE12
* @arg @ref LL_SYSCFG_EXTI_LINE13
* @arg @ref LL_SYSCFG_EXTI_LINE14
* @arg @ref LL_SYSCFG_EXTI_LINE15
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_SetEXTISource(uint32_t Port, uint32_t Line)
{
MODIFY_REG(SYSCFG->EXTICR[Line & 0x3U], (Line >> 16U), Port << (POSITION_VAL((Line >> 16U)) & 0x1FU) );
}
/**
* @brief Get the configured defined for specific EXTI Line
* @rmtoll SYSCFG_EXTICR1 EXTIx LL_SYSCFG_GetEXTISource\n
* SYSCFG_EXTICR2 EXTIx LL_SYSCFG_GetEXTISource\n
* SYSCFG_EXTICR3 EXTIx LL_SYSCFG_GetEXTISource\n
* SYSCFG_EXTICR4 EXTIx LL_SYSCFG_GetEXTISource
* @param Line This parameter can be one of the following values:
* @arg @ref LL_SYSCFG_EXTI_LINE0
* @arg @ref LL_SYSCFG_EXTI_LINE1
* @arg @ref LL_SYSCFG_EXTI_LINE2
* @arg @ref LL_SYSCFG_EXTI_LINE3
* @arg @ref LL_SYSCFG_EXTI_LINE4
* @arg @ref LL_SYSCFG_EXTI_LINE5
* @arg @ref LL_SYSCFG_EXTI_LINE6
* @arg @ref LL_SYSCFG_EXTI_LINE7
* @arg @ref LL_SYSCFG_EXTI_LINE8
* @arg @ref LL_SYSCFG_EXTI_LINE9
* @arg @ref LL_SYSCFG_EXTI_LINE10
* @arg @ref LL_SYSCFG_EXTI_LINE11
* @arg @ref LL_SYSCFG_EXTI_LINE12
* @arg @ref LL_SYSCFG_EXTI_LINE13
* @arg @ref LL_SYSCFG_EXTI_LINE14
* @arg @ref LL_SYSCFG_EXTI_LINE15
* @retval Returned value can be one of the following values:
* @arg @ref LL_SYSCFG_EXTI_PORTA
* @arg @ref LL_SYSCFG_EXTI_PORTB
* @arg @ref LL_SYSCFG_EXTI_PORTC
* @arg @ref LL_SYSCFG_EXTI_PORTD
* @arg @ref LL_SYSCFG_EXTI_PORTE
* @arg @ref LL_SYSCFG_EXTI_PORTF
* @arg @ref LL_SYSCFG_EXTI_PORTG
*
* (*) value not defined in all devices
*/
__STATIC_INLINE uint32_t LL_SYSCFG_GetEXTISource(uint32_t Line)
{
return (uint32_t)(READ_BIT(SYSCFG->EXTICR[Line & 0x3U], (Line >> 16U)) >> (POSITION_VAL(Line >> 16U) & 0x1FU));
}
/**
* @brief Enable CCMSRAM Erase (starts a hardware CCMSRAM erase operation. This bit is
* automatically cleared at the end of the CCMSRAM erase operation.)
* @note This bit is write-protected: setting this bit is possible only after the
* correct key sequence is written in the SYSCFG_SKR register as described in
* the Reference Manual.
* @rmtoll SYSCFG_SCSR CCMER LL_SYSCFG_EnableCCMSRAMErase
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableCCMSRAMErase(void)
{
/* Starts a hardware CCMSRAM erase operation*/
SET_BIT(SYSCFG->SCSR, SYSCFG_SCSR_CCMER);
}
/**
* @brief Check if CCMSRAM erase operation is on going
* @rmtoll SYSCFG_SCSR CCMBSY LL_SYSCFG_IsCCMSRAMEraseOngoing
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsCCMSRAMEraseOngoing(void)
{
return ((READ_BIT(SYSCFG->SCSR, SYSCFG_SCSR_CCMBSY) == (SYSCFG_SCSR_CCMBSY)) ? 1UL : 0UL);
}
/**
* @brief Set connections to TIM1/8/15/16/17 Break inputs
* @rmtoll SYSCFG_CFGR2 CLL LL_SYSCFG_SetTIMBreakInputs\n
* SYSCFG_CFGR2 SPL LL_SYSCFG_SetTIMBreakInputs\n
* SYSCFG_CFGR2 PVDL LL_SYSCFG_SetTIMBreakInputs\n
* SYSCFG_CFGR2 ECCL LL_SYSCFG_SetTIMBreakInputs
* @param Break This parameter can be a combination of the following values:
* @arg @ref LL_SYSCFG_TIMBREAK_ECC
* @arg @ref LL_SYSCFG_TIMBREAK_PVD
* @arg @ref LL_SYSCFG_TIMBREAK_SRAM_PARITY
* @arg @ref LL_SYSCFG_TIMBREAK_LOCKUP
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_SetTIMBreakInputs(uint32_t Break)
{
MODIFY_REG(SYSCFG->CFGR2, SYSCFG_CFGR2_CLL | SYSCFG_CFGR2_SPL | SYSCFG_CFGR2_PVDL | SYSCFG_CFGR2_ECCL, Break);
}
/**
* @brief Get connections to TIM1/8/15/16/17 Break inputs
* @rmtoll SYSCFG_CFGR2 CLL LL_SYSCFG_GetTIMBreakInputs\n
* SYSCFG_CFGR2 SPL LL_SYSCFG_GetTIMBreakInputs\n
* SYSCFG_CFGR2 PVDL LL_SYSCFG_GetTIMBreakInputs\n
* SYSCFG_CFGR2 ECCL LL_SYSCFG_GetTIMBreakInputs
* @retval Returned value can be can be a combination of the following values:
* @arg @ref LL_SYSCFG_TIMBREAK_ECC
* @arg @ref LL_SYSCFG_TIMBREAK_PVD
* @arg @ref LL_SYSCFG_TIMBREAK_SRAM_PARITY
* @arg @ref LL_SYSCFG_TIMBREAK_LOCKUP
*/
__STATIC_INLINE uint32_t LL_SYSCFG_GetTIMBreakInputs(void)
{
return (uint32_t)(READ_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_CLL | SYSCFG_CFGR2_SPL | SYSCFG_CFGR2_PVDL | SYSCFG_CFGR2_ECCL));
}
/**
* @brief Check if SRAM parity error detected
* @rmtoll SYSCFG_CFGR2 SPF LL_SYSCFG_IsActiveFlag_SP
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_SYSCFG_IsActiveFlag_SP(void)
{
return ((READ_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_SPF) == (SYSCFG_CFGR2_SPF)) ? 1UL : 0UL);
}
/**
* @brief Clear SRAM parity error flag
* @rmtoll SYSCFG_CFGR2 SPF LL_SYSCFG_ClearFlag_SP
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_ClearFlag_SP(void)
{
SET_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_SPF);
}
/**
* @brief Enable CCMSRAM page write protection
* @note Write protection is cleared only by a system reset
* @rmtoll SYSCFG_SWPR PAGEx LL_SYSCFG_EnableCCMSRAMPageWRP
* @param CCMSRAMWRP This parameter can be a combination of the following values:
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE0
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE1
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE2
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE3
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE4
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE5
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE6
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE7
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE8
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE9
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE10 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE11 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE12 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE13 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE14 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE15 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE16 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE17 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE18 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE19 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE20 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE21 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE22 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE23 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE24 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE25 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE26 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE27 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE28 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE29 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE30 (*)
* @arg @ref LL_SYSCFG_CCMSRAMWRP_PAGE31 (*)
*
* (*) value not defined in all devices
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_EnableCCMSRAMPageWRP(uint32_t CCMSRAMWRP)
{
SET_BIT(SYSCFG->SWPR, CCMSRAMWRP);
}
/**
* @brief CCMSRAM page write protection lock prior to erase
* @rmtoll SYSCFG_SKR KEY LL_SYSCFG_LockCCMSRAMWRP
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_LockCCMSRAMWRP(void)
{
/* Writing a wrong key reactivates the write protection */
WRITE_REG(SYSCFG->SKR, 0x00);
}
/**
* @brief CCMSRAM page write protection unlock prior to erase
* @rmtoll SYSCFG_SKR KEY LL_SYSCFG_UnlockCCMSRAMWRP
* @retval None
*/
__STATIC_INLINE void LL_SYSCFG_UnlockCCMSRAMWRP(void)
{
/* unlock the write protection of the CCMER bit */
WRITE_REG(SYSCFG->SKR, 0xCA);
WRITE_REG(SYSCFG->SKR, 0x53);
}
/**
* @}
*/
/** @defgroup SYSTEM_LL_EF_DBGMCU DBGMCU
* @{
*/
/**
* @brief Return the device identifier
* @rmtoll DBGMCU_IDCODE DEV_ID LL_DBGMCU_GetDeviceID
* @retval Values between Min_Data=0x00 and Max_Data=0x0FFF (ex: device ID is 0x6415)
*/
__STATIC_INLINE uint32_t LL_DBGMCU_GetDeviceID(void)
{
return (uint32_t)(READ_BIT(DBGMCU->IDCODE, DBGMCU_IDCODE_DEV_ID));
}
/**
* @brief Return the device revision identifier
* @note This field indicates the revision of the device.
* @rmtoll DBGMCU_IDCODE REV_ID LL_DBGMCU_GetRevisionID
* @retval Values between Min_Data=0x00 and Max_Data=0xFFFF
*/
__STATIC_INLINE uint32_t LL_DBGMCU_GetRevisionID(void)
{
return (uint32_t)(READ_BIT(DBGMCU->IDCODE, DBGMCU_IDCODE_REV_ID) >> (DBGMCU_REVID_POSITION & 0x1FU));
}
/**
* @brief Enable the Debug Module during SLEEP mode
* @rmtoll DBGMCU_CR DBG_SLEEP LL_DBGMCU_EnableDBGSleepMode
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_EnableDBGSleepMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_SLEEP);
}
/**
* @brief Disable the Debug Module during SLEEP mode
* @rmtoll DBGMCU_CR DBG_SLEEP LL_DBGMCU_DisableDBGSleepMode
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_DisableDBGSleepMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_SLEEP);
}
/**
* @brief Enable the Debug Module during STOP mode
* @rmtoll DBGMCU_CR DBG_STOP LL_DBGMCU_EnableDBGStopMode
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_EnableDBGStopMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STOP);
}
/**
* @brief Disable the Debug Module during STOP mode
* @rmtoll DBGMCU_CR DBG_STOP LL_DBGMCU_DisableDBGStopMode
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_DisableDBGStopMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STOP);
}
/**
* @brief Enable the Debug Module during STANDBY mode
* @rmtoll DBGMCU_CR DBG_STANDBY LL_DBGMCU_EnableDBGStandbyMode
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_EnableDBGStandbyMode(void)
{
SET_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STANDBY);
}
/**
* @brief Disable the Debug Module during STANDBY mode
* @rmtoll DBGMCU_CR DBG_STANDBY LL_DBGMCU_DisableDBGStandbyMode
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_DisableDBGStandbyMode(void)
{
CLEAR_BIT(DBGMCU->CR, DBGMCU_CR_DBG_STANDBY);
}
/**
* @brief Set Trace pin assignment control
* @rmtoll DBGMCU_CR TRACE_IOEN LL_DBGMCU_SetTracePinAssignment\n
* DBGMCU_CR TRACE_MODE LL_DBGMCU_SetTracePinAssignment
* @param PinAssignment This parameter can be one of the following values:
* @arg @ref LL_DBGMCU_TRACE_NONE
* @arg @ref LL_DBGMCU_TRACE_ASYNCH
* @arg @ref LL_DBGMCU_TRACE_SYNCH_SIZE1
* @arg @ref LL_DBGMCU_TRACE_SYNCH_SIZE2
* @arg @ref LL_DBGMCU_TRACE_SYNCH_SIZE4
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_SetTracePinAssignment(uint32_t PinAssignment)
{
MODIFY_REG(DBGMCU->CR, DBGMCU_CR_TRACE_IOEN | DBGMCU_CR_TRACE_MODE, PinAssignment);
}
/**
* @brief Get Trace pin assignment control
* @rmtoll DBGMCU_CR TRACE_IOEN LL_DBGMCU_GetTracePinAssignment\n
* DBGMCU_CR TRACE_MODE LL_DBGMCU_GetTracePinAssignment
* @retval Returned value can be one of the following values:
* @arg @ref LL_DBGMCU_TRACE_NONE
* @arg @ref LL_DBGMCU_TRACE_ASYNCH
* @arg @ref LL_DBGMCU_TRACE_SYNCH_SIZE1
* @arg @ref LL_DBGMCU_TRACE_SYNCH_SIZE2
* @arg @ref LL_DBGMCU_TRACE_SYNCH_SIZE4
*/
__STATIC_INLINE uint32_t LL_DBGMCU_GetTracePinAssignment(void)
{
return (uint32_t)(READ_BIT(DBGMCU->CR, DBGMCU_CR_TRACE_IOEN | DBGMCU_CR_TRACE_MODE));
}
/**
* @brief Freeze APB1 peripherals (group1 peripherals)
* @rmtoll DBGMCU_APB1FZR1 DBG_xxxx_STOP LL_DBGMCU_APB1_GRP1_FreezePeriph
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM2_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM3_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM4_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM5_STOP (*)
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM6_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM7_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_RTC_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_WWDG_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_IWDG_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_I2C1_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_I2C2_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_I2C3_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_LPTIM1_STOP
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_APB1_GRP1_FreezePeriph(uint32_t Periphs)
{
SET_BIT(DBGMCU->APB1FZR1, Periphs);
}
/**
* @brief Freeze APB1 peripherals (group2 peripherals)
* @rmtoll DBGMCU_APB1FZR2 DBG_xxxx_STOP LL_DBGMCU_APB1_GRP2_FreezePeriph
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_DBGMCU_APB1_GRP2_I2C4_STOP (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_APB1_GRP2_FreezePeriph(uint32_t Periphs)
{
SET_BIT(DBGMCU->APB1FZR2, Periphs);
}
/**
* @brief Unfreeze APB1 peripherals (group1 peripherals)
* @rmtoll DBGMCU_APB1FZR1 DBG_xxxx_STOP LL_DBGMCU_APB1_GRP1_UnFreezePeriph
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM2_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM3_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM4_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM5_STOP (*)
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM6_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_TIM7_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_RTC_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_WWDG_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_IWDG_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_I2C1_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_I2C2_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_I2C3_STOP
* @arg @ref LL_DBGMCU_APB1_GRP1_LPTIM1_STOP
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_APB1_GRP1_UnFreezePeriph(uint32_t Periphs)
{
CLEAR_BIT(DBGMCU->APB1FZR1, Periphs);
}
/**
* @brief Unfreeze APB1 peripherals (group2 peripherals)
* @rmtoll DBGMCU_APB1FZR2 DBG_xxxx_STOP LL_DBGMCU_APB1_GRP2_UnFreezePeriph
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_DBGMCU_APB1_GRP2_I2C4_STOP (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_APB1_GRP2_UnFreezePeriph(uint32_t Periphs)
{
CLEAR_BIT(DBGMCU->APB1FZR2, Periphs);
}
/**
* @brief Freeze APB2 peripherals
* @rmtoll DBGMCU_APB2FZ DBG_TIMx_STOP LL_DBGMCU_APB2_GRP1_FreezePeriph
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM1_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM8_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM15_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM16_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM17_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM20_STOP (*)
* @arg @ref LL_DBGMCU_APB2_GRP1_HRTIM1_STOP (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_APB2_GRP1_FreezePeriph(uint32_t Periphs)
{
SET_BIT(DBGMCU->APB2FZ, Periphs);
}
/**
* @brief Unfreeze APB2 peripherals
* @rmtoll DBGMCU_APB2FZ DBG_TIMx_STOP LL_DBGMCU_APB2_GRP1_UnFreezePeriph
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM1_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM8_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM15_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM16_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM17_STOP
* @arg @ref LL_DBGMCU_APB2_GRP1_TIM20_STOP (*)
* @arg @ref LL_DBGMCU_APB2_GRP1_HRTIM1_STOP (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_DBGMCU_APB2_GRP1_UnFreezePeriph(uint32_t Periphs)
{
CLEAR_BIT(DBGMCU->APB2FZ, Periphs);
}
/**
* @}
*/
#if defined(VREFBUF)
/** @defgroup SYSTEM_LL_EF_VREFBUF VREFBUF
* @{
*/
/**
* @brief Enable Internal voltage reference
* @rmtoll VREFBUF_CSR ENVR LL_VREFBUF_Enable
* @retval None
*/
__STATIC_INLINE void LL_VREFBUF_Enable(void)
{
SET_BIT(VREFBUF->CSR, VREFBUF_CSR_ENVR);
}
/**
* @brief Disable Internal voltage reference
* @rmtoll VREFBUF_CSR ENVR LL_VREFBUF_Disable
* @retval None
*/
__STATIC_INLINE void LL_VREFBUF_Disable(void)
{
CLEAR_BIT(VREFBUF->CSR, VREFBUF_CSR_ENVR);
}
/**
* @brief Enable high impedance (VREF+pin is high impedance)
* @rmtoll VREFBUF_CSR HIZ LL_VREFBUF_EnableHIZ
* @retval None
*/
__STATIC_INLINE void LL_VREFBUF_EnableHIZ(void)
{
SET_BIT(VREFBUF->CSR, VREFBUF_CSR_HIZ);
}
/**
* @brief Disable high impedance (VREF+pin is internally connected to the voltage reference buffer output)
* @rmtoll VREFBUF_CSR HIZ LL_VREFBUF_DisableHIZ
* @retval None
*/
__STATIC_INLINE void LL_VREFBUF_DisableHIZ(void)
{
CLEAR_BIT(VREFBUF->CSR, VREFBUF_CSR_HIZ);
}
/**
* @brief Set the Voltage reference scale
* @rmtoll VREFBUF_CSR VRS LL_VREFBUF_SetVoltageScaling
* @param Scale This parameter can be one of the following values:
* @arg @ref LL_VREFBUF_VOLTAGE_SCALE0
* @arg @ref LL_VREFBUF_VOLTAGE_SCALE1
* @arg @ref LL_VREFBUF_VOLTAGE_SCALE2
* @retval None
*/
__STATIC_INLINE void LL_VREFBUF_SetVoltageScaling(uint32_t Scale)
{
MODIFY_REG(VREFBUF->CSR, VREFBUF_CSR_VRS, Scale);
}
/**
* @brief Get the Voltage reference scale
* @rmtoll VREFBUF_CSR VRS LL_VREFBUF_GetVoltageScaling
* @retval Returned value can be one of the following values:
* @arg @ref LL_VREFBUF_VOLTAGE_SCALE0
* @arg @ref LL_VREFBUF_VOLTAGE_SCALE1
* @arg @ref LL_VREFBUF_VOLTAGE_SCALE2
*/
__STATIC_INLINE uint32_t LL_VREFBUF_GetVoltageScaling(void)
{
return (uint32_t)(READ_BIT(VREFBUF->CSR, VREFBUF_CSR_VRS));
}
/**
* @brief Check if Voltage reference buffer is ready
* @rmtoll VREFBUF_CSR VRR LL_VREFBUF_IsVREFReady
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_VREFBUF_IsVREFReady(void)
{
return ((READ_BIT(VREFBUF->CSR, VREFBUF_CSR_VRR) == (VREFBUF_CSR_VRR)) ? 1UL : 0UL);
}
/**
* @brief Get the trimming code for VREFBUF calibration
* @rmtoll VREFBUF_CCR TRIM LL_VREFBUF_GetTrimming
* @retval Between 0 and 0x3F
*/
__STATIC_INLINE uint32_t LL_VREFBUF_GetTrimming(void)
{
return (uint32_t)(READ_BIT(VREFBUF->CCR, VREFBUF_CCR_TRIM));
}
/**
* @brief Set the trimming code for VREFBUF calibration (Tune the internal reference buffer voltage)
* @rmtoll VREFBUF_CCR TRIM LL_VREFBUF_SetTrimming
* @param Value Between 0 and 0x3F
* @retval None
*/
__STATIC_INLINE void LL_VREFBUF_SetTrimming(uint32_t Value)
{
WRITE_REG(VREFBUF->CCR, Value);
}
/**
* @}
*/
#endif /* VREFBUF */
/** @defgroup SYSTEM_LL_EF_FLASH FLASH
* @{
*/
/**
* @brief Set FLASH Latency
* @rmtoll FLASH_ACR LATENCY LL_FLASH_SetLatency
* @param Latency This parameter can be one of the following values:
* @arg @ref LL_FLASH_LATENCY_0
* @arg @ref LL_FLASH_LATENCY_1
* @arg @ref LL_FLASH_LATENCY_2
* @arg @ref LL_FLASH_LATENCY_3
* @arg @ref LL_FLASH_LATENCY_4
* @arg @ref LL_FLASH_LATENCY_5 (*)
* @arg @ref LL_FLASH_LATENCY_6 (*)
* @arg @ref LL_FLASH_LATENCY_7 (*)
* @arg @ref LL_FLASH_LATENCY_8 (*)
* @arg @ref LL_FLASH_LATENCY_9 (*)
* @arg @ref LL_FLASH_LATENCY_10 (*)
* @arg @ref LL_FLASH_LATENCY_11 (*)
* @arg @ref LL_FLASH_LATENCY_12 (*)
* @arg @ref LL_FLASH_LATENCY_13 (*)
* @arg @ref LL_FLASH_LATENCY_14 (*)
* @arg @ref LL_FLASH_LATENCY_15 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_FLASH_SetLatency(uint32_t Latency)
{
MODIFY_REG(FLASH->ACR, FLASH_ACR_LATENCY, Latency);
}
/**
* @brief Get FLASH Latency
* @rmtoll FLASH_ACR LATENCY LL_FLASH_GetLatency
* @retval Returned value can be one of the following values:
* @arg @ref LL_FLASH_LATENCY_0
* @arg @ref LL_FLASH_LATENCY_1
* @arg @ref LL_FLASH_LATENCY_2
* @arg @ref LL_FLASH_LATENCY_3
* @arg @ref LL_FLASH_LATENCY_4
* @arg @ref LL_FLASH_LATENCY_5 (*)
* @arg @ref LL_FLASH_LATENCY_6 (*)
* @arg @ref LL_FLASH_LATENCY_7 (*)
* @arg @ref LL_FLASH_LATENCY_8 (*)
* @arg @ref LL_FLASH_LATENCY_9 (*)
* @arg @ref LL_FLASH_LATENCY_10 (*)
* @arg @ref LL_FLASH_LATENCY_11 (*)
* @arg @ref LL_FLASH_LATENCY_12 (*)
* @arg @ref LL_FLASH_LATENCY_13 (*)
* @arg @ref LL_FLASH_LATENCY_14 (*)
* @arg @ref LL_FLASH_LATENCY_15 (*)
*
* (*) value not defined in all devices.
*/
__STATIC_INLINE uint32_t LL_FLASH_GetLatency(void)
{
return (uint32_t)(READ_BIT(FLASH->ACR, FLASH_ACR_LATENCY));
}
/**
* @brief Enable Prefetch
* @rmtoll FLASH_ACR PRFTEN LL_FLASH_EnablePrefetch
* @retval None
*/
__STATIC_INLINE void LL_FLASH_EnablePrefetch(void)
{
SET_BIT(FLASH->ACR, FLASH_ACR_PRFTEN);
}
/**
* @brief Disable Prefetch
* @rmtoll FLASH_ACR PRFTEN LL_FLASH_DisablePrefetch
* @retval None
*/
__STATIC_INLINE void LL_FLASH_DisablePrefetch(void)
{
CLEAR_BIT(FLASH->ACR, FLASH_ACR_PRFTEN);
}
/**
* @brief Check if Prefetch buffer is enabled
* @rmtoll FLASH_ACR PRFTEN LL_FLASH_IsPrefetchEnabled
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_FLASH_IsPrefetchEnabled(void)
{
return ((READ_BIT(FLASH->ACR, FLASH_ACR_PRFTEN) == (FLASH_ACR_PRFTEN)) ? 1UL : 0UL);
}
/**
* @brief Enable Instruction cache
* @rmtoll FLASH_ACR ICEN LL_FLASH_EnableInstCache
* @retval None
*/
__STATIC_INLINE void LL_FLASH_EnableInstCache(void)
{
SET_BIT(FLASH->ACR, FLASH_ACR_ICEN);
}
/**
* @brief Disable Instruction cache
* @rmtoll FLASH_ACR ICEN LL_FLASH_DisableInstCache
* @retval None
*/
__STATIC_INLINE void LL_FLASH_DisableInstCache(void)
{
CLEAR_BIT(FLASH->ACR, FLASH_ACR_ICEN);
}
/**
* @brief Enable Data cache
* @rmtoll FLASH_ACR DCEN LL_FLASH_EnableDataCache
* @retval None
*/
__STATIC_INLINE void LL_FLASH_EnableDataCache(void)
{
SET_BIT(FLASH->ACR, FLASH_ACR_DCEN);
}
/**
* @brief Disable Data cache
* @rmtoll FLASH_ACR DCEN LL_FLASH_DisableDataCache
* @retval None
*/
__STATIC_INLINE void LL_FLASH_DisableDataCache(void)
{
CLEAR_BIT(FLASH->ACR, FLASH_ACR_DCEN);
}
/**
* @brief Enable Instruction cache reset
* @note bit can be written only when the instruction cache is disabled
* @rmtoll FLASH_ACR ICRST LL_FLASH_EnableInstCacheReset
* @retval None
*/
__STATIC_INLINE void LL_FLASH_EnableInstCacheReset(void)
{
SET_BIT(FLASH->ACR, FLASH_ACR_ICRST);
}
/**
* @brief Disable Instruction cache reset
* @rmtoll FLASH_ACR ICRST LL_FLASH_DisableInstCacheReset
* @retval None
*/
__STATIC_INLINE void LL_FLASH_DisableInstCacheReset(void)
{
CLEAR_BIT(FLASH->ACR, FLASH_ACR_ICRST);
}
/**
* @brief Enable Data cache reset
* @note bit can be written only when the data cache is disabled
* @rmtoll FLASH_ACR DCRST LL_FLASH_EnableDataCacheReset
* @retval None
*/
__STATIC_INLINE void LL_FLASH_EnableDataCacheReset(void)
{
SET_BIT(FLASH->ACR, FLASH_ACR_DCRST);
}
/**
* @brief Disable Data cache reset
* @rmtoll FLASH_ACR DCRST LL_FLASH_DisableDataCacheReset
* @retval None
*/
__STATIC_INLINE void LL_FLASH_DisableDataCacheReset(void)
{
CLEAR_BIT(FLASH->ACR, FLASH_ACR_DCRST);
}
/**
* @brief Enable Flash Power-down mode during run mode or Low-power run mode
* @note Flash memory can be put in power-down mode only when the code is executed
* from RAM
* @note Flash must not be accessed when power down is enabled
* @note Flash must not be put in power-down while a program or an erase operation
* is on-going
* @rmtoll FLASH_ACR RUN_PD LL_FLASH_EnableRunPowerDown\n
* FLASH_PDKEYR PDKEY1 LL_FLASH_EnableRunPowerDown\n
* FLASH_PDKEYR PDKEY2 LL_FLASH_EnableRunPowerDown
* @retval None
*/
__STATIC_INLINE void LL_FLASH_EnableRunPowerDown(void)
{
/* Following values must be written consecutively to unlock the RUN_PD bit in
FLASH_ACR */
WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY1);
WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY2);
SET_BIT(FLASH->ACR, FLASH_ACR_RUN_PD);
}
/**
* @brief Disable Flash Power-down mode during run mode or Low-power run mode
* @rmtoll FLASH_ACR RUN_PD LL_FLASH_DisableRunPowerDown\n
* FLASH_PDKEYR PDKEY1 LL_FLASH_DisableRunPowerDown\n
* FLASH_PDKEYR PDKEY2 LL_FLASH_DisableRunPowerDown
* @retval None
*/
__STATIC_INLINE void LL_FLASH_DisableRunPowerDown(void)
{
/* Following values must be written consecutively to unlock the RUN_PD bit in
FLASH_ACR */
WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY1);
WRITE_REG(FLASH->PDKEYR, FLASH_PDKEY2);
CLEAR_BIT(FLASH->ACR, FLASH_ACR_RUN_PD);
}
/**
* @brief Enable Flash Power-down mode during Sleep or Low-power sleep mode
* @note Flash must not be put in power-down while a program or an erase operation
* is on-going
* @rmtoll FLASH_ACR SLEEP_PD LL_FLASH_EnableSleepPowerDown
* @retval None
*/
__STATIC_INLINE void LL_FLASH_EnableSleepPowerDown(void)
{
SET_BIT(FLASH->ACR, FLASH_ACR_SLEEP_PD);
}
/**
* @brief Disable Flash Power-down mode during Sleep or Low-power sleep mode
* @rmtoll FLASH_ACR SLEEP_PD LL_FLASH_DisableSleepPowerDown
* @retval None
*/
__STATIC_INLINE void LL_FLASH_DisableSleepPowerDown(void)
{
CLEAR_BIT(FLASH->ACR, FLASH_ACR_SLEEP_PD);
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* defined (FLASH) || defined (SYSCFG) || defined (DBGMCU) || defined (VREFBUF) */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_LL_SYSTEM_H */
| 59,149 | C | 37.99143 | 167 | 0.624136 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_def.h | /**
******************************************************************************
* @file stm32g4xx_hal_def.h
* @author MCD Application Team
* @brief This file contains HAL common defines, enumeration, macros and
* structures definitions.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_HAL_DEF
#define __STM32G4xx_HAL_DEF
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
#include "Legacy/stm32_hal_legacy.h" /* Aliases file for old names compatibility */
#include <stddef.h>
/* Exported types ------------------------------------------------------------*/
/**
* @brief HAL Status structures definition
*/
typedef enum
{
HAL_OK = 0x00U,
HAL_ERROR = 0x01U,
HAL_BUSY = 0x02U,
HAL_TIMEOUT = 0x03U
} HAL_StatusTypeDef;
/**
* @brief HAL Lock structures definition
*/
typedef enum
{
HAL_UNLOCKED = 0x00U,
HAL_LOCKED = 0x01U
} HAL_LockTypeDef;
/* Exported macros -----------------------------------------------------------*/
#define HAL_MAX_DELAY 0xFFFFFFFFU
#define HAL_IS_BIT_SET(REG, BIT) (((REG) & (BIT)) == (BIT))
#define HAL_IS_BIT_CLR(REG, BIT) (((REG) & (BIT)) == 0U)
#define __HAL_LINKDMA(__HANDLE__, __PPP_DMA_FIELD__, __DMA_HANDLE__) \
do{ \
(__HANDLE__)->__PPP_DMA_FIELD__ = &(__DMA_HANDLE__); \
(__DMA_HANDLE__).Parent = (__HANDLE__); \
} while(0)
#if !defined(UNUSED)
#define UNUSED(X) (void)X /* To avoid gcc/g++ warnings */
#endif /* UNUSED */
/** @brief Reset the Handle's State field.
* @param __HANDLE__: specifies the Peripheral Handle.
* @note This macro can be used for the following purpose:
* - When the Handle is declared as local variable; before passing it as parameter
* to HAL_PPP_Init() for the first time, it is mandatory to use this macro
* to set to 0 the Handle's "State" field.
* Otherwise, "State" field may have any random value and the first time the function
* HAL_PPP_Init() is called, the low level hardware initialization will be missed
* (i.e. HAL_PPP_MspInit() will not be executed).
* - When there is a need to reconfigure the low level hardware: instead of calling
* HAL_PPP_DeInit() then HAL_PPP_Init(), user can make a call to this macro then HAL_PPP_Init().
* In this later function, when the Handle's "State" field is set to 0, it will execute the function
* HAL_PPP_MspInit() which will reconfigure the low level hardware.
* @retval None
*/
#define __HAL_RESET_HANDLE_STATE(__HANDLE__) ((__HANDLE__)->State = 0)
#if (USE_RTOS == 1U)
/* Reserved for future use */
#error " USE_RTOS should be 0 in the current HAL release "
#else
#define __HAL_LOCK(__HANDLE__) \
do{ \
if((__HANDLE__)->Lock == HAL_LOCKED) \
{ \
return HAL_BUSY; \
} \
else \
{ \
(__HANDLE__)->Lock = HAL_LOCKED; \
} \
}while (0U)
#define __HAL_UNLOCK(__HANDLE__) \
do{ \
(__HANDLE__)->Lock = HAL_UNLOCKED; \
}while (0U)
#endif /* USE_RTOS */
#if defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050) /* ARM Compiler V6 */
#ifndef __weak
#define __weak __attribute__((weak))
#endif
#ifndef __packed
#define __packed __attribute__((packed))
#endif
#elif defined ( __GNUC__ ) && !defined (__CC_ARM) /* GNU Compiler */
#ifndef __weak
#define __weak __attribute__((weak))
#endif /* __weak */
#ifndef __packed
#define __packed __attribute__((__packed__))
#endif /* __packed */
#endif /* __GNUC__ */
/* Macro to get variable aligned on 4-bytes, for __ICCARM__ the directive "#pragma data_alignment=4" must be used instead */
#if defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050) /* ARM Compiler V6 */
#ifndef __ALIGN_BEGIN
#define __ALIGN_BEGIN
#endif
#ifndef __ALIGN_END
#define __ALIGN_END __attribute__ ((aligned (4)))
#endif
#elif defined ( __GNUC__ ) && !defined (__CC_ARM) /* GNU Compiler */
#ifndef __ALIGN_END
#define __ALIGN_END __attribute__ ((aligned (4U)))
#endif /* __ALIGN_END */
#ifndef __ALIGN_BEGIN
#define __ALIGN_BEGIN
#endif /* __ALIGN_BEGIN */
#else
#ifndef __ALIGN_END
#define __ALIGN_END
#endif /* __ALIGN_END */
#ifndef __ALIGN_BEGIN
#if defined (__CC_ARM) /* ARM Compiler V5*/
#define __ALIGN_BEGIN __align(4U)
#elif defined (__ICCARM__) /* IAR Compiler */
#define __ALIGN_BEGIN
#endif /* __CC_ARM */
#endif /* __ALIGN_BEGIN */
#endif /* __GNUC__ */
/**
* @brief __RAM_FUNC definition
*/
#if defined ( __CC_ARM ) || (defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050))
/* ARM Compiler V4/V5 and V6
--------------------------
RAM functions are defined using the toolchain options.
Functions that are executed in RAM should reside in a separate source module.
Using the 'Options for File' dialog you can simply change the 'Code / Const'
area of a module to a memory space in physical RAM.
Available memory areas are declared in the 'Target' tab of the 'Options for Target'
dialog.
*/
#define __RAM_FUNC
#elif defined ( __ICCARM__ )
/* ICCARM Compiler
---------------
RAM functions are defined using a specific toolchain keyword "__ramfunc".
*/
#define __RAM_FUNC __ramfunc
#elif defined ( __GNUC__ )
/* GNU Compiler
------------
RAM functions are defined using a specific toolchain attribute
"__attribute__((section(".RamFunc")))".
*/
#define __RAM_FUNC __attribute__((section(".RamFunc")))
#endif /* __CC_ARM */
/**
* @brief __NOINLINE definition
*/
#if defined ( __CC_ARM ) || (defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)) || defined ( __GNUC__ )
/* ARM V4/V5 and V6 & GNU Compiler
-------------------------------
*/
#define __NOINLINE __attribute__ ( (noinline) )
#elif defined ( __ICCARM__ )
/* ICCARM Compiler
---------------
*/
#define __NOINLINE _Pragma("optimize = no_inline")
#endif /* __CC_ARM || __GNUC__ */
#ifdef __cplusplus
}
#endif
#endif /* ___STM32G4xx_HAL_DEF */
| 6,966 | C | 31.863207 | 124 | 0.533305 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_gpio.h | /**
******************************************************************************
* @file stm32g4xx_hal_gpio.h
* @author MCD Application Team
* @brief Header file of GPIO HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_GPIO_H
#define STM32G4xx_HAL_GPIO_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup GPIO GPIO
* @brief GPIO HAL module driver
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup GPIO_Exported_Types GPIO Exported Types
* @{
*/
/**
* @brief GPIO Init structure definition
*/
typedef struct
{
uint32_t Pin; /*!< Specifies the GPIO pins to be configured.
This parameter can be any value of @ref GPIO_pins */
uint32_t Mode; /*!< Specifies the operating mode for the selected pins.
This parameter can be a value of @ref GPIO_mode */
uint32_t Pull; /*!< Specifies the Pull-up or Pull-Down activation for the selected pins.
This parameter can be a value of @ref GPIO_pull */
uint32_t Speed; /*!< Specifies the speed for the selected pins.
This parameter can be a value of @ref GPIO_speed */
uint32_t Alternate; /*!< Peripheral to be connected to the selected pins
This parameter can be a value of @ref GPIOEx_Alternate_function_selection */
} GPIO_InitTypeDef;
/**
* @brief GPIO Bit SET and Bit RESET enumeration
*/
typedef enum
{
GPIO_PIN_RESET = 0U,
GPIO_PIN_SET
} GPIO_PinState;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup GPIO_Exported_Constants GPIO Exported Constants
* @{
*/
/** @defgroup GPIO_pins GPIO pins
* @{
*/
#define GPIO_PIN_0 ((uint16_t)0x0001) /* Pin 0 selected */
#define GPIO_PIN_1 ((uint16_t)0x0002) /* Pin 1 selected */
#define GPIO_PIN_2 ((uint16_t)0x0004) /* Pin 2 selected */
#define GPIO_PIN_3 ((uint16_t)0x0008) /* Pin 3 selected */
#define GPIO_PIN_4 ((uint16_t)0x0010) /* Pin 4 selected */
#define GPIO_PIN_5 ((uint16_t)0x0020) /* Pin 5 selected */
#define GPIO_PIN_6 ((uint16_t)0x0040) /* Pin 6 selected */
#define GPIO_PIN_7 ((uint16_t)0x0080) /* Pin 7 selected */
#define GPIO_PIN_8 ((uint16_t)0x0100) /* Pin 8 selected */
#define GPIO_PIN_9 ((uint16_t)0x0200) /* Pin 9 selected */
#define GPIO_PIN_10 ((uint16_t)0x0400) /* Pin 10 selected */
#define GPIO_PIN_11 ((uint16_t)0x0800) /* Pin 11 selected */
#define GPIO_PIN_12 ((uint16_t)0x1000) /* Pin 12 selected */
#define GPIO_PIN_13 ((uint16_t)0x2000) /* Pin 13 selected */
#define GPIO_PIN_14 ((uint16_t)0x4000) /* Pin 14 selected */
#define GPIO_PIN_15 ((uint16_t)0x8000) /* Pin 15 selected */
#define GPIO_PIN_All ((uint16_t)0xFFFF) /* All pins selected */
#define GPIO_PIN_MASK (0x0000FFFFU) /* PIN mask for assert test */
/**
* @}
*/
/** @defgroup GPIO_mode GPIO mode
* @brief GPIO Configuration Mode
* Elements values convention: 0x00WX00YZ
* - W : EXTI trigger detection on 3 bits
* - X : EXTI mode (IT or Event) on 2 bits
* - Y : Output type (Push Pull or Open Drain) on 1 bit
* - Z : GPIO mode (Input, Output, Alternate or Analog) on 2 bits
* @{
*/
#define GPIO_MODE_INPUT MODE_INPUT /*!< Input Floating Mode */
#define GPIO_MODE_OUTPUT_PP (MODE_OUTPUT | OUTPUT_PP) /*!< Output Push Pull Mode */
#define GPIO_MODE_OUTPUT_OD (MODE_OUTPUT | OUTPUT_OD) /*!< Output Open Drain Mode */
#define GPIO_MODE_AF_PP (MODE_AF | OUTPUT_PP) /*!< Alternate Function Push Pull Mode */
#define GPIO_MODE_AF_OD (MODE_AF | OUTPUT_OD) /*!< Alternate Function Open Drain Mode */
#define GPIO_MODE_ANALOG MODE_ANALOG /*!< Analog Mode */
#define GPIO_MODE_IT_RISING (MODE_INPUT | EXTI_IT | TRIGGER_RISING) /*!< External Interrupt Mode with Rising edge trigger detection */
#define GPIO_MODE_IT_FALLING (MODE_INPUT | EXTI_IT | TRIGGER_FALLING) /*!< External Interrupt Mode with Falling edge trigger detection */
#define GPIO_MODE_IT_RISING_FALLING (MODE_INPUT | EXTI_IT | TRIGGER_RISING | TRIGGER_FALLING) /*!< External Interrupt Mode with Rising/Falling edge trigger detection */
#define GPIO_MODE_EVT_RISING (MODE_INPUT | EXTI_EVT | TRIGGER_RISING) /*!< External Event Mode with Rising edge trigger detection */
#define GPIO_MODE_EVT_FALLING (MODE_INPUT | EXTI_EVT | TRIGGER_FALLING) /*!< External Event Mode with Falling edge trigger detection */
#define GPIO_MODE_EVT_RISING_FALLING (MODE_INPUT | EXTI_EVT | TRIGGER_RISING | TRIGGER_FALLING) /*!< External Event Mode with Rising/Falling edge trigger detection */
/**
* @}
*/
/** @defgroup GPIO_speed GPIO speed
* @brief GPIO Output Maximum frequency
* @{
*/
#define GPIO_SPEED_FREQ_LOW (0x00000000U) /*!< range up to 5 MHz, please refer to the product datasheet */
#define GPIO_SPEED_FREQ_MEDIUM (0x00000001U) /*!< range 5 MHz to 25 MHz, please refer to the product datasheet */
#define GPIO_SPEED_FREQ_HIGH (0x00000002U) /*!< range 25 MHz to 50 MHz, please refer to the product datasheet */
#define GPIO_SPEED_FREQ_VERY_HIGH (0x00000003U) /*!< range 50 MHz to 120 MHz, please refer to the product datasheet */
/**
* @}
*/
/** @defgroup GPIO_pull GPIO pull
* @brief GPIO Pull-Up or Pull-Down Activation
* @{
*/
#define GPIO_NOPULL (0x00000000U) /*!< No Pull-up or Pull-down activation */
#define GPIO_PULLUP (0x00000001U) /*!< Pull-up activation */
#define GPIO_PULLDOWN (0x00000002U) /*!< Pull-down activation */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup GPIO_Exported_Macros GPIO Exported Macros
* @{
*/
/**
* @brief Check whether the specified EXTI line flag is set or not.
* @param __EXTI_LINE__ specifies the EXTI line flag to check.
* This parameter can be GPIO_PIN_x where x can be(0..15)
* @retval The new state of __EXTI_LINE__ (SET or RESET).
*/
#define __HAL_GPIO_EXTI_GET_FLAG(__EXTI_LINE__) (EXTI->PR1 & (__EXTI_LINE__))
/**
* @brief Clear the EXTI's line pending flags.
* @param __EXTI_LINE__ specifies the EXTI lines flags to clear.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15)
* @retval None
*/
#define __HAL_GPIO_EXTI_CLEAR_FLAG(__EXTI_LINE__) (EXTI->PR1 = (__EXTI_LINE__))
/**
* @brief Check whether the specified EXTI line is asserted or not.
* @param __EXTI_LINE__ specifies the EXTI line to check.
* This parameter can be GPIO_PIN_x where x can be(0..15)
* @retval The new state of __EXTI_LINE__ (SET or RESET).
*/
#define __HAL_GPIO_EXTI_GET_IT(__EXTI_LINE__) (EXTI->PR1 & (__EXTI_LINE__))
/**
* @brief Clear the EXTI's line pending bits.
* @param __EXTI_LINE__ specifies the EXTI lines to clear.
* This parameter can be any combination of GPIO_PIN_x where x can be (0..15)
* @retval None
*/
#define __HAL_GPIO_EXTI_CLEAR_IT(__EXTI_LINE__) (EXTI->PR1 = (__EXTI_LINE__))
/**
* @brief Generate a Software interrupt on selected EXTI line.
* @param __EXTI_LINE__ specifies the EXTI line to check.
* This parameter can be GPIO_PIN_x where x can be(0..15)
* @retval None
*/
#define __HAL_GPIO_EXTI_GENERATE_SWIT(__EXTI_LINE__) (EXTI->SWIER1 |= (__EXTI_LINE__))
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup GPIO_Private_Constants GPIO Private Constants
* @{
*/
#define GPIO_MODE_Pos 0U
#define GPIO_MODE (0x3UL << GPIO_MODE_Pos)
#define MODE_INPUT (0x0UL << GPIO_MODE_Pos)
#define MODE_OUTPUT (0x1UL << GPIO_MODE_Pos)
#define MODE_AF (0x2UL << GPIO_MODE_Pos)
#define MODE_ANALOG (0x3UL << GPIO_MODE_Pos)
#define OUTPUT_TYPE_Pos 4U
#define OUTPUT_TYPE (0x1UL << OUTPUT_TYPE_Pos)
#define OUTPUT_PP (0x0UL << OUTPUT_TYPE_Pos)
#define OUTPUT_OD (0x1UL << OUTPUT_TYPE_Pos)
#define EXTI_MODE_Pos 16U
#define EXTI_MODE (0x3UL << EXTI_MODE_Pos)
#define EXTI_IT (0x1UL << EXTI_MODE_Pos)
#define EXTI_EVT (0x2UL << EXTI_MODE_Pos)
#define TRIGGER_MODE_Pos 20U
#define TRIGGER_MODE (0x7UL << TRIGGER_MODE_Pos)
#define TRIGGER_RISING (0x1UL << TRIGGER_MODE_Pos)
#define TRIGGER_FALLING (0x2UL << TRIGGER_MODE_Pos)
/**
* @}
*/
/** @defgroup GPIO_Private_Macros GPIO Private Macros
* @{
*/
#define IS_GPIO_PIN_ACTION(ACTION) (((ACTION) == GPIO_PIN_RESET) || ((ACTION) == GPIO_PIN_SET))
#define IS_GPIO_PIN(__PIN__) ((((uint32_t)(__PIN__) & GPIO_PIN_MASK) != 0x00U) &&\
(((uint32_t)(__PIN__) & ~GPIO_PIN_MASK) == 0x00U))
#define IS_GPIO_MODE(__MODE__) (((__MODE__) == GPIO_MODE_INPUT) ||\
((__MODE__) == GPIO_MODE_OUTPUT_PP) ||\
((__MODE__) == GPIO_MODE_OUTPUT_OD) ||\
((__MODE__) == GPIO_MODE_AF_PP) ||\
((__MODE__) == GPIO_MODE_AF_OD) ||\
((__MODE__) == GPIO_MODE_IT_RISING) ||\
((__MODE__) == GPIO_MODE_IT_FALLING) ||\
((__MODE__) == GPIO_MODE_IT_RISING_FALLING) ||\
((__MODE__) == GPIO_MODE_EVT_RISING) ||\
((__MODE__) == GPIO_MODE_EVT_FALLING) ||\
((__MODE__) == GPIO_MODE_EVT_RISING_FALLING) ||\
((__MODE__) == GPIO_MODE_ANALOG))
#define IS_GPIO_SPEED(__SPEED__) (((__SPEED__) == GPIO_SPEED_FREQ_LOW) ||\
((__SPEED__) == GPIO_SPEED_FREQ_MEDIUM) ||\
((__SPEED__) == GPIO_SPEED_FREQ_HIGH) ||\
((__SPEED__) == GPIO_SPEED_FREQ_VERY_HIGH))
#define IS_GPIO_PULL(__PULL__) (((__PULL__) == GPIO_NOPULL) ||\
((__PULL__) == GPIO_PULLUP) || \
((__PULL__) == GPIO_PULLDOWN))
/**
* @}
*/
/* Include GPIO HAL Extended module */
#include "stm32g4xx_hal_gpio_ex.h"
/* Exported functions --------------------------------------------------------*/
/** @defgroup GPIO_Exported_Functions GPIO Exported Functions
* @brief GPIO Exported Functions
* @{
*/
/** @defgroup GPIO_Exported_Functions_Group1 Initialization/de-initialization functions
* @brief Initialization and Configuration functions
* @{
*/
/* Initialization and de-initialization functions *****************************/
void HAL_GPIO_Init(GPIO_TypeDef *GPIOx, GPIO_InitTypeDef *GPIO_Init);
void HAL_GPIO_DeInit(GPIO_TypeDef *GPIOx, uint32_t GPIO_Pin);
/**
* @}
*/
/** @defgroup GPIO_Exported_Functions_Group2 IO operation functions
* @brief IO operation functions
* @{
*/
/* IO operation functions *****************************************************/
GPIO_PinState HAL_GPIO_ReadPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin);
void HAL_GPIO_WritePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin, GPIO_PinState PinState);
void HAL_GPIO_TogglePin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin);
HAL_StatusTypeDef HAL_GPIO_LockPin(GPIO_TypeDef *GPIOx, uint16_t GPIO_Pin);
void HAL_GPIO_EXTI_IRQHandler(uint16_t GPIO_Pin);
void HAL_GPIO_EXTI_Callback(uint16_t GPIO_Pin);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_GPIO_H */
| 13,939 | C | 41.629969 | 183 | 0.496951 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_exti.h | /**
******************************************************************************
* @file stm32g4xx_hal_exti.h
* @author MCD Application Team
* @brief Header file of EXTI HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_EXTI_H
#define STM32G4xx_HAL_EXTI_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup EXTI EXTI
* @brief EXTI HAL module driver
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup EXTI_Exported_Types EXTI Exported Types
* @{
*/
typedef enum
{
HAL_EXTI_COMMON_CB_ID = 0x00UL
} EXTI_CallbackIDTypeDef;
/**
* @brief EXTI Handle structure definition
*/
typedef struct
{
uint32_t Line; /*!< Exti line number */
void (* PendingCallback)(void); /*!< Exti pending callback */
} EXTI_HandleTypeDef;
/**
* @brief EXTI Configuration structure definition
*/
typedef struct
{
uint32_t Line; /*!< The Exti line to be configured. This parameter
can be a value of @ref EXTI_Line */
uint32_t Mode; /*!< The Exit Mode to be configured for a core.
This parameter can be a combination of @ref EXTI_Mode */
uint32_t Trigger; /*!< The Exti Trigger to be configured. This parameter
can be a value of @ref EXTI_Trigger */
uint32_t GPIOSel; /*!< The Exti GPIO multiplexer selection to be configured.
This parameter is only possible for line 0 to 15. It
can be a value of @ref EXTI_GPIOSel */
} EXTI_ConfigTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup EXTI_Exported_Constants EXTI Exported Constants
* @{
*/
/** @defgroup EXTI_Line EXTI Line
* @{
*/
#define EXTI_LINE_0 (EXTI_GPIO | EXTI_REG1 | 0x00u)
#define EXTI_LINE_1 (EXTI_GPIO | EXTI_REG1 | 0x01u)
#define EXTI_LINE_2 (EXTI_GPIO | EXTI_REG1 | 0x02u)
#define EXTI_LINE_3 (EXTI_GPIO | EXTI_REG1 | 0x03u)
#define EXTI_LINE_4 (EXTI_GPIO | EXTI_REG1 | 0x04u)
#define EXTI_LINE_5 (EXTI_GPIO | EXTI_REG1 | 0x05u)
#define EXTI_LINE_6 (EXTI_GPIO | EXTI_REG1 | 0x06u)
#define EXTI_LINE_7 (EXTI_GPIO | EXTI_REG1 | 0x07u)
#define EXTI_LINE_8 (EXTI_GPIO | EXTI_REG1 | 0x08u)
#define EXTI_LINE_9 (EXTI_GPIO | EXTI_REG1 | 0x09u)
#define EXTI_LINE_10 (EXTI_GPIO | EXTI_REG1 | 0x0Au)
#define EXTI_LINE_11 (EXTI_GPIO | EXTI_REG1 | 0x0Bu)
#define EXTI_LINE_12 (EXTI_GPIO | EXTI_REG1 | 0x0Cu)
#define EXTI_LINE_13 (EXTI_GPIO | EXTI_REG1 | 0x0Du)
#define EXTI_LINE_14 (EXTI_GPIO | EXTI_REG1 | 0x0Eu)
#define EXTI_LINE_15 (EXTI_GPIO | EXTI_REG1 | 0x0Fu)
#define EXTI_LINE_16 (EXTI_CONFIG | EXTI_REG1 | 0x10u)
#define EXTI_LINE_17 (EXTI_CONFIG | EXTI_REG1 | 0x11u)
#define EXTI_LINE_18 (EXTI_DIRECT | EXTI_REG1 | 0x12u)
#define EXTI_LINE_19 (EXTI_CONFIG | EXTI_REG1 | 0x13u)
#define EXTI_LINE_20 (EXTI_CONFIG | EXTI_REG1 | 0x14u)
#define EXTI_LINE_21 (EXTI_CONFIG | EXTI_REG1 | 0x15u)
#define EXTI_LINE_22 (EXTI_CONFIG | EXTI_REG1 | 0x16u)
#define EXTI_LINE_23 (EXTI_DIRECT | EXTI_REG1 | 0x17u)
#define EXTI_LINE_24 (EXTI_DIRECT | EXTI_REG1 | 0x18u)
#define EXTI_LINE_25 (EXTI_DIRECT | EXTI_REG1 | 0x19u)
#define EXTI_LINE_26 (EXTI_DIRECT | EXTI_REG1 | 0x1Au)
#define EXTI_LINE_27 (EXTI_DIRECT | EXTI_REG1 | 0x1Bu)
#define EXTI_LINE_28 (EXTI_DIRECT | EXTI_REG1 | 0x1Cu)
#define EXTI_LINE_29 (EXTI_CONFIG | EXTI_REG1 | 0x1Du)
#define EXTI_LINE_30 (EXTI_CONFIG | EXTI_REG1 | 0x1Eu)
#define EXTI_LINE_31 (EXTI_CONFIG | EXTI_REG1 | 0x1Fu)
#define EXTI_LINE_32 (EXTI_CONFIG | EXTI_REG2 | 0x00u)
#define EXTI_LINE_33 (EXTI_CONFIG | EXTI_REG2 | 0x01u)
#define EXTI_LINE_34 (EXTI_DIRECT | EXTI_REG2 | 0x02u)
#define EXTI_LINE_35 (EXTI_DIRECT | EXTI_REG2 | 0x03u)
#define EXTI_LINE_36 (EXTI_DIRECT | EXTI_REG2 | 0x04u)
#define EXTI_LINE_37 (EXTI_DIRECT | EXTI_REG2 | 0x05u)
#define EXTI_LINE_38 (EXTI_CONFIG | EXTI_REG2 | 0x06u)
#define EXTI_LINE_39 (EXTI_CONFIG | EXTI_REG2 | 0x07u)
#define EXTI_LINE_40 (EXTI_CONFIG | EXTI_REG2 | 0x08u)
#define EXTI_LINE_41 (EXTI_CONFIG | EXTI_REG2 | 0x09u)
#define EXTI_LINE_42 (EXTI_DIRECT | EXTI_REG2 | 0x0Au)
#define EXTI_LINE_43 (EXTI_DIRECT | EXTI_REG2 | 0x0Bu)
/**
* @}
*/
/** @defgroup EXTI_Mode EXTI Mode
* @{
*/
#define EXTI_MODE_NONE 0x00000000U
#define EXTI_MODE_INTERRUPT 0x00000001U
#define EXTI_MODE_EVENT 0x00000002U
/**
* @}
*/
/** @defgroup EXTI_Trigger EXTI Trigger
* @{
*/
#define EXTI_TRIGGER_NONE 0x00000000U
#define EXTI_TRIGGER_RISING 0x00000001U
#define EXTI_TRIGGER_FALLING 0x00000002U
#define EXTI_TRIGGER_RISING_FALLING (EXTI_TRIGGER_RISING | EXTI_TRIGGER_FALLING)
/**
* @}
*/
/** @defgroup EXTI_GPIOSel EXTI GPIOSel
* @brief
* @{
*/
#define EXTI_GPIOA 0x00000000U
#define EXTI_GPIOB 0x00000001U
#define EXTI_GPIOC 0x00000002U
#define EXTI_GPIOD 0x00000003U
#define EXTI_GPIOE 0x00000004U
#define EXTI_GPIOF 0x00000005U
#define EXTI_GPIOG 0x00000006U
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup EXTI_Exported_Macros EXTI Exported Macros
* @{
*/
/**
* @}
*/
/* Private constants --------------------------------------------------------*/
/** @defgroup EXTI_Private_Constants EXTI Private Constants
* @{
*/
/**
* @brief EXTI Line property definition
*/
#define EXTI_PROPERTY_SHIFT 24U
#define EXTI_DIRECT (0x01uL << EXTI_PROPERTY_SHIFT)
#define EXTI_CONFIG (0x02uL << EXTI_PROPERTY_SHIFT)
#define EXTI_GPIO ((0x04uL << EXTI_PROPERTY_SHIFT) | EXTI_CONFIG)
#define EXTI_RESERVED (0x08uL << EXTI_PROPERTY_SHIFT)
#define EXTI_PROPERTY_MASK (EXTI_DIRECT | EXTI_CONFIG | EXTI_GPIO)
/**
* @brief EXTI Register and bit usage
*/
#define EXTI_REG_SHIFT 16U
#define EXTI_REG1 (0x00uL << EXTI_REG_SHIFT)
#define EXTI_REG2 (0x01uL << EXTI_REG_SHIFT)
#define EXTI_REG_MASK (EXTI_REG1 | EXTI_REG2)
#define EXTI_PIN_MASK 0x0000001FU
/**
* @brief EXTI Mask for interrupt & event mode
*/
#define EXTI_MODE_MASK (EXTI_MODE_EVENT | EXTI_MODE_INTERRUPT)
/**
* @brief EXTI Mask for trigger possibilities
*/
#define EXTI_TRIGGER_MASK (EXTI_TRIGGER_RISING | EXTI_TRIGGER_FALLING)
/**
* @brief EXTI Line number
*/
#define EXTI_LINE_NB 44UL
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup EXTI_Private_Macros EXTI Private Macros
* @{
*/
#define IS_EXTI_LINE(__EXTI_LINE__) ((((__EXTI_LINE__) & ~(EXTI_PROPERTY_MASK | EXTI_REG_MASK | EXTI_PIN_MASK)) == 0x00U) && \
((((__EXTI_LINE__) & EXTI_PROPERTY_MASK) == EXTI_DIRECT) || \
(((__EXTI_LINE__) & EXTI_PROPERTY_MASK) == EXTI_CONFIG) || \
(((__EXTI_LINE__) & EXTI_PROPERTY_MASK) == EXTI_GPIO)) && \
(((__EXTI_LINE__) & (EXTI_REG_MASK | EXTI_PIN_MASK)) < \
(((EXTI_LINE_NB / 32u) << EXTI_REG_SHIFT) | (EXTI_LINE_NB % 32u))))
#define IS_EXTI_MODE(__EXTI_LINE__) ((((__EXTI_LINE__) & EXTI_MODE_MASK) != 0x00U) && \
(((__EXTI_LINE__) & ~EXTI_MODE_MASK) == 0x00U))
#define IS_EXTI_TRIGGER(__EXTI_LINE__) (((__EXTI_LINE__) & ~EXTI_TRIGGER_MASK) == 0x00U)
#define IS_EXTI_CONFIG_LINE(__EXTI_LINE__) (((__EXTI_LINE__) & EXTI_CONFIG) != 0x00U)
#define IS_EXTI_GPIO_PORT(__PORT__) (((__PORT__) == EXTI_GPIOA) || \
((__PORT__) == EXTI_GPIOB) || \
((__PORT__) == EXTI_GPIOC) || \
((__PORT__) == EXTI_GPIOD) || \
((__PORT__) == EXTI_GPIOE) || \
((__PORT__) == EXTI_GPIOF) || \
((__PORT__) == EXTI_GPIOG))
#define IS_EXTI_GPIO_PIN(__PIN__) ((__PIN__) < 16u)
#define IS_EXTI_PENDING_EDGE(__EDGE__) (((__EDGE__) == EXTI_TRIGGER_RISING) || \
((__EDGE__) == EXTI_TRIGGER_FALLING)|| \
((__EDGE__) == EXTI_TRIGGER_RISING_FALLING))
#define IS_EXTI_CB(__CB__) ((__CB__) == HAL_EXTI_COMMON_CB_ID)
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup EXTI_Exported_Functions EXTI Exported Functions
* @brief EXTI Exported Functions
* @{
*/
/** @defgroup EXTI_Exported_Functions_Group1 Configuration functions
* @brief Configuration functions
* @{
*/
/* Configuration functions ****************************************************/
HAL_StatusTypeDef HAL_EXTI_SetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig);
HAL_StatusTypeDef HAL_EXTI_GetConfigLine(EXTI_HandleTypeDef *hexti, EXTI_ConfigTypeDef *pExtiConfig);
HAL_StatusTypeDef HAL_EXTI_ClearConfigLine(EXTI_HandleTypeDef *hexti);
HAL_StatusTypeDef HAL_EXTI_RegisterCallback(EXTI_HandleTypeDef *hexti, EXTI_CallbackIDTypeDef CallbackID, void (*pPendingCbfn)(void));
HAL_StatusTypeDef HAL_EXTI_GetHandle(EXTI_HandleTypeDef *hexti, uint32_t ExtiLine);
/**
* @}
*/
/** @defgroup EXTI_Exported_Functions_Group2 IO operation functions
* @brief IO operation functions
* @{
*/
/* IO operation functions *****************************************************/
void HAL_EXTI_IRQHandler(EXTI_HandleTypeDef *hexti);
uint32_t HAL_EXTI_GetPending(EXTI_HandleTypeDef *hexti, uint32_t Edge);
void HAL_EXTI_ClearPending(EXTI_HandleTypeDef *hexti, uint32_t Edge);
void HAL_EXTI_GenerateSWI(EXTI_HandleTypeDef *hexti);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_EXTI_H */
| 12,351 | C | 38.088607 | 135 | 0.48239 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_gpio_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_gpio_ex.h
* @author MCD Application Team
* @brief Header file of GPIO HAL Extended module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_GPIO_EX_H
#define STM32G4xx_HAL_GPIO_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @defgroup GPIOEx GPIOEx
* @brief GPIO Extended HAL module driver
* @{
*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup GPIOEx_Exported_Constants GPIOEx Exported Constants
* @{
*/
/** @defgroup GPIOEx_Alternate_function_selection GPIOEx Alternate function selection
* @{
*/
/**
* @brief AF 0 selection
*/
#define GPIO_AF0_RTC_50Hz ((uint8_t)0x00) /* RTC_50Hz Alternate Function mapping */
#define GPIO_AF0_MCO ((uint8_t)0x00) /* MCO (MCO1 and MCO2) Alternate Function mapping */
#define GPIO_AF0_SWJ ((uint8_t)0x00) /* SWJ (SWD and JTAG) Alternate Function mapping */
#define GPIO_AF0_TRACE ((uint8_t)0x00) /* TRACE Alternate Function mapping */
/**
* @brief AF 1 selection
*/
#define GPIO_AF1_TIM2 ((uint8_t)0x01) /* TIM2 Alternate Function mapping */
#if defined(TIM5)
#define GPIO_AF1_TIM5 ((uint8_t)0x01) /* TIM5 Alternate Function mapping */
#endif /* TIM5 */
#define GPIO_AF1_TIM16 ((uint8_t)0x01) /* TIM16 Alternate Function mapping */
#define GPIO_AF1_TIM17 ((uint8_t)0x01) /* TIM17 Alternate Function mapping */
#define GPIO_AF1_TIM17_COMP1 ((uint8_t)0x01) /* TIM17/COMP1 Break in Alternate Function mapping */
#define GPIO_AF1_TIM15 ((uint8_t)0x01) /* TIM15 Alternate Function mapping */
#define GPIO_AF1_LPTIM1 ((uint8_t)0x01) /* LPTIM1 Alternate Function mapping */
#define GPIO_AF1_IR ((uint8_t)0x01) /* IR Alternate Function mapping */
/**
* @brief AF 2 selection
*/
#define GPIO_AF2_TIM1 ((uint8_t)0x02) /* TIM1 Alternate Function mapping */
#define GPIO_AF2_TIM2 ((uint8_t)0x02) /* TIM2 Alternate Function mapping */
#define GPIO_AF2_TIM3 ((uint8_t)0x02) /* TIM3 Alternate Function mapping */
#define GPIO_AF2_TIM4 ((uint8_t)0x02) /* TIM4 Alternate Function mapping */
#if defined(TIM5)
#define GPIO_AF2_TIM5 ((uint8_t)0x02) /* TIM5 Alternate Function mapping */
#endif /* TIM5 */
#define GPIO_AF2_TIM8 ((uint8_t)0x02) /* TIM8 Alternate Function mapping */
#define GPIO_AF2_TIM15 ((uint8_t)0x02) /* TIM15 Alternate Function mapping */
#define GPIO_AF2_TIM16 ((uint8_t)0x02) /* TIM16 Alternate Function mapping */
#if defined(TIM20)
#define GPIO_AF2_TIM20 ((uint8_t)0x02) /* TIM20 Alternate Function mapping */
#endif /* TIM20 */
#define GPIO_AF2_TIM1_COMP1 ((uint8_t)0x02) /* TIM1/COMP1 Break in Alternate Function mapping */
#define GPIO_AF2_TIM15_COMP1 ((uint8_t)0x02) /* TIM15/COMP1 Break in Alternate Function mapping */
#define GPIO_AF2_TIM16_COMP1 ((uint8_t)0x02) /* TIM16/COMP1 Break in Alternate Function mapping */
#if defined(TIM20)
#define GPIO_AF2_TIM20_COMP1 ((uint8_t)0x02) /* TIM20/COMP1 Break in Alternate Function mapping */
#define GPIO_AF2_TIM20_COMP2 ((uint8_t)0x02) /* TIM20/COMP2 Break in Alternate Function mapping */
#endif /* TIM20 */
#define GPIO_AF2_I2C3 ((uint8_t)0x02) /* I2C3 Alternate Function mapping */
#define GPIO_AF2_COMP1 ((uint8_t)0x02) /* COMP1 Alternate Function mapping */
/**
* @brief AF 3 selection
*/
#define GPIO_AF3_TIM15 ((uint8_t)0x03) /* TIM15 Alternate Function mapping */
#if defined(TIM20)
#define GPIO_AF3_TIM20 ((uint8_t)0x03) /* TIM20 Alternate Function mapping */
#endif /* TIM20 */
#define GPIO_AF3_UCPD1 ((uint8_t)0x03) /* UCPD1 Alternate Function mapping */
#define GPIO_AF3_I2C3 ((uint8_t)0x03) /* I2C3 Alternate Function mapping */
#if defined(I2C4)
#define GPIO_AF3_I2C4 ((uint8_t)0x03) /* I2C4 Alternate Function mapping */
#endif /* I2C4 */
#if defined(HRTIM1)
#define GPIO_AF3_HRTIM1 ((uint8_t)0x03) /* HRTIM1 Alternate Function mapping */
#endif /* HRTIM1 */
#if defined(QUADSPI)
#define GPIO_AF3_QUADSPI ((uint8_t)0x03) /* QUADSPI Alternate Function mapping */
#endif /* QUADSPI */
#define GPIO_AF3_TIM8 ((uint8_t)0x03) /* TIM8 Alternate Function mapping */
#define GPIO_AF3_SAI1 ((uint8_t)0x03) /* SAI1 Alternate Function mapping */
#define GPIO_AF3_COMP3 ((uint8_t)0x03) /* COMP3 Alternate Function mapping */
/**
* @brief AF 4 selection
*/
#define GPIO_AF4_TIM1 ((uint8_t)0x04) /* TIM1 Alternate Function mapping */
#define GPIO_AF4_TIM8 ((uint8_t)0x04) /* TIM8 Alternate Function mapping */
#define GPIO_AF4_TIM16 ((uint8_t)0x04) /* TIM16 Alternate Function mapping */
#define GPIO_AF4_TIM17 ((uint8_t)0x04) /* TIM17 Alternate Function mapping */
#define GPIO_AF4_TIM8_COMP1 ((uint8_t)0x04) /* TIM8/COMP1 Break in Alternate Function mapping */
#define GPIO_AF4_I2C1 ((uint8_t)0x04) /* I2C1 Alternate Function mapping */
#define GPIO_AF4_I2C2 ((uint8_t)0x04) /* I2C2 Alternate Function mapping */
#define GPIO_AF4_I2C3 ((uint8_t)0x04) /* I2C3 Alternate Function mapping */
#if defined(I2C4)
#define GPIO_AF4_I2C4 ((uint8_t)0x04) /* I2C4 Alternate Function mapping */
#endif /* I2C4 */
/**
* @brief AF 5 selection
*/
#define GPIO_AF5_SPI1 ((uint8_t)0x05) /* SPI1 Alternate Function mapping */
#define GPIO_AF5_SPI2 ((uint8_t)0x05) /* SPI2 Alternate Function mapping */
#if defined(SPI4)
#define GPIO_AF5_SPI4 ((uint8_t)0x05) /* SPI4 Alternate Function mapping */
#endif /* SPI4 */
#define GPIO_AF5_IR ((uint8_t)0x05) /* IR Alternate Function mapping */
#define GPIO_AF5_TIM8 ((uint8_t)0x05) /* TIM8 Alternate Function mapping */
#define GPIO_AF5_TIM8_COMP1 ((uint8_t)0x05) /* TIM8/COMP1 Break in Alternate Function mapping */
#define GPIO_AF5_UART4 ((uint8_t)0x05) /* UART4 Alternate Function mapping */
#if defined(UART5)
#define GPIO_AF5_UART5 ((uint8_t)0x05) /* UART5 Alternate Function mapping */
#endif /* UART5 */
#define GPIO_AF5_I2S2ext ((uint8_t)0x05) /* I2S2ext_SD Alternate Function mapping */
/**
* @brief AF 6 selection
*/
#define GPIO_AF6_SPI2 ((uint8_t)0x06) /* SPI2 Alternate Function mapping */
#define GPIO_AF6_SPI3 ((uint8_t)0x06) /* SPI3 Alternate Function mapping */
#define GPIO_AF6_TIM1 ((uint8_t)0x06) /* TIM1 Alternate Function mapping */
#if defined(TIM5)
#define GPIO_AF6_TIM5 ((uint8_t)0x06) /* TIM5 Alternate Function mapping */
#endif /* TIM5 */
#define GPIO_AF6_TIM8 ((uint8_t)0x06) /* TIM8 Alternate Function mapping */
#if defined(TIM20)
#define GPIO_AF6_TIM20 ((uint8_t)0x06) /* TIM20 Alternate Function mapping */
#endif /* TIM20 */
#define GPIO_AF6_TIM1_COMP1 ((uint8_t)0x06) /* TIM1/COMP1 Break in Alternate Function mapping */
#define GPIO_AF6_TIM1_COMP2 ((uint8_t)0x06) /* TIM1/COMP2 Break in Alternate Function mapping */
#define GPIO_AF6_TIM8_COMP2 ((uint8_t)0x06) /* TIM8/COMP2 Break in Alternate Function mapping */
#define GPIO_AF6_IR ((uint8_t)0x06) /* IR Alternate Function mapping */
#define GPIO_AF6_I2S3ext ((uint8_t)0x06) /* I2S3ext_SD Alternate Function mapping */
/**
* @brief AF 7 selection
*/
#define GPIO_AF7_USART1 ((uint8_t)0x07) /* USART1 Alternate Function mapping */
#define GPIO_AF7_USART2 ((uint8_t)0x07) /* USART2 Alternate Function mapping */
#define GPIO_AF7_USART3 ((uint8_t)0x07) /* USART3 Alternate Function mapping */
#if defined(COMP5)
#define GPIO_AF7_COMP5 ((uint8_t)0x07) /* COMP5 Alternate Function mapping */
#endif /* COMP5 */
#if defined(COMP6)
#define GPIO_AF7_COMP6 ((uint8_t)0x07) /* COMP6 Alternate Function mapping */
#endif /* COMP6 */
#if defined(COMP7)
#define GPIO_AF7_COMP7 ((uint8_t)0x07) /* COMP7 Alternate Function mapping */
#endif /* COMP7 */
/**
* @brief AF 8 selection
*/
#define GPIO_AF8_COMP1 ((uint8_t)0x08) /* COMP1 Alternate Function mapping */
#define GPIO_AF8_COMP2 ((uint8_t)0x08) /* COMP2 Alternate Function mapping */
#define GPIO_AF8_COMP3 ((uint8_t)0x08) /* COMP3 Alternate Function mapping */
#define GPIO_AF8_COMP4 ((uint8_t)0x08) /* COMP4 Alternate Function mapping */
#if defined(COMP5)
#define GPIO_AF8_COMP5 ((uint8_t)0x08) /* COMP5 Alternate Function mapping */
#endif /* COMP5 */
#if defined(COMP6)
#define GPIO_AF8_COMP6 ((uint8_t)0x08) /* COMP6 Alternate Function mapping */
#endif /* COMP6 */
#if defined(COMP7)
#define GPIO_AF8_COMP7 ((uint8_t)0x08) /* COMP7 Alternate Function mapping */
#endif /* COMP7 */
#define GPIO_AF8_I2C3 ((uint8_t)0x08) /* I2C3 Alternate Function mapping */
#if defined(I2C4)
#define GPIO_AF8_I2C4 ((uint8_t)0x08) /* I2C4 Alternate Function mapping */
#endif /* I2C4 */
#define GPIO_AF8_LPUART1 ((uint8_t)0x08) /* LPUART1 Alternate Function mapping */
#define GPIO_AF8_UART4 ((uint8_t)0x08) /* UART4 Alternate Function mapping */
#if defined(UART5)
#define GPIO_AF8_UART5 ((uint8_t)0x08) /* UART5 Alternate Function mapping */
#endif /* UART5 */
/**
* @brief AF 9 selection
*/
#define GPIO_AF9_TIM1 ((uint8_t)0x09) /* TIM1 Alternate Function mapping */
#define GPIO_AF9_TIM8 ((uint8_t)0x09) /* TIM8 Alternate Function mapping */
#define GPIO_AF9_TIM15 ((uint8_t)0x09) /* TIM15 Alternate Function mapping */
#define GPIO_AF9_TIM1_COMP1 ((uint8_t)0x09) /* TIM1/COMP1 Break in Alternate Function mapping */
#define GPIO_AF9_TIM8_COMP1 ((uint8_t)0x09) /* TIM8/COMP1 Break in Alternate Function mapping */
#define GPIO_AF9_TIM15_COMP1 ((uint8_t)0x09) /* TIM15/COMP1 Break in Alternate Function mapping */
#define GPIO_AF9_FDCAN1 ((uint8_t)0x09) /* FDCAN1 Alternate Function mapping */
#if defined(FDCAN2)
#define GPIO_AF9_FDCAN2 ((uint8_t)0x09) /* FDCAN2 Alternate Function mapping */
#endif /* FDCAN2 */
/**
* @brief AF 10 selection
*/
#define GPIO_AF10_TIM2 ((uint8_t)0x0A) /* TIM2 Alternate Function mapping */
#define GPIO_AF10_TIM3 ((uint8_t)0x0A) /* TIM3 Alternate Function mapping */
#define GPIO_AF10_TIM4 ((uint8_t)0x0A) /* TIM4 Alternate Function mapping */
#define GPIO_AF10_TIM8 ((uint8_t)0x0A) /* TIM8 Alternate Function mapping */
#define GPIO_AF10_TIM17 ((uint8_t)0x0A) /* TIM17 Alternate Function mapping */
#define GPIO_AF10_TIM8_COMP2 ((uint8_t)0x0A) /* TIM8/COMP2 Break in Alternate Function mapping */
#define GPIO_AF10_TIM17_COMP1 ((uint8_t)0x0A) /* TIM17/COMP1 Break in Alternate Function mapping */
#if defined(QUADSPI)
#define GPIO_AF10_QUADSPI ((uint8_t)0x0A) /* OctoSPI Manager Port 1 Alternate Function mapping */
#endif /* QUADSPI */
/**
* @brief AF 11 selection
*/
#define GPIO_AF11_FDCAN1 ((uint8_t)0x0B) /* FDCAN1 Alternate Function mapping */
#if defined(FDCAN3)
#define GPIO_AF11_FDCAN3 ((uint8_t)0x0B) /* FDCAN3 Alternate Function mapping */
#endif /* FDCAN3 */
#define GPIO_AF11_TIM1 ((uint8_t)0x0B) /* TIM1 Alternate Function mapping */
#define GPIO_AF11_TIM8 ((uint8_t)0x0B) /* TIM8 Alternate Function mapping */
#define GPIO_AF11_TIM8_COMP1 ((uint8_t)0x0B) /* TIM8/COMP1 Break in Alternate Function mapping */
#define GPIO_AF11_LPTIM1 ((uint8_t)0x0B) /* LPTIM1 Alternate Function mapping */
/**
* @brief AF 12 selection
*/
#define GPIO_AF12_LPUART1 ((uint8_t)0x0C) /* LPUART1 Alternate Function mapping */
#define GPIO_AF12_TIM1 ((uint8_t)0x0C) /* TIM1 Alternate Function mapping */
#define GPIO_AF12_TIM1_COMP1 ((uint8_t)0x0C) /* TIM1/COMP1 Break in Alternate Function mapping */
#define GPIO_AF12_TIM1_COMP2 ((uint8_t)0x0C) /* TIM1/COMP2 Break in Alternate Function mapping */
#if defined(HRTIM1)
#define GPIO_AF12_HRTIM1 ((uint8_t)0x0C) /* HRTIM1 Alternate Function mapping */
#endif /* HRTIM1 */
#if defined(FMC_BANK1)
#define GPIO_AF12_FMC ((uint8_t)0x0C) /* FMC Alternate Function mapping */
#endif /* FMC_BANK1 */
#define GPIO_AF12_SAI1 ((uint8_t)0x0C) /* SAI1 Alternate Function mapping */
/**
* @brief AF 13 selection
*/
#if defined(HRTIM1)
#define GPIO_AF13_HRTIM1 ((uint8_t)0x0D) /* HRTIM1 Alternate Function mapping */
#endif /* HRTIM1 */
#define GPIO_AF13_SAI1 ((uint8_t)0x0D) /* SAI1 Alternate Function mapping */
/**
* @brief AF 14 selection
*/
#define GPIO_AF14_TIM2 ((uint8_t)0x0E) /* TIM2 Alternate Function mapping */
#define GPIO_AF14_TIM15 ((uint8_t)0x0E) /* TIM15 Alternate Function mapping */
#define GPIO_AF14_UCPD1 ((uint8_t)0x0E) /* UCPD1 Alternate Function mapping */
#define GPIO_AF14_SAI1 ((uint8_t)0x0E) /* SAI1 Alternate Function mapping */
#define GPIO_AF14_UART4 ((uint8_t)0x0E) /* UART4 Alternate Function mapping */
#if defined(UART5)
#define GPIO_AF14_UART5 ((uint8_t)0x0E) /* UART5 Alternate Function mapping */
#endif /* UART5 */
/**
* @brief AF 15 selection
*/
#define GPIO_AF15_EVENTOUT ((uint8_t)0x0F) /* EVENTOUT Alternate Function mapping */
#define IS_GPIO_AF(AF) ((AF) <= (uint8_t)0x0F)
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup GPIOEx_Exported_Macros GPIOEx Exported Macros
* @{
*/
/** @defgroup GPIOEx_Get_Port_Index GPIOEx Get Port Index
* @{
*/
#define GPIO_GET_INDEX(__GPIOx__) (((__GPIOx__) == (GPIOA))? 0UL :\
((__GPIOx__) == (GPIOB))? 1UL :\
((__GPIOx__) == (GPIOC))? 2UL :\
((__GPIOx__) == (GPIOD))? 3UL :\
((__GPIOx__) == (GPIOE))? 4UL :\
((__GPIOx__) == (GPIOF))? 5UL : 6UL)
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_GPIO_EX_H */
| 15,425 | C | 44.237537 | 111 | 0.599676 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_bus.h | /**
******************************************************************************
* @file stm32g4xx_ll_bus.h
* @author MCD Application Team
* @brief Header file of BUS LL module.
@verbatim
##### RCC Limitations #####
==============================================================================
[..]
A delay between an RCC peripheral clock enable and the effective peripheral
enabling should be taken into account in order to manage the peripheral read/write
from/to registers.
(+) This delay depends on the peripheral mapping.
(++) AHB & APB peripherals, 1 dummy read is necessary
[..]
Workarounds:
(#) For AHB & APB peripherals, a dummy read to the peripheral register has been
inserted in each LL_{BUS}_GRP{x}_EnableClock() function.
@endverbatim
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_BUS_H
#define STM32G4xx_LL_BUS_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
#if defined(RCC)
/** @defgroup BUS_LL BUS
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private constants ---------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup BUS_LL_Exported_Constants BUS Exported Constants
* @{
*/
/** @defgroup BUS_LL_EC_AHB1_GRP1_PERIPH AHB1 GRP1 PERIPH
* @{
*/
#define LL_AHB1_GRP1_PERIPH_ALL 0xFFFFFFFFU
#define LL_AHB1_GRP1_PERIPH_DMA1 RCC_AHB1ENR_DMA1EN
#define LL_AHB1_GRP1_PERIPH_DMA2 RCC_AHB1ENR_DMA2EN
#define LL_AHB1_GRP1_PERIPH_DMAMUX1 RCC_AHB1ENR_DMAMUX1EN
#define LL_AHB1_GRP1_PERIPH_CORDIC RCC_AHB1ENR_CORDICEN
#define LL_AHB1_GRP1_PERIPH_FMAC RCC_AHB1ENR_FMACEN
#define LL_AHB1_GRP1_PERIPH_FLASH RCC_AHB1ENR_FLASHEN
#define LL_AHB1_GRP1_PERIPH_SRAM1 RCC_AHB1SMENR_SRAM1SMEN
#define LL_AHB1_GRP1_PERIPH_CRC RCC_AHB1ENR_CRCEN
/**
* @}
*/
/** @defgroup BUS_LL_EC_AHB2_GRP1_PERIPH AHB2 GRP1 PERIPH
* @{
*/
#define LL_AHB2_GRP1_PERIPH_ALL 0xFFFFFFFFU
#define LL_AHB2_GRP1_PERIPH_GPIOA RCC_AHB2ENR_GPIOAEN
#define LL_AHB2_GRP1_PERIPH_GPIOB RCC_AHB2ENR_GPIOBEN
#define LL_AHB2_GRP1_PERIPH_GPIOC RCC_AHB2ENR_GPIOCEN
#define LL_AHB2_GRP1_PERIPH_GPIOD RCC_AHB2ENR_GPIODEN
#define LL_AHB2_GRP1_PERIPH_GPIOE RCC_AHB2ENR_GPIOEEN
#define LL_AHB2_GRP1_PERIPH_GPIOF RCC_AHB2ENR_GPIOFEN
#define LL_AHB2_GRP1_PERIPH_GPIOG RCC_AHB2ENR_GPIOGEN
#define LL_AHB2_GRP1_PERIPH_CCM RCC_AHB2SMENR_CCMSMEN
#define LL_AHB2_GRP1_PERIPH_SRAM2 RCC_AHB2SMENR_SRAM2SMEN
#define LL_AHB2_GRP1_PERIPH_ADC12 RCC_AHB2ENR_ADC12EN
#if defined(ADC345_COMMON)
#define LL_AHB2_GRP1_PERIPH_ADC345 RCC_AHB2ENR_ADC345EN
#endif /* ADC345_COMMON */
#define LL_AHB2_GRP1_PERIPH_DAC1 RCC_AHB2ENR_DAC1EN
#if defined(DAC2)
#define LL_AHB2_GRP1_PERIPH_DAC2 RCC_AHB2ENR_DAC2EN
#endif /* DAC2 */
#define LL_AHB2_GRP1_PERIPH_DAC3 RCC_AHB2ENR_DAC3EN
#if defined(DAC4)
#define LL_AHB2_GRP1_PERIPH_DAC4 RCC_AHB2ENR_DAC4EN
#endif /* DAC4 */
#if defined(AES)
#define LL_AHB2_GRP1_PERIPH_AES RCC_AHB2ENR_AESEN
#endif /* AES */
#define LL_AHB2_GRP1_PERIPH_RNG RCC_AHB2ENR_RNGEN
/**
* @}
*/
/** @defgroup BUS_LL_EC_AHB3_GRP1_PERIPH AHB3 GRP1 PERIPH
* @{
*/
#define LL_AHB3_GRP1_PERIPH_ALL 0xFFFFFFFFU
#if defined(FMC_Bank1_R)
#define LL_AHB3_GRP1_PERIPH_FMC RCC_AHB3ENR_FMCEN
#endif /* FMC_Bank1_R */
#if defined(QUADSPI)
#define LL_AHB3_GRP1_PERIPH_QSPI RCC_AHB3ENR_QSPIEN
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup BUS_LL_EC_APB1_GRP1_PERIPH APB1 GRP1 PERIPH
* @{
*/
#define LL_APB1_GRP1_PERIPH_ALL 0xFFFFFFFFU
#define LL_APB1_GRP1_PERIPH_TIM2 RCC_APB1ENR1_TIM2EN
#define LL_APB1_GRP1_PERIPH_TIM3 RCC_APB1ENR1_TIM3EN
#define LL_APB1_GRP1_PERIPH_TIM4 RCC_APB1ENR1_TIM4EN
#if defined(TIM5)
#define LL_APB1_GRP1_PERIPH_TIM5 RCC_APB1ENR1_TIM5EN
#endif /* TIM5 */
#define LL_APB1_GRP1_PERIPH_TIM6 RCC_APB1ENR1_TIM6EN
#define LL_APB1_GRP1_PERIPH_TIM7 RCC_APB1ENR1_TIM7EN
#define LL_APB1_GRP1_PERIPH_CRS RCC_APB1ENR1_CRSEN
#define LL_APB1_GRP1_PERIPH_RTCAPB RCC_APB1ENR1_RTCAPBEN
#define LL_APB1_GRP1_PERIPH_WWDG RCC_APB1ENR1_WWDGEN
#define LL_APB1_GRP1_PERIPH_SPI2 RCC_APB1ENR1_SPI2EN
#define LL_APB1_GRP1_PERIPH_SPI3 RCC_APB1ENR1_SPI3EN
#define LL_APB1_GRP1_PERIPH_USART2 RCC_APB1ENR1_USART2EN
#define LL_APB1_GRP1_PERIPH_USART3 RCC_APB1ENR1_USART3EN
#if defined(UART4)
#define LL_APB1_GRP1_PERIPH_UART4 RCC_APB1ENR1_UART4EN
#endif /* UART4 */
#if defined(UART5)
#define LL_APB1_GRP1_PERIPH_UART5 RCC_APB1ENR1_UART5EN
#endif /* UART5 */
#define LL_APB1_GRP1_PERIPH_I2C1 RCC_APB1ENR1_I2C1EN
#define LL_APB1_GRP1_PERIPH_I2C2 RCC_APB1ENR1_I2C2EN
#define LL_APB1_GRP1_PERIPH_USB RCC_APB1ENR1_USBEN
#if defined(FDCAN1)
#define LL_APB1_GRP1_PERIPH_FDCAN RCC_APB1ENR1_FDCANEN
#endif /* FDCAN1 */
#define LL_APB1_GRP1_PERIPH_PWR RCC_APB1ENR1_PWREN
#define LL_APB1_GRP1_PERIPH_I2C3 RCC_APB1ENR1_I2C3EN
#define LL_APB1_GRP1_PERIPH_LPTIM1 RCC_APB1ENR1_LPTIM1EN
/**
* @}
*/
/** @defgroup BUS_LL_EC_APB1_GRP2_PERIPH APB1 GRP2 PERIPH
* @{
*/
#define LL_APB1_GRP2_PERIPH_ALL 0xFFFFFFFFU
#define LL_APB1_GRP2_PERIPH_LPUART1 RCC_APB1ENR2_LPUART1EN
#if defined(I2C4)
#define LL_APB1_GRP2_PERIPH_I2C4 RCC_APB1ENR2_I2C4EN
#endif /* I2C4 */
#define LL_APB1_GRP2_PERIPH_UCPD1 RCC_APB1ENR2_UCPD1EN
/**
* @}
*/
/** @defgroup BUS_LL_EC_APB2_GRP1_PERIPH APB2 GRP1 PERIPH
* @{
*/
#define LL_APB2_GRP1_PERIPH_ALL 0xFFFFFFFFU
#define LL_APB2_GRP1_PERIPH_SYSCFG RCC_APB2ENR_SYSCFGEN
#define LL_APB2_GRP1_PERIPH_TIM1 RCC_APB2ENR_TIM1EN
#define LL_APB2_GRP1_PERIPH_SPI1 RCC_APB2ENR_SPI1EN
#define LL_APB2_GRP1_PERIPH_TIM8 RCC_APB2ENR_TIM8EN
#define LL_APB2_GRP1_PERIPH_USART1 RCC_APB2ENR_USART1EN
#if defined(SPI4)
#define LL_APB2_GRP1_PERIPH_SPI4 RCC_APB2ENR_SPI4EN
#endif /* SPI4 */
#define LL_APB2_GRP1_PERIPH_TIM15 RCC_APB2ENR_TIM15EN
#define LL_APB2_GRP1_PERIPH_TIM16 RCC_APB2ENR_TIM16EN
#define LL_APB2_GRP1_PERIPH_TIM17 RCC_APB2ENR_TIM17EN
#if defined(TIM20)
#define LL_APB2_GRP1_PERIPH_TIM20 RCC_APB2ENR_TIM20EN
#endif /* TIM20 */
#define LL_APB2_GRP1_PERIPH_SAI1 RCC_APB2ENR_SAI1EN
#if defined(HRTIM1)
#define LL_APB2_GRP1_PERIPH_HRTIM1 RCC_APB2ENR_HRTIM1EN
#endif /* HRTIM1 */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup BUS_LL_Exported_Functions BUS Exported Functions
* @{
*/
/** @defgroup BUS_LL_EF_AHB1 AHB1
* @{
*/
/**
* @brief Enable AHB1 peripherals clock.
* @rmtoll AHB1ENR DMA1EN LL_AHB1_GRP1_EnableClock\n
* AHB1ENR DMA2EN LL_AHB1_GRP1_EnableClock\n
* AHB1ENR DMAMMUXEN LL_AHB1_GRP1_EnableClock\n
* AHB1ENR CORDICEN LL_AHB1_GRP1_EnableClock\n
* AHB1ENR FMACEN LL_AHB1_GRP1_EnableClock\n
* AHB1ENR FLASHEN LL_AHB1_GRP1_EnableClock\n
* AHB1ENR CRCEN LL_AHB1_GRP1_EnableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA1
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA2
* @arg @ref LL_AHB1_GRP1_PERIPH_DMAMUX1
* @arg @ref LL_AHB1_GRP1_PERIPH_CORDIC
* @arg @ref LL_AHB1_GRP1_PERIPH_FMAC
* @arg @ref LL_AHB1_GRP1_PERIPH_FLASH
* @arg @ref LL_AHB1_GRP1_PERIPH_CRC
* @retval None
*/
__STATIC_INLINE void LL_AHB1_GRP1_EnableClock(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->AHB1ENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->AHB1ENR, Periphs);
(void)tmpreg;
}
/**
* @brief Check if AHB1 peripheral clock is enabled or not
* @rmtoll AHB1ENR DMA1EN LL_AHB1_GRP1_IsEnabledClock\n
* AHB1ENR DMA2EN LL_AHB1_GRP1_IsEnabledClock\n
* AHB1ENR DMAMUXEN LL_AHB1_GRP1_IsEnabledClock\n
* AHB1ENR CORDICEN LL_AHB1_GRP1_IsEnabledClock\n
* AHB1ENR FMACEN LL_AHB1_GRP1_IsEnabledClock\n
* AHB1ENR FLASHEN LL_AHB1_GRP1_IsEnabledClock\n
* AHB1ENR CRCEN LL_AHB1_GRP1_IsEnabledClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA1
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA2
* @arg @ref LL_AHB1_GRP1_PERIPH_DMAMUX1
* @arg @ref LL_AHB1_GRP1_PERIPH_CORDIC
* @arg @ref LL_AHB1_GRP1_PERIPH_FMAC
* @arg @ref LL_AHB1_GRP1_PERIPH_FLASH
* @arg @ref LL_AHB1_GRP1_PERIPH_CRC
* @retval State of Periphs (1 or 0).
*/
__STATIC_INLINE uint32_t LL_AHB1_GRP1_IsEnabledClock(uint32_t Periphs)
{
return ((READ_BIT(RCC->AHB1ENR, Periphs) == Periphs) ? 1UL : 0UL);
}
/**
* @brief Disable AHB1 peripherals clock.
* @rmtoll AHB1ENR DMA1EN LL_AHB1_GRP1_DisableClock\n
* AHB1ENR DMA2EN LL_AHB1_GRP1_DisableClock\n
* AHB1ENR DMAMUXEN LL_AHB1_GRP1_DisableClock\n
* AHB1ENR CORDICEN LL_AHB1_GRP1_DisableClock\n
* AHB1ENR FMACEN LL_AHB1_GRP1_DisableClock\n
* AHB1ENR FLASHEN LL_AHB1_GRP1_DisableClock\n
* AHB1ENR CRCEN LL_AHB1_GRP1_DisableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA1
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA2
* @arg @ref LL_AHB1_GRP1_PERIPH_DMAMUX1
* @arg @ref LL_AHB1_GRP1_PERIPH_CORDIC
* @arg @ref LL_AHB1_GRP1_PERIPH_FMAC
* @arg @ref LL_AHB1_GRP1_PERIPH_FLASH
* @arg @ref LL_AHB1_GRP1_PERIPH_CRC
* @retval None
*/
__STATIC_INLINE void LL_AHB1_GRP1_DisableClock(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB1ENR, Periphs);
}
/**
* @brief Force AHB1 peripherals reset.
* @rmtoll AHB1RSTR DMA1RST LL_AHB1_GRP1_ForceReset\n
* AHB1RSTR DMA2RST LL_AHB1_GRP1_ForceReset\n
* AHB1RSTR DMAMUXRST LL_AHB1_GRP1_ForceReset\n
* AHB1RSTR CORDICRST LL_AHB1_GRP1_ForceReset\n
* AHB1RSTR FMACRST LL_AHB1_GRP1_ForceReset\n
* AHB1RSTR FLASHRST LL_AHB1_GRP1_ForceReset\n
* AHB1RSTR CRCRST LL_AHB1_GRP1_ForceReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB1_GRP1_PERIPH_ALL
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA1
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA2
* @arg @ref LL_AHB1_GRP1_PERIPH_DMAMUX1
* @arg @ref LL_AHB1_GRP1_PERIPH_CORDIC
* @arg @ref LL_AHB1_GRP1_PERIPH_FMAC
* @arg @ref LL_AHB1_GRP1_PERIPH_FLASH
* @arg @ref LL_AHB1_GRP1_PERIPH_CRC
* @retval None
*/
__STATIC_INLINE void LL_AHB1_GRP1_ForceReset(uint32_t Periphs)
{
SET_BIT(RCC->AHB1RSTR, Periphs);
}
/**
* @brief Release AHB1 peripherals reset.
* @rmtoll AHB1RSTR DMA1RST LL_AHB1_GRP1_ReleaseReset\n
* AHB1RSTR DMA2RST LL_AHB1_GRP1_ReleaseReset\n
* AHB1RSTR DMAMUXRST LL_AHB1_GRP1_ReleaseReset\n
* AHB1RSTR CORDICRST LL_AHB1_GRP1_ReleaseReset\n
* AHB1RSTR FMACRST LL_AHB1_GRP1_ReleaseReset\n
* AHB1RSTR FLASHRST LL_AHB1_GRP1_ReleaseReset\n
* AHB1RSTR CRCRST LL_AHB1_GRP1_ReleaseReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB1_GRP1_PERIPH_ALL
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA1
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA2
* @arg @ref LL_AHB1_GRP1_PERIPH_DMAMUX1
* @arg @ref LL_AHB1_GRP1_PERIPH_CORDIC
* @arg @ref LL_AHB1_GRP1_PERIPH_FMAC
* @arg @ref LL_AHB1_GRP1_PERIPH_FLASH
* @arg @ref LL_AHB1_GRP1_PERIPH_CRC
* @retval None
*/
__STATIC_INLINE void LL_AHB1_GRP1_ReleaseReset(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB1RSTR, Periphs);
}
/**
* @brief Enable AHB1 peripheral clocks in Sleep and Stop modes
* @rmtoll AHB1SMENR DMA1SMEN LL_AHB1_GRP1_EnableClockStopSleep\n
* AHB1SMENR DMA2SMEN LL_AHB1_GRP1_EnableClockStopSleep\n
* AHB1SMENR DMAMUXSMEN LL_AHB1_GRP1_EnableClockStopSleep\n
* AHB1SMENR CORDICSMEN LL_AHB1_GRP1_EnableClockStopSleep\n
* AHB1SMENR FMACSMEN LL_AHB1_GRP1_EnableClockStopSleep\n
* AHB1SMENR FLASHSMEN LL_AHB1_GRP1_EnableClockStopSleep\n
* AHB1SMENR SRAM1SMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR CRCSMEN LL_AHB1_GRP1_EnableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA1
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA2
* @arg @ref LL_AHB1_GRP1_PERIPH_DMAMUX1
* @arg @ref LL_AHB1_GRP1_PERIPH_CORDIC
* @arg @ref LL_AHB1_GRP1_PERIPH_FMAC
* @arg @ref LL_AHB1_GRP1_PERIPH_FLASH
* @arg @ref LL_AHB1_GRP1_PERIPH_SRAM1
* @arg @ref LL_AHB1_GRP1_PERIPH_CRC
* @retval None
*/
__STATIC_INLINE void LL_AHB1_GRP1_EnableClockStopSleep(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->AHB1SMENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->AHB1SMENR, Periphs);
(void)tmpreg;
}
/**
* @brief Disable AHB1 peripheral clocks in Sleep and Stop modes
* @rmtoll AHB1SMENR DMA1SMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR DMA2SMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR DMAMUXSMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR CORDICSMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR FMACSMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR FLASHSMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR SRAM1SMEN LL_AHB1_GRP1_DisableClockStopSleep\n
* AHB1SMENR CRCSMEN LL_AHB1_GRP1_DisableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA1
* @arg @ref LL_AHB1_GRP1_PERIPH_DMA2
* @arg @ref LL_AHB1_GRP1_PERIPH_DMAMUX1
* @arg @ref LL_AHB1_GRP1_PERIPH_CORDIC
* @arg @ref LL_AHB1_GRP1_PERIPH_FMAC
* @arg @ref LL_AHB1_GRP1_PERIPH_FLASH
* @arg @ref LL_AHB1_GRP1_PERIPH_SRAM1
* @arg @ref LL_AHB1_GRP1_PERIPH_CRC
* @retval None
*/
__STATIC_INLINE void LL_AHB1_GRP1_DisableClockStopSleep(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB1SMENR, Periphs);
}
/**
* @}
*/
/** @defgroup BUS_LL_EF_AHB2 AHB2
* @{
*/
/**
* @brief Enable AHB2 peripherals clock.
* @rmtoll AHB2ENR GPIOAEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR GPIOBEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR GPIOCEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR GPIODEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR GPIOEEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR GPIOFEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR GPIOGEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR ADC12EN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR ADC345EN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR DAC1EN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR DAC2EN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR DAC3EN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR DAC4EN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR AESEN LL_AHB2_GRP1_EnableClock\n
* AHB2ENR RNGEN LL_AHB2_GRP1_EnableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOA
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOB
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOC
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOD
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOE
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOF
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOG
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC12
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC345 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC1
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC2 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC3
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC4 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_AES (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_RNG
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB2_GRP1_EnableClock(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->AHB2ENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->AHB2ENR, Periphs);
(void)tmpreg;
}
/**
* @brief Check if AHB2 peripheral clock is enabled or not
* @rmtoll AHB2ENR GPIOAEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR GPIOBEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR GPIOCEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR GPIODEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR GPIOEEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR GPIOFEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR GPIOGEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR ADC12EN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR ADC345EN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR DAC1EN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR DAC2EN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR DAC3EN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR DAC4EN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR AESEN LL_AHB2_GRP1_IsEnabledClock\n
* AHB2ENR RNGEN LL_AHB2_GRP1_IsEnabledClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOA
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOB
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOC
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOD
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOE
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOF
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOG
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC12
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC345 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC1
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC2 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC3
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC4 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_AES (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_RNG
*
* (*) value not defined in all devices.
* @retval State of Periphs (1 or 0).
*/
__STATIC_INLINE uint32_t LL_AHB2_GRP1_IsEnabledClock(uint32_t Periphs)
{
return ((READ_BIT(RCC->AHB2ENR, Periphs) == Periphs) ? 1UL : 0UL);
}
/**
* @brief Disable AHB2 peripherals clock.
* @rmtoll AHB2ENR GPIOAEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR GPIOBEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR GPIOCEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR GPIODEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR GPIOEEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR GPIOFEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR GPIOGEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR ADC12EN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR ADC345EN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR DAC1EN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR DAC2EN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR DAC3EN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR DAC4EN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR AESEN LL_AHB2_GRP1_DisableClock\n
* AHB2ENR RNGEN LL_AHB2_GRP1_DisableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOA
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOB
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOC
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOD
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOE
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOF
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOG
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC12
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC345 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC1
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC2 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC3
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC4 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_AES (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_RNG
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB2_GRP1_DisableClock(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB2ENR, Periphs);
}
/**
* @brief Force AHB2 peripherals reset.
* @rmtoll AHB2RSTR GPIOARST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR GPIOBRST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR GPIOCRST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR GPIODRST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR GPIOERST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR GPIOFRST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR GPIOGRST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR ADC12RST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR ADC345RST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR DAC1RST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR DAC2RST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR DAC3RST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR DAC4RST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR AESRST LL_AHB2_GRP1_ForceReset\n
* AHB2RSTR RNGRST LL_AHB2_GRP1_ForceReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOA
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOB
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOC
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOD
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOE
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOF
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOG
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC12
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC345 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC1
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC2 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC3
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC4 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_AES (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_RNG
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB2_GRP1_ForceReset(uint32_t Periphs)
{
SET_BIT(RCC->AHB2RSTR, Periphs);
}
/**
* @brief Release AHB2 peripherals reset.
* @rmtoll AHB2RSTR GPIOARST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR GPIOBRST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR GPIOCRST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR GPIODRST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR GPIOERST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR GPIOFRST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR GPIOGRST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR ADC12RST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR ADC345RST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR DAC1RST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR DAC2RST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR DAC3RST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR DAC4RST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR AESRST LL_AHB2_GRP1_ReleaseReset\n
* AHB2RSTR RNGRST LL_AHB2_GRP1_ReleaseReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOA
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOB
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOC
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOD
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOE
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOF
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOG
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC12
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC345 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC1
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC2 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC3
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC4 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_AES (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_RNG
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB2_GRP1_ReleaseReset(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB2RSTR, Periphs);
}
/**
* @brief Enable AHB2 peripheral clocks in Sleep and Stop modes
* @rmtoll AHB2SMENR GPIOASMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR GPIOBSMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR GPIOCSMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR GPIODSMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR GPIOESMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR GPIOFSMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR GPIOGSMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR SRAM2SMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR CCMSMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR ADC12SMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR ADC345SMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR DAC1SMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR DAC2SMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR DAC3SMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR DAC4SMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR AESSMEN LL_AHB2_GRP1_EnableClockStopSleep\n
* AHB2SMENR RNGSMEN LL_AHB2_GRP1_EnableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOA
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOB
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOC
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOD
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOE
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOF
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOG
* @arg @ref LL_AHB2_GRP1_PERIPH_SRAM2
* @arg @ref LL_AHB2_GRP1_PERIPH_CCM
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC12
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC345 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC1
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC2 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC3
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC4 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_AES (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_RNG
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB2_GRP1_EnableClockStopSleep(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->AHB2SMENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->AHB2SMENR, Periphs);
(void)tmpreg;
}
/**
* @brief Disable AHB2 peripheral clocks in Sleep and Stop modes
* @rmtoll AHB2SMENR GPIOASMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR GPIOBSMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR GPIOCSMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR GPIODSMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR GPIOESMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR GPIOFSMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR GPIOGSMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR SRAM2SMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR CCMSMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR ADC12SMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR ADC345SMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR DAC1SMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR DAC2SMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR DAC3SMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR DAC4SMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR AESSMEN LL_AHB2_GRP1_DisableClockStopSleep\n
* AHB2SMENR RNGSMEN LL_AHB2_GRP1_DisableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOA
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOB
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOC
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOD
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOE
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOF
* @arg @ref LL_AHB2_GRP1_PERIPH_GPIOG
* @arg @ref LL_AHB2_GRP1_PERIPH_SRAM2
* @arg @ref LL_AHB2_GRP1_PERIPH_CCM
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC12
* @arg @ref LL_AHB2_GRP1_PERIPH_ADC345 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC1
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC2 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC3
* @arg @ref LL_AHB2_GRP1_PERIPH_DAC4 (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_AES (*)
* @arg @ref LL_AHB2_GRP1_PERIPH_RNG
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB2_GRP1_DisableClockStopSleep(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB2SMENR, Periphs);
}
/**
* @}
*/
/** @defgroup BUS_LL_EF_AHB3 AHB3
* @{
*/
/**
* @brief Enable AHB3 peripherals clock.
* @rmtoll AHB3ENR FMCEN LL_AHB3_GRP1_EnableClock\n
* AHB3ENR QSPIEN LL_AHB3_GRP1_EnableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB3_GRP1_PERIPH_FMC (*)
* @arg @ref LL_AHB3_GRP1_PERIPH_QSPI (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB3_GRP1_EnableClock(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->AHB3ENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->AHB3ENR, Periphs);
(void)tmpreg;
}
/**
* @brief Check if AHB3 peripheral clock is enabled or not
* @rmtoll AHB3ENR FMCEN LL_AHB3_GRP1_IsEnabledClock\n
* AHB3ENR QSPIEN LL_AHB3_GRP1_IsEnabledClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB3_GRP1_PERIPH_FMC (*)
* @arg @ref LL_AHB3_GRP1_PERIPH_QSPI (*)
*
* (*) value not defined in all devices.
* @retval State of Periphs (1 or 0).
*/
__STATIC_INLINE uint32_t LL_AHB3_GRP1_IsEnabledClock(uint32_t Periphs)
{
return ((READ_BIT(RCC->AHB3ENR, Periphs) == Periphs) ? 1UL : 0UL);
}
/**
* @brief Disable AHB3 peripherals clock.
* @rmtoll AHB3ENR FMCEN LL_AHB3_GRP1_DisableClock\n
* AHB3ENR QSPIEN LL_AHB3_GRP1_DisableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB3_GRP1_PERIPH_FMC (*)
* @arg @ref LL_AHB3_GRP1_PERIPH_QSPI (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB3_GRP1_DisableClock(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB3ENR, Periphs);
}
/**
* @brief Force AHB3 peripherals reset.
* @rmtoll AHB3RSTR FMCRST LL_AHB3_GRP1_ForceReset\n
* AHB3RSTR QSPIRST LL_AHB3_GRP1_ForceReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB3_GRP1_PERIPH_ALL
* @arg @ref LL_AHB3_GRP1_PERIPH_FMC (*)
* @arg @ref LL_AHB3_GRP1_PERIPH_QSPI (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB3_GRP1_ForceReset(uint32_t Periphs)
{
SET_BIT(RCC->AHB3RSTR, Periphs);
}
/**
* @brief Release AHB3 peripherals reset.
* @rmtoll AHB3RSTR FMCRST LL_AHB3_GRP1_ReleaseReset\n
* AHB3RSTR QSPIRST LL_AHB3_GRP1_ReleaseReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB3_GRP1_PERIPH_ALL
* @arg @ref LL_AHB3_GRP1_PERIPH_FMC (*)
* @arg @ref LL_AHB3_GRP1_PERIPH_QSPI (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB3_GRP1_ReleaseReset(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB3RSTR, Periphs);
}
/**
* @brief Enable AHB3 peripheral clocks in Sleep and Stop modes
* @rmtoll AHB3SMENR FMCSMEN LL_AHB3_GRP1_EnableClockStopSleep\n
* AHB3SMENR QSPISMEN LL_AHB3_GRP1_EnableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB3_GRP1_PERIPH_FMC (*)
* @arg @ref LL_AHB3_GRP1_PERIPH_QSPI (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB3_GRP1_EnableClockStopSleep(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->AHB3SMENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->AHB3SMENR, Periphs);
(void)tmpreg;
}
/**
* @brief Disable AHB3 peripheral clocks in Sleep and Stop modes
* @rmtoll AHB3SMENR FMCSMEN LL_AHB3_GRP1_DisableClockStopSleep\n
* AHB3SMENR QSPISMEN LL_AHB3_GRP1_DisableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_AHB3_GRP1_PERIPH_FMC (*)
* @arg @ref LL_AHB3_GRP1_PERIPH_QSPI (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_AHB3_GRP1_DisableClockStopSleep(uint32_t Periphs)
{
CLEAR_BIT(RCC->AHB3SMENR, Periphs);
}
/**
* @}
*/
/** @defgroup BUS_LL_EF_APB1 APB1
* @{
*/
/**
* @brief Enable APB1 peripherals clock.
* @rmtoll APB1ENR1 TIM2EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 TIM3EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 TIM4EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 TIM5EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 TIM6EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 TIM7EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 CRSEN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 RTCAPBEN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 WWDGEN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 SPI2EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 SPI3EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 USART2EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 USART3EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 UART4EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 UART5EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 I2C1EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 I2C2EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 USBEN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 FDCANEN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 PWREN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 I2C3EN LL_APB1_GRP1_EnableClock\n
* APB1ENR1 LPTIM1EN LL_APB1_GRP1_EnableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP1_PERIPH_TIM2
* @arg @ref LL_APB1_GRP1_PERIPH_TIM3
* @arg @ref LL_APB1_GRP1_PERIPH_TIM4
* @arg @ref LL_APB1_GRP1_PERIPH_TIM5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_TIM6
* @arg @ref LL_APB1_GRP1_PERIPH_TIM7
* @arg @ref LL_APB1_GRP1_PERIPH_CRS
* @arg @ref LL_APB1_GRP1_PERIPH_RTCAPB
* @arg @ref LL_APB1_GRP1_PERIPH_WWDG
* @arg @ref LL_APB1_GRP1_PERIPH_SPI2
* @arg @ref LL_APB1_GRP1_PERIPH_SPI3
* @arg @ref LL_APB1_GRP1_PERIPH_USART2
* @arg @ref LL_APB1_GRP1_PERIPH_USART3
* @arg @ref LL_APB1_GRP1_PERIPH_UART4 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_UART5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_I2C1
* @arg @ref LL_APB1_GRP1_PERIPH_I2C2
* @arg @ref LL_APB1_GRP1_PERIPH_USB
* @arg @ref LL_APB1_GRP1_PERIPH_FDCAN (*)
* @arg @ref LL_APB1_GRP1_PERIPH_PWR
* @arg @ref LL_APB1_GRP1_PERIPH_I2C3
* @arg @ref LL_APB1_GRP1_PERIPH_LPTIM1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP1_EnableClock(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->APB1ENR1, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->APB1ENR1, Periphs);
(void)tmpreg;
}
/**
* @brief Enable APB1 peripherals clock.
* @rmtoll APB1ENR2 LPUART1EN LL_APB1_GRP2_EnableClock\n
* APB1ENR2 I2C4EN LL_APB1_GRP2_EnableClock\n
* APB1ENR2 UCPD1EN LL_APB1_GRP2_EnableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP2_PERIPH_LPUART1
* @arg @ref LL_APB1_GRP2_PERIPH_I2C4 (*)
* @arg @ref LL_APB1_GRP2_PERIPH_UCPD1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP2_EnableClock(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->APB1ENR2, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->APB1ENR2, Periphs);
(void)tmpreg;
}
/**
* @brief Check if APB1 peripheral clock is enabled or not
* @rmtoll APB1ENR1 TIM2EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 TIM3EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 TIM4EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 TIM5EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 TIM6EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 TIM7EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 CRSEN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 RTCAPBEN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 WWDGEN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 SPI2EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 SPI3EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 USART2EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 USART3EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 UART4EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 UART5EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 I2C1EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 I2C2EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 USBEN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 FDCANEN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 PWREN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 I2C3EN LL_APB1_GRP1_IsEnabledClock\n
* APB1ENR1 LPTIM1EN LL_APB1_GRP1_IsEnabledClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP1_PERIPH_TIM2
* @arg @ref LL_APB1_GRP1_PERIPH_TIM3
* @arg @ref LL_APB1_GRP1_PERIPH_TIM4
* @arg @ref LL_APB1_GRP1_PERIPH_TIM5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_TIM6
* @arg @ref LL_APB1_GRP1_PERIPH_TIM7
* @arg @ref LL_APB1_GRP1_PERIPH_CRS
* @arg @ref LL_APB1_GRP1_PERIPH_RTCAPB
* @arg @ref LL_APB1_GRP1_PERIPH_WWDG
* @arg @ref LL_APB1_GRP1_PERIPH_SPI2
* @arg @ref LL_APB1_GRP1_PERIPH_SPI3
* @arg @ref LL_APB1_GRP1_PERIPH_USART2
* @arg @ref LL_APB1_GRP1_PERIPH_USART3
* @arg @ref LL_APB1_GRP1_PERIPH_UART4 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_UART5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_I2C1
* @arg @ref LL_APB1_GRP1_PERIPH_I2C2
* @arg @ref LL_APB1_GRP1_PERIPH_USB
* @arg @ref LL_APB1_GRP1_PERIPH_FDCAN (*)
* @arg @ref LL_APB1_GRP1_PERIPH_PWR
* @arg @ref LL_APB1_GRP1_PERIPH_I2C3
* @arg @ref LL_APB1_GRP1_PERIPH_LPTIM1
*
* (*) value not defined in all devices.
* @retval State of Periphs (1 or 0).
*/
__STATIC_INLINE uint32_t LL_APB1_GRP1_IsEnabledClock(uint32_t Periphs)
{
return ((READ_BIT(RCC->APB1ENR1, Periphs) == Periphs) ? 1UL : 0UL);
}
/**
* @brief Check if APB1 peripheral clock is enabled or not
* @rmtoll APB1ENR2 LPUART1EN LL_APB1_GRP2_IsEnabledClock\n
* APB1ENR2 I2C4EN LL_APB1_GRP2_IsEnabledClock\n
* APB1ENR2 UCPD1EN LL_APB1_GRP2_IsEnabledClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP2_PERIPH_LPUART1
* @arg @ref LL_APB1_GRP2_PERIPH_I2C4 (*)
* @arg @ref LL_APB1_GRP2_PERIPH_UCPD1
*
* (*) value not defined in all devices.
* @retval State of Periphs (1 or 0).
*/
__STATIC_INLINE uint32_t LL_APB1_GRP2_IsEnabledClock(uint32_t Periphs)
{
return ((READ_BIT(RCC->APB1ENR2, Periphs) == Periphs) ? 1UL : 0UL);
}
/**
* @brief Disable APB1 peripherals clock.
* @rmtoll APB1ENR1 TIM2EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 TIM3EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 TIM4EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 TIM5EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 TIM6EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 TIM7EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 CRSEN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 RTCAPBEN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 WWDGEN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 SPI2EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 SPI3EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 USART2EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 USART3EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 UART4EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 UART5EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 I2C1EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 I2C2EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 USBEN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 FDCANEN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 PWREN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 I2C3EN LL_APB1_GRP1_DisableClock\n
* APB1ENR1 LPTIM1EN LL_APB1_GRP1_DisableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP1_PERIPH_TIM2
* @arg @ref LL_APB1_GRP1_PERIPH_TIM3
* @arg @ref LL_APB1_GRP1_PERIPH_TIM4
* @arg @ref LL_APB1_GRP1_PERIPH_TIM5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_TIM6
* @arg @ref LL_APB1_GRP1_PERIPH_TIM7
* @arg @ref LL_APB1_GRP1_PERIPH_CRS
* @arg @ref LL_APB1_GRP1_PERIPH_RTCAPB
* @arg @ref LL_APB1_GRP1_PERIPH_WWDG
* @arg @ref LL_APB1_GRP1_PERIPH_SPI2
* @arg @ref LL_APB1_GRP1_PERIPH_SPI3
* @arg @ref LL_APB1_GRP1_PERIPH_USART2
* @arg @ref LL_APB1_GRP1_PERIPH_USART3
* @arg @ref LL_APB1_GRP1_PERIPH_UART4 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_UART5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_I2C1
* @arg @ref LL_APB1_GRP1_PERIPH_I2C2
* @arg @ref LL_APB1_GRP1_PERIPH_USB
* @arg @ref LL_APB1_GRP1_PERIPH_FDCAN (*)
* @arg @ref LL_APB1_GRP1_PERIPH_PWR
* @arg @ref LL_APB1_GRP1_PERIPH_I2C3
* @arg @ref LL_APB1_GRP1_PERIPH_LPTIM1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP1_DisableClock(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB1ENR1, Periphs);
}
/**
* @brief Disable APB1 peripherals clock.
* @rmtoll APB1ENR2 LPUART1EN LL_APB1_GRP2_DisableClock\n
* APB1ENR2 I2C4EN LL_APB1_GRP2_DisableClock\n
* APB1ENR2 UCPD1EN LL_APB1_GRP2_DisableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP2_PERIPH_LPUART1
* @arg @ref LL_APB1_GRP2_PERIPH_I2C4 (*)
* @arg @ref LL_APB1_GRP2_PERIPH_UCPD1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP2_DisableClock(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB1ENR2, Periphs);
}
/**
* @brief Force APB1 peripherals reset.
* @rmtoll APB1RSTR1 TIM2RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 TIM3RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 TIM4RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 TIM5RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 TIM6RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 TIM7RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 CRSRST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 SPI2RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 SPI3RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 USART2RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 USART3RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 UART4RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 UART5RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 I2C1RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 I2C2RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 USBRST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 FDCANRST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 PWRRST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 I2C3RST LL_APB1_GRP1_ForceReset\n
* APB1RSTR1 LPTIM1RST LL_APB1_GRP1_ForceReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP1_PERIPH_TIM2
* @arg @ref LL_APB1_GRP1_PERIPH_TIM3
* @arg @ref LL_APB1_GRP1_PERIPH_TIM4
* @arg @ref LL_APB1_GRP1_PERIPH_TIM5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_TIM6
* @arg @ref LL_APB1_GRP1_PERIPH_TIM7
* @arg @ref LL_APB1_GRP1_PERIPH_CRS
* @arg @ref LL_APB1_GRP1_PERIPH_SPI2
* @arg @ref LL_APB1_GRP1_PERIPH_SPI3
* @arg @ref LL_APB1_GRP1_PERIPH_USART2
* @arg @ref LL_APB1_GRP1_PERIPH_USART3
* @arg @ref LL_APB1_GRP1_PERIPH_UART4 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_UART5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_I2C1
* @arg @ref LL_APB1_GRP1_PERIPH_I2C2
* @arg @ref LL_APB1_GRP1_PERIPH_USB
* @arg @ref LL_APB1_GRP1_PERIPH_FDCAN (*)
* @arg @ref LL_APB1_GRP1_PERIPH_PWR
* @arg @ref LL_APB1_GRP1_PERIPH_I2C3
* @arg @ref LL_APB1_GRP1_PERIPH_LPTIM1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP1_ForceReset(uint32_t Periphs)
{
SET_BIT(RCC->APB1RSTR1, Periphs);
}
/**
* @brief Force APB1 peripherals reset.
* @rmtoll APB1RSTR2 LPUART1RST LL_APB1_GRP2_ForceReset\n
* APB1RSTR2 I2C4RST LL_APB1_GRP2_ForceReset\n
* APB1RSTR2 UCPD1RST LL_APB1_GRP2_ForceReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP2_PERIPH_LPUART1
* @arg @ref LL_APB1_GRP2_PERIPH_I2C4 (*)
* @arg @ref LL_APB1_GRP2_PERIPH_UCPD1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP2_ForceReset(uint32_t Periphs)
{
SET_BIT(RCC->APB1RSTR2, Periphs);
}
/**
* @brief Release APB1 peripherals reset.
* @rmtoll APB1RSTR1 TIM2RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 TIM3RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 TIM4RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 TIM5RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 TIM6RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 TIM7RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 CRSRST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 SPI2RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 SPI3RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 USART2RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 USART3RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 UART4RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 UART5RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 I2C1RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 I2C2RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 USBRST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 FDCANRST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 PWRRST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 I2C3RST LL_APB1_GRP1_ReleaseReset\n
* APB1RSTR1 LPTIM1RST LL_APB1_GRP1_ReleaseReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP1_PERIPH_TIM2
* @arg @ref LL_APB1_GRP1_PERIPH_TIM3
* @arg @ref LL_APB1_GRP1_PERIPH_TIM4
* @arg @ref LL_APB1_GRP1_PERIPH_TIM5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_TIM6
* @arg @ref LL_APB1_GRP1_PERIPH_TIM7
* @arg @ref LL_APB1_GRP1_PERIPH_CRS
* @arg @ref LL_APB1_GRP1_PERIPH_SPI2
* @arg @ref LL_APB1_GRP1_PERIPH_SPI3
* @arg @ref LL_APB1_GRP1_PERIPH_USART2
* @arg @ref LL_APB1_GRP1_PERIPH_USART3
* @arg @ref LL_APB1_GRP1_PERIPH_UART4 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_UART5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_I2C1
* @arg @ref LL_APB1_GRP1_PERIPH_I2C2
* @arg @ref LL_APB1_GRP1_PERIPH_USB
* @arg @ref LL_APB1_GRP1_PERIPH_FDCAN (*)
* @arg @ref LL_APB1_GRP1_PERIPH_PWR
* @arg @ref LL_APB1_GRP1_PERIPH_I2C3
* @arg @ref LL_APB1_GRP1_PERIPH_LPTIM1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP1_ReleaseReset(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB1RSTR1, Periphs);
}
/**
* @brief Release APB1 peripherals reset.
* @rmtoll APB1RSTR2 LPUART1RST LL_APB1_GRP2_ReleaseReset\n
* APB1RSTR2 I2C4RST LL_APB1_GRP2_ReleaseReset\n
* APB1RSTR2 UCPD1RST LL_APB1_GRP2_ReleaseReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP2_PERIPH_LPUART1
* @arg @ref LL_APB1_GRP2_PERIPH_I2C4 (*)
* @arg @ref LL_APB1_GRP2_PERIPH_UCPD1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP2_ReleaseReset(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB1RSTR2, Periphs);
}
/**
* @brief Enable APB1 peripheral clocks in Sleep and Stop modes
* @rmtoll APB1SMENR1 TIM2SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 TIM3SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 TIM4SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 TIM5SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 TIM6SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 TIM7SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 CRSSMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 RTCAPBSMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 WWDGSMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 SPI2SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 SPI3SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 USART2SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 USART3SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 UART4SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 UART5SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 I2C1SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 I2C2SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 USBSMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 FDCANSMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 PWRSMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 I2C3SMEN LL_APB1_GRP1_EnableClockStopSleep\n
* APB1SMENR1 LPTIM1SMEN LL_APB1_GRP1_EnableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP1_PERIPH_TIM2
* @arg @ref LL_APB1_GRP1_PERIPH_TIM3
* @arg @ref LL_APB1_GRP1_PERIPH_TIM4
* @arg @ref LL_APB1_GRP1_PERIPH_TIM5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_TIM6
* @arg @ref LL_APB1_GRP1_PERIPH_TIM7
* @arg @ref LL_APB1_GRP1_PERIPH_CRS
* @arg @ref LL_APB1_GRP1_PERIPH_RTCAPB
* @arg @ref LL_APB1_GRP1_PERIPH_WWDG
* @arg @ref LL_APB1_GRP1_PERIPH_SPI2
* @arg @ref LL_APB1_GRP1_PERIPH_SPI3
* @arg @ref LL_APB1_GRP1_PERIPH_USART2
* @arg @ref LL_APB1_GRP1_PERIPH_USART3
* @arg @ref LL_APB1_GRP1_PERIPH_UART4 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_UART5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_I2C1
* @arg @ref LL_APB1_GRP1_PERIPH_I2C2
* @arg @ref LL_APB1_GRP1_PERIPH_USB
* @arg @ref LL_APB1_GRP1_PERIPH_FDCAN (*)
* @arg @ref LL_APB1_GRP1_PERIPH_PWR
* @arg @ref LL_APB1_GRP1_PERIPH_I2C3
* @arg @ref LL_APB1_GRP1_PERIPH_LPTIM1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP1_EnableClockStopSleep(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->APB1SMENR1, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->APB1SMENR1, Periphs);
(void)tmpreg;
}
/**
* @brief Enable APB1 peripheral clocks in Sleep and Stop modes
* @rmtoll APB1SMENR2 LPUART1SMEN LL_APB1_GRP2_EnableClockStopSleep\n
* APB1SMENR2 I2C4SMEN LL_APB1_GRP2_EnableClockStopSleep\n
* APB1SMENR2 UCPD1SMEN LL_APB1_GRP2_EnableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP2_PERIPH_LPUART1
* @arg @ref LL_APB1_GRP2_PERIPH_I2C4 (*)
* @arg @ref LL_APB1_GRP2_PERIPH_UCPD1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP2_EnableClockStopSleep(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->APB1SMENR2, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->APB1SMENR2, Periphs);
(void)tmpreg;
}
/**
* @brief Disable APB1 peripheral clocks in Sleep and Stop modes
* @rmtoll APB1SMENR1 TIM2SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 TIM3SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 TIM4SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 TIM5SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 TIM6SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 TIM7SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 CRSSMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 RTCAPBSMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 WWDGSMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 SPI2SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 SPI3SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 USART2SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 USART3SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 UART4SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 UART5SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 I2C1SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 I2C2SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 USBSMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 FDCANSMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 PWRSMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 I2C3SMEN LL_APB1_GRP1_DisableClockStopSleep\n
* APB1SMENR1 LPTIM1SMEN LL_APB1_GRP1_DisableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP1_PERIPH_TIM2
* @arg @ref LL_APB1_GRP1_PERIPH_TIM3
* @arg @ref LL_APB1_GRP1_PERIPH_TIM4
* @arg @ref LL_APB1_GRP1_PERIPH_TIM5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_TIM6
* @arg @ref LL_APB1_GRP1_PERIPH_TIM7
* @arg @ref LL_APB1_GRP1_PERIPH_CRS
* @arg @ref LL_APB1_GRP1_PERIPH_RTCAPB
* @arg @ref LL_APB1_GRP1_PERIPH_WWDG
* @arg @ref LL_APB1_GRP1_PERIPH_SPI2
* @arg @ref LL_APB1_GRP1_PERIPH_SPI3
* @arg @ref LL_APB1_GRP1_PERIPH_USART2
* @arg @ref LL_APB1_GRP1_PERIPH_USART3
* @arg @ref LL_APB1_GRP1_PERIPH_UART4 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_UART5 (*)
* @arg @ref LL_APB1_GRP1_PERIPH_I2C1
* @arg @ref LL_APB1_GRP1_PERIPH_I2C2
* @arg @ref LL_APB1_GRP1_PERIPH_USB
* @arg @ref LL_APB1_GRP1_PERIPH_FDCAN (*)
* @arg @ref LL_APB1_GRP1_PERIPH_PWR
* @arg @ref LL_APB1_GRP1_PERIPH_I2C3
* @arg @ref LL_APB1_GRP1_PERIPH_LPTIM1
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP1_DisableClockStopSleep(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB1SMENR1, Periphs);
}
/**
* @brief Disable APB1 peripheral clocks in Sleep and Stop modes
* @rmtoll APB1SMENR2 LPUART1SMEN LL_APB1_GRP2_DisableClockStopSleep\n
* APB1SMENR2 I2C4SMEN LL_APB1_GRP2_DisableClockStopSleep\n
* APB1SMENR2 UCPD1SMEN LL_APB1_GRP2_DisableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB1_GRP2_PERIPH_LPUART1
* @arg @ref LL_APB1_GRP2_PERIPH_I2C4 (*)
* @arg @ref LL_APB1_GRP2_PERIPH_UCPD1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB1_GRP2_DisableClockStopSleep(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB1SMENR2, Periphs);
}
/**
* @}
*/
/** @defgroup BUS_LL_EF_APB2 APB2
* @{
*/
/**
* @brief Enable APB2 peripherals clock.
* @rmtoll APB2ENR SYSCFGEN LL_APB2_GRP1_EnableClock\n
* APB2ENR TIM1EN LL_APB2_GRP1_EnableClock\n
* APB2ENR SPI1EN LL_APB2_GRP1_EnableClock\n
* APB2ENR TIM8EN LL_APB2_GRP1_EnableClock\n
* APB2ENR USART1EN LL_APB2_GRP1_EnableClock\n
* APB2ENR SPI4EN LL_APB2_GRP1_EnableClock\n
* APB2ENR TIM15EN LL_APB2_GRP1_EnableClock\n
* APB2ENR TIM16EN LL_APB2_GRP1_EnableClock\n
* APB2ENR TIM17EN LL_APB2_GRP1_EnableClock\n
* APB2ENR TIM20EN LL_APB2_GRP1_EnableClock\n
* APB2ENR SAI1EN LL_APB2_GRP1_EnableClock\n
* APB2ENR HRTIM1EN LL_APB2_GRP1_EnableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB2_GRP1_PERIPH_SYSCFG
* @arg @ref LL_APB2_GRP1_PERIPH_TIM1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI1
* @arg @ref LL_APB2_GRP1_PERIPH_TIM8
* @arg @ref LL_APB2_GRP1_PERIPH_USART1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI4 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_TIM15
* @arg @ref LL_APB2_GRP1_PERIPH_TIM16
* @arg @ref LL_APB2_GRP1_PERIPH_TIM17
* @arg @ref LL_APB2_GRP1_PERIPH_TIM20 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_SAI1
* @arg @ref LL_APB2_GRP1_PERIPH_HRTIM1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB2_GRP1_EnableClock(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->APB2ENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->APB2ENR, Periphs);
(void)tmpreg;
}
/**
* @brief Check if APB2 peripheral clock is enabled or not
* @rmtoll APB2ENR SYSCFGEN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR TIM1EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR SPI1EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR TIM8EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR USART1EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR SPI4EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR TIM15EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR TIM16EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR TIM17EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR TIM20EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR SAI1EN LL_APB2_GRP1_IsEnabledClock\n
* APB2ENR HRTIM1EN LL_APB2_GRP1_IsEnabledClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB2_GRP1_PERIPH_SYSCFG
* @arg @ref LL_APB2_GRP1_PERIPH_TIM1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI1
* @arg @ref LL_APB2_GRP1_PERIPH_TIM8
* @arg @ref LL_APB2_GRP1_PERIPH_USART1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI4 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_TIM15
* @arg @ref LL_APB2_GRP1_PERIPH_TIM16
* @arg @ref LL_APB2_GRP1_PERIPH_TIM17
* @arg @ref LL_APB2_GRP1_PERIPH_TIM20 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_SAI1
* @arg @ref LL_APB2_GRP1_PERIPH_HRTIM1 (*)
*
* (*) value not defined in all devices.
* @retval State of Periphs (1 or 0).
*/
__STATIC_INLINE uint32_t LL_APB2_GRP1_IsEnabledClock(uint32_t Periphs)
{
return ((READ_BIT(RCC->APB2ENR, Periphs) == Periphs) ? 1UL : 0UL);
}
/**
* @brief Disable APB2 peripherals clock.
* @rmtoll APB2ENR SYSCFGEN LL_APB2_GRP1_DisableClock\n
* APB2ENR TIM1EN LL_APB2_GRP1_DisableClock\n
* APB2ENR SPI1EN LL_APB2_GRP1_DisableClock\n
* APB2ENR TIM8EN LL_APB2_GRP1_DisableClock\n
* APB2ENR USART1EN LL_APB2_GRP1_DisableClock\n
* APB2ENR SPI4EN LL_APB2_GRP1_DisableClock\n
* APB2ENR TIM15EN LL_APB2_GRP1_DisableClock\n
* APB2ENR TIM16EN LL_APB2_GRP1_DisableClock\n
* APB2ENR TIM17EN LL_APB2_GRP1_DisableClock\n
* APB2ENR TIM20EN LL_APB2_GRP1_DisableClock\n
* APB2ENR SAI1EN LL_APB2_GRP1_DisableClock\n
* APB2ENR HRTIM1EN LL_APB2_GRP1_DisableClock
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB2_GRP1_PERIPH_SYSCFG
* @arg @ref LL_APB2_GRP1_PERIPH_TIM1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI1
* @arg @ref LL_APB2_GRP1_PERIPH_TIM8
* @arg @ref LL_APB2_GRP1_PERIPH_USART1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI4 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_TIM15
* @arg @ref LL_APB2_GRP1_PERIPH_TIM16
* @arg @ref LL_APB2_GRP1_PERIPH_TIM17
* @arg @ref LL_APB2_GRP1_PERIPH_TIM20 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_SAI1
* @arg @ref LL_APB2_GRP1_PERIPH_HRTIM1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB2_GRP1_DisableClock(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB2ENR, Periphs);
}
/**
* @brief Force APB2 peripherals reset.
* @rmtoll APB2RSTR SYSCFGRST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR SPI1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM8RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR USART1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR SPI4RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM15RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM16RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM17RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM20RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR SAI1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR HRTIM1RST LL_APB2_GRP1_ForceReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB2_GRP1_PERIPH_SYSCFG
* @arg @ref LL_APB2_GRP1_PERIPH_TIM1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI1
* @arg @ref LL_APB2_GRP1_PERIPH_TIM8
* @arg @ref LL_APB2_GRP1_PERIPH_USART1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI4 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_TIM15
* @arg @ref LL_APB2_GRP1_PERIPH_TIM16
* @arg @ref LL_APB2_GRP1_PERIPH_TIM17
* @arg @ref LL_APB2_GRP1_PERIPH_TIM20 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_SAI1
* @arg @ref LL_APB2_GRP1_PERIPH_HRTIM1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB2_GRP1_ForceReset(uint32_t Periphs)
{
SET_BIT(RCC->APB2RSTR, Periphs);
}
/**
* @brief Release APB2 peripherals reset.
* @rmtoll APB2RSTR SYSCFGRST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR SPI1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM8RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR USART1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR SPI4RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM15RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM16RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM17RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR TIM20RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR SAI1RST LL_APB2_GRP1_ForceReset\n
* APB2RSTR HRTIM1RST LL_APB2_GRP1_ForceReset
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB2_GRP1_PERIPH_SYSCFG
* @arg @ref LL_APB2_GRP1_PERIPH_TIM1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI1
* @arg @ref LL_APB2_GRP1_PERIPH_TIM8
* @arg @ref LL_APB2_GRP1_PERIPH_USART1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI4 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_TIM15
* @arg @ref LL_APB2_GRP1_PERIPH_TIM16
* @arg @ref LL_APB2_GRP1_PERIPH_TIM17
* @arg @ref LL_APB2_GRP1_PERIPH_TIM20 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_SAI1
* @arg @ref LL_APB2_GRP1_PERIPH_HRTIM1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB2_GRP1_ReleaseReset(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB2RSTR, Periphs);
}
/**
* @brief Enable APB2 peripheral clocks in Sleep and Stop modes
* @rmtoll APB2SMENR SYSCFGSMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR TIM1SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR SPI1SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR TIM8SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR USART1SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR SPI4SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR TIM15SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR TIM16SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR TIM17SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR TIM20SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR SAI1SMEN LL_APB2_GRP1_EnableClockStopSleep\n
* APB2SMENR HRTIM1SMEN LL_APB2_GRP1_EnableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB2_GRP1_PERIPH_SYSCFG
* @arg @ref LL_APB2_GRP1_PERIPH_TIM1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI1
* @arg @ref LL_APB2_GRP1_PERIPH_TIM8
* @arg @ref LL_APB2_GRP1_PERIPH_USART1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI4 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_TIM15
* @arg @ref LL_APB2_GRP1_PERIPH_TIM16
* @arg @ref LL_APB2_GRP1_PERIPH_TIM17
* @arg @ref LL_APB2_GRP1_PERIPH_TIM20 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_SAI1
* @arg @ref LL_APB2_GRP1_PERIPH_HRTIM1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB2_GRP1_EnableClockStopSleep(uint32_t Periphs)
{
__IO uint32_t tmpreg;
SET_BIT(RCC->APB2SMENR, Periphs);
/* Delay after an RCC peripheral clock enabling */
tmpreg = READ_BIT(RCC->APB2SMENR, Periphs);
(void)tmpreg;
}
/**
* @brief Disable APB2 peripheral clocks in Sleep and Stop modes
* @rmtoll APB2SMENR SYSCFGSMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR TIM1SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR SPI1SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR TIM8SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR USART1SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR SPI4SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR TIM15SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR TIM16SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR TIM17SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR TIM20SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR SAI1SMEN LL_APB2_GRP1_DisableClockStopSleep\n
* APB2SMENR HRTIM1SMEN LL_APB2_GRP1_DisableClockStopSleep
* @param Periphs This parameter can be a combination of the following values:
* @arg @ref LL_APB2_GRP1_PERIPH_SYSCFG
* @arg @ref LL_APB2_GRP1_PERIPH_TIM1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI1
* @arg @ref LL_APB2_GRP1_PERIPH_TIM8
* @arg @ref LL_APB2_GRP1_PERIPH_USART1
* @arg @ref LL_APB2_GRP1_PERIPH_SPI4 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_TIM15
* @arg @ref LL_APB2_GRP1_PERIPH_TIM16
* @arg @ref LL_APB2_GRP1_PERIPH_TIM17
* @arg @ref LL_APB2_GRP1_PERIPH_TIM20 (*)
* @arg @ref LL_APB2_GRP1_PERIPH_SAI1
* @arg @ref LL_APB2_GRP1_PERIPH_HRTIM1 (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_APB2_GRP1_DisableClockStopSleep(uint32_t Periphs)
{
CLEAR_BIT(RCC->APB2SMENR, Periphs);
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* defined(RCC) */
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_BUS_H */
| 74,749 | C | 43.467579 | 88 | 0.594309 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_ll_rcc.h | /**
******************************************************************************
* @file stm32g4xx_ll_rcc.h
* @author MCD Application Team
* @brief Header file of RCC LL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file in
* the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_LL_RCC_H
#define STM32G4xx_LL_RCC_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx.h"
/** @addtogroup STM32G4xx_LL_Driver
* @{
*/
/** @defgroup RCC_LL RCC
* @{
*/
/* Private types -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/** @defgroup RCC_LL_Private_Variables RCC Private Variables
* @{
*/
/**
* @}
*/
/* Private constants ---------------------------------------------------------*/
/** @defgroup RCC_LL_Private_Constants RCC Private Constants
* @{
*/
/* Defines used to perform offsets*/
/* Offset used to access to RCC_CCIPR and RCC_CCIPR2 registers */
#define RCC_OFFSET_CCIPR 0U
#define RCC_OFFSET_CCIPR2 0x14U
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup RCC_LL_Private_Macros RCC Private Macros
* @{
*/
/**
* @}
*/
#endif /*USE_FULL_LL_DRIVER*/
/* Exported types ------------------------------------------------------------*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup RCC_LL_Exported_Types RCC Exported Types
* @{
*/
/** @defgroup LL_ES_CLOCK_FREQ Clocks Frequency Structure
* @{
*/
/**
* @brief RCC Clocks Frequency Structure
*/
typedef struct
{
uint32_t SYSCLK_Frequency; /*!< SYSCLK clock frequency */
uint32_t HCLK_Frequency; /*!< HCLK clock frequency */
uint32_t PCLK1_Frequency; /*!< PCLK1 clock frequency */
uint32_t PCLK2_Frequency; /*!< PCLK2 clock frequency */
} LL_RCC_ClocksTypeDef;
/**
* @}
*/
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/* Exported constants --------------------------------------------------------*/
/** @defgroup RCC_LL_Exported_Constants RCC Exported Constants
* @{
*/
/** @defgroup RCC_LL_EC_OSC_VALUES Oscillator Values adaptation
* @brief Defines used to adapt values of different oscillators
* @note These values could be modified in the user environment according to
* HW set-up.
* @{
*/
#if !defined (HSE_VALUE)
#define HSE_VALUE 8000000U /*!< Value of the HSE oscillator in Hz */
#endif /* HSE_VALUE */
#if !defined (HSI_VALUE)
#define HSI_VALUE 16000000U /*!< Value of the HSI oscillator in Hz */
#endif /* HSI_VALUE */
#if !defined (LSE_VALUE)
#define LSE_VALUE 32768U /*!< Value of the LSE oscillator in Hz */
#endif /* LSE_VALUE */
#if !defined (LSI_VALUE)
#define LSI_VALUE 32000U /*!< Value of the LSI oscillator in Hz */
#endif /* LSI_VALUE */
#if !defined (HSI48_VALUE)
#define HSI48_VALUE 48000000U /*!< Value of the HSI48 oscillator in Hz */
#endif /* HSI48_VALUE */
#if !defined (EXTERNAL_CLOCK_VALUE)
#define EXTERNAL_CLOCK_VALUE 48000U /*!< Value of the I2S_CKIN, I2S and SAI1 external clock source in Hz */
#endif /* EXTERNAL_CLOCK_VALUE */
/**
* @}
*/
/** @defgroup RCC_LL_EC_CLEAR_FLAG Clear Flags Defines
* @brief Flags defines which can be used with LL_RCC_WriteReg function
* @{
*/
#define LL_RCC_CICR_LSIRDYC RCC_CICR_LSIRDYC /*!< LSI Ready Interrupt Clear */
#define LL_RCC_CICR_LSERDYC RCC_CICR_LSERDYC /*!< LSE Ready Interrupt Clear */
#define LL_RCC_CICR_HSIRDYC RCC_CICR_HSIRDYC /*!< HSI Ready Interrupt Clear */
#define LL_RCC_CICR_HSERDYC RCC_CICR_HSERDYC /*!< HSE Ready Interrupt Clear */
#define LL_RCC_CICR_PLLRDYC RCC_CICR_PLLRDYC /*!< PLL Ready Interrupt Clear */
#define LL_RCC_CICR_HSI48RDYC RCC_CICR_HSI48RDYC /*!< HSI48 Ready Interrupt Clear */
#define LL_RCC_CICR_LSECSSC RCC_CICR_LSECSSC /*!< LSE Clock Security System Interrupt Clear */
#define LL_RCC_CICR_CSSC RCC_CICR_CSSC /*!< Clock Security System Interrupt Clear */
/**
* @}
*/
/** @defgroup RCC_LL_EC_GET_FLAG Get Flags Defines
* @brief Flags defines which can be used with LL_RCC_ReadReg function
* @{
*/
#define LL_RCC_CIFR_LSIRDYF RCC_CIFR_LSIRDYF /*!< LSI Ready Interrupt flag */
#define LL_RCC_CIFR_LSERDYF RCC_CIFR_LSERDYF /*!< LSE Ready Interrupt flag */
#define LL_RCC_CIFR_HSIRDYF RCC_CIFR_HSIRDYF /*!< HSI Ready Interrupt flag */
#define LL_RCC_CIFR_HSERDYF RCC_CIFR_HSERDYF /*!< HSE Ready Interrupt flag */
#define LL_RCC_CIFR_PLLRDYF RCC_CIFR_PLLRDYF /*!< PLL Ready Interrupt flag */
#define LL_RCC_CIFR_HSI48RDYF RCC_CIFR_HSI48RDYF /*!< HSI48 Ready Interrupt flag */
#define LL_RCC_CIFR_LSECSSF RCC_CIFR_LSECSSF /*!< LSE Clock Security System Interrupt flag */
#define LL_RCC_CIFR_CSSF RCC_CIFR_CSSF /*!< Clock Security System Interrupt flag */
#define LL_RCC_CSR_LPWRRSTF RCC_CSR_LPWRRSTF /*!< Low-Power reset flag */
#define LL_RCC_CSR_OBLRSTF RCC_CSR_OBLRSTF /*!< OBL reset flag */
#define LL_RCC_CSR_PINRSTF RCC_CSR_PINRSTF /*!< PIN reset flag */
#define LL_RCC_CSR_SFTRSTF RCC_CSR_SFTRSTF /*!< Software Reset flag */
#define LL_RCC_CSR_IWDGRSTF RCC_CSR_IWDGRSTF /*!< Independent Watchdog reset flag */
#define LL_RCC_CSR_WWDGRSTF RCC_CSR_WWDGRSTF /*!< Window watchdog reset flag */
#define LL_RCC_CSR_BORRSTF RCC_CSR_BORRSTF /*!< BOR reset flag */
/**
* @}
*/
/** @defgroup RCC_LL_EC_IT IT Defines
* @brief IT defines which can be used with LL_RCC_ReadReg and LL_RCC_WriteReg functions
* @{
*/
#define LL_RCC_CIER_LSIRDYIE RCC_CIER_LSIRDYIE /*!< LSI Ready Interrupt Enable */
#define LL_RCC_CIER_LSERDYIE RCC_CIER_LSERDYIE /*!< LSE Ready Interrupt Enable */
#define LL_RCC_CIER_HSIRDYIE RCC_CIER_HSIRDYIE /*!< HSI Ready Interrupt Enable */
#define LL_RCC_CIER_HSERDYIE RCC_CIER_HSERDYIE /*!< HSE Ready Interrupt Enable */
#define LL_RCC_CIER_PLLRDYIE RCC_CIER_PLLRDYIE /*!< PLL Ready Interrupt Enable */
#define LL_RCC_CIER_HSI48RDYIE RCC_CIER_HSI48RDYIE /*!< HSI48 Ready Interrupt Enable */
#define LL_RCC_CIER_LSECSSIE RCC_CIER_LSECSSIE /*!< LSE CSS Interrupt Enable */
/**
* @}
*/
/** @defgroup RCC_LL_EC_LSEDRIVE LSE oscillator drive capability
* @{
*/
#define LL_RCC_LSEDRIVE_LOW 0x00000000U /*!< Xtal mode lower driving capability */
#define LL_RCC_LSEDRIVE_MEDIUMLOW RCC_BDCR_LSEDRV_0 /*!< Xtal mode medium low driving capability */
#define LL_RCC_LSEDRIVE_MEDIUMHIGH RCC_BDCR_LSEDRV_1 /*!< Xtal mode medium high driving capability */
#define LL_RCC_LSEDRIVE_HIGH RCC_BDCR_LSEDRV /*!< Xtal mode higher driving capability */
/**
* @}
*/
/** @defgroup RCC_LL_EC_LSCO_CLKSOURCE LSCO Selection
* @{
*/
#define LL_RCC_LSCO_CLKSOURCE_LSI 0x00000000U /*!< LSI selection for low speed clock */
#define LL_RCC_LSCO_CLKSOURCE_LSE RCC_BDCR_LSCOSEL /*!< LSE selection for low speed clock */
/**
* @}
*/
/** @defgroup RCC_LL_EC_SYS_CLKSOURCE System clock switch
* @{
*/
#define LL_RCC_SYS_CLKSOURCE_HSI RCC_CFGR_SW_HSI /*!< HSI selection as system clock */
#define LL_RCC_SYS_CLKSOURCE_HSE RCC_CFGR_SW_HSE /*!< HSE selection as system clock */
#define LL_RCC_SYS_CLKSOURCE_PLL RCC_CFGR_SW_PLL /*!< PLL selection as system clock */
/**
* @}
*/
/** @defgroup RCC_LL_EC_SYS_CLKSOURCE_STATUS System clock switch status
* @{
*/
#define LL_RCC_SYS_CLKSOURCE_STATUS_HSI RCC_CFGR_SWS_HSI /*!< HSI used as system clock */
#define LL_RCC_SYS_CLKSOURCE_STATUS_HSE RCC_CFGR_SWS_HSE /*!< HSE used as system clock */
#define LL_RCC_SYS_CLKSOURCE_STATUS_PLL RCC_CFGR_SWS_PLL /*!< PLL used as system clock */
/**
* @}
*/
/** @defgroup RCC_LL_EC_SYSCLK_DIV AHB prescaler
* @{
*/
#define LL_RCC_SYSCLK_DIV_1 RCC_CFGR_HPRE_DIV1 /*!< SYSCLK not divided */
#define LL_RCC_SYSCLK_DIV_2 RCC_CFGR_HPRE_DIV2 /*!< SYSCLK divided by 2 */
#define LL_RCC_SYSCLK_DIV_4 RCC_CFGR_HPRE_DIV4 /*!< SYSCLK divided by 4 */
#define LL_RCC_SYSCLK_DIV_8 RCC_CFGR_HPRE_DIV8 /*!< SYSCLK divided by 8 */
#define LL_RCC_SYSCLK_DIV_16 RCC_CFGR_HPRE_DIV16 /*!< SYSCLK divided by 16 */
#define LL_RCC_SYSCLK_DIV_64 RCC_CFGR_HPRE_DIV64 /*!< SYSCLK divided by 64 */
#define LL_RCC_SYSCLK_DIV_128 RCC_CFGR_HPRE_DIV128 /*!< SYSCLK divided by 128 */
#define LL_RCC_SYSCLK_DIV_256 RCC_CFGR_HPRE_DIV256 /*!< SYSCLK divided by 256 */
#define LL_RCC_SYSCLK_DIV_512 RCC_CFGR_HPRE_DIV512 /*!< SYSCLK divided by 512 */
/**
* @}
*/
/** @defgroup RCC_LL_EC_APB1_DIV APB low-speed prescaler (APB1)
* @{
*/
#define LL_RCC_APB1_DIV_1 RCC_CFGR_PPRE1_DIV1 /*!< HCLK not divided */
#define LL_RCC_APB1_DIV_2 RCC_CFGR_PPRE1_DIV2 /*!< HCLK divided by 2 */
#define LL_RCC_APB1_DIV_4 RCC_CFGR_PPRE1_DIV4 /*!< HCLK divided by 4 */
#define LL_RCC_APB1_DIV_8 RCC_CFGR_PPRE1_DIV8 /*!< HCLK divided by 8 */
#define LL_RCC_APB1_DIV_16 RCC_CFGR_PPRE1_DIV16 /*!< HCLK divided by 16 */
/**
* @}
*/
/** @defgroup RCC_LL_EC_APB2_DIV APB high-speed prescaler (APB2)
* @{
*/
#define LL_RCC_APB2_DIV_1 RCC_CFGR_PPRE2_DIV1 /*!< HCLK not divided */
#define LL_RCC_APB2_DIV_2 RCC_CFGR_PPRE2_DIV2 /*!< HCLK divided by 2 */
#define LL_RCC_APB2_DIV_4 RCC_CFGR_PPRE2_DIV4 /*!< HCLK divided by 4 */
#define LL_RCC_APB2_DIV_8 RCC_CFGR_PPRE2_DIV8 /*!< HCLK divided by 8 */
#define LL_RCC_APB2_DIV_16 RCC_CFGR_PPRE2_DIV16 /*!< HCLK divided by 16 */
/**
* @}
*/
/** @defgroup RCC_LL_EC_MCO1SOURCE MCO1 SOURCE selection
* @{
*/
#define LL_RCC_MCO1SOURCE_NOCLOCK 0x00000000U /*!< MCO output disabled, no clock on MCO */
#define LL_RCC_MCO1SOURCE_SYSCLK RCC_CFGR_MCOSEL_0 /*!< SYSCLK selection as MCO1 source */
#define LL_RCC_MCO1SOURCE_HSI (RCC_CFGR_MCOSEL_0| RCC_CFGR_MCOSEL_1) /*!< HSI16 selection as MCO1 source */
#define LL_RCC_MCO1SOURCE_HSE RCC_CFGR_MCOSEL_2 /*!< HSE selection as MCO1 source */
#define LL_RCC_MCO1SOURCE_PLLCLK (RCC_CFGR_MCOSEL_0|RCC_CFGR_MCOSEL_2) /*!< Main PLL selection as MCO1 source */
#define LL_RCC_MCO1SOURCE_LSI (RCC_CFGR_MCOSEL_1|RCC_CFGR_MCOSEL_2) /*!< LSI selection as MCO1 source */
#define LL_RCC_MCO1SOURCE_LSE (RCC_CFGR_MCOSEL_0|RCC_CFGR_MCOSEL_1|RCC_CFGR_MCOSEL_2) /*!< LSE selection as MCO1 source */
#define LL_RCC_MCO1SOURCE_HSI48 RCC_CFGR_MCOSEL_3 /*!< HSI48 selection as MCO1 source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_MCO1_DIV MCO1 prescaler
* @{
*/
#define LL_RCC_MCO1_DIV_1 RCC_CFGR_MCOPRE_DIV1 /*!< MCO not divided */
#define LL_RCC_MCO1_DIV_2 RCC_CFGR_MCOPRE_DIV2 /*!< MCO divided by 2 */
#define LL_RCC_MCO1_DIV_4 RCC_CFGR_MCOPRE_DIV4 /*!< MCO divided by 4 */
#define LL_RCC_MCO1_DIV_8 RCC_CFGR_MCOPRE_DIV8 /*!< MCO divided by 8 */
#define LL_RCC_MCO1_DIV_16 RCC_CFGR_MCOPRE_DIV16 /*!< MCO divided by 16 */
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup RCC_LL_EC_PERIPH_FREQUENCY Peripheral clock frequency
* @{
*/
#define LL_RCC_PERIPH_FREQUENCY_NO 0x00000000U /*!< No clock enabled for the peripheral */
#define LL_RCC_PERIPH_FREQUENCY_NA 0xFFFFFFFFU /*!< Frequency cannot be provided as external clock */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/** @defgroup RCC_LL_EC_USARTx_CLKSOURCE Peripheral USART clock source selection
* @{
*/
#define LL_RCC_USART1_CLKSOURCE_PCLK2 (RCC_CCIPR_USART1SEL << 16U) /*!< PCLK2 clock used as USART1 clock source */
#define LL_RCC_USART1_CLKSOURCE_SYSCLK ((RCC_CCIPR_USART1SEL << 16U) | RCC_CCIPR_USART1SEL_0) /*!< SYSCLK clock used as USART1 clock source */
#define LL_RCC_USART1_CLKSOURCE_HSI ((RCC_CCIPR_USART1SEL << 16U) | RCC_CCIPR_USART1SEL_1) /*!< HSI clock used as USART1 clock source */
#define LL_RCC_USART1_CLKSOURCE_LSE ((RCC_CCIPR_USART1SEL << 16U) | RCC_CCIPR_USART1SEL) /*!< LSE clock used as USART1 clock source */
#define LL_RCC_USART2_CLKSOURCE_PCLK1 (RCC_CCIPR_USART2SEL << 16U) /*!< PCLK1 clock used as USART2 clock source */
#define LL_RCC_USART2_CLKSOURCE_SYSCLK ((RCC_CCIPR_USART2SEL << 16U) | RCC_CCIPR_USART2SEL_0) /*!< SYSCLK clock used as USART2 clock source */
#define LL_RCC_USART2_CLKSOURCE_HSI ((RCC_CCIPR_USART2SEL << 16U) | RCC_CCIPR_USART2SEL_1) /*!< HSI clock used as USART2 clock source */
#define LL_RCC_USART2_CLKSOURCE_LSE ((RCC_CCIPR_USART2SEL << 16U) | RCC_CCIPR_USART2SEL) /*!< LSE clock used as USART2 clock source */
#define LL_RCC_USART3_CLKSOURCE_PCLK1 (RCC_CCIPR_USART3SEL << 16U) /*!< PCLK1 clock used as USART3 clock source */
#define LL_RCC_USART3_CLKSOURCE_SYSCLK ((RCC_CCIPR_USART3SEL << 16U) | RCC_CCIPR_USART3SEL_0) /*!< SYSCLK clock used as USART3 clock source */
#define LL_RCC_USART3_CLKSOURCE_HSI ((RCC_CCIPR_USART3SEL << 16U) | RCC_CCIPR_USART3SEL_1) /*!< HSI clock used as USART3 clock source */
#define LL_RCC_USART3_CLKSOURCE_LSE ((RCC_CCIPR_USART3SEL << 16U) | RCC_CCIPR_USART3SEL) /*!< LSE clock used as USART3 clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_UARTx_CLKSOURCE Peripheral UART clock source selection
* @{
*/
#if defined(RCC_CCIPR_UART4SEL)
#define LL_RCC_UART4_CLKSOURCE_PCLK1 (RCC_CCIPR_UART4SEL << 16U) /*!< PCLK1 clock used as UART4 clock source */
#define LL_RCC_UART4_CLKSOURCE_SYSCLK ((RCC_CCIPR_UART4SEL << 16U) | RCC_CCIPR_UART4SEL_0) /*!< SYSCLK clock used as UART4 clock source */
#define LL_RCC_UART4_CLKSOURCE_HSI ((RCC_CCIPR_UART4SEL << 16U) | RCC_CCIPR_UART4SEL_1) /*!< HSI clock used as UART4 clock source */
#define LL_RCC_UART4_CLKSOURCE_LSE ((RCC_CCIPR_UART4SEL << 16U) | RCC_CCIPR_UART4SEL) /*!< LSE clock used as UART4 clock source */
#endif /* RCC_CCIPR_UART4SEL */
#if defined(RCC_CCIPR_UART5SEL)
#define LL_RCC_UART5_CLKSOURCE_PCLK1 (RCC_CCIPR_UART5SEL << 16U) /*!< PCLK1 clock used as UART5 clock source */
#define LL_RCC_UART5_CLKSOURCE_SYSCLK ((RCC_CCIPR_UART5SEL << 16U) | RCC_CCIPR_UART5SEL_0) /*!< SYSCLK clock used as UART5 clock source */
#define LL_RCC_UART5_CLKSOURCE_HSI ((RCC_CCIPR_UART5SEL << 16U) | RCC_CCIPR_UART5SEL_1) /*!< HSI clock used as UART5 clock source */
#define LL_RCC_UART5_CLKSOURCE_LSE ((RCC_CCIPR_UART5SEL << 16U) | RCC_CCIPR_UART5SEL) /*!< LSE clock used as UART5 clock source */
#endif /* RCC_CCIPR_UART5SEL */
/**
* @}
*/
/** @defgroup RCC_LL_EC_LPUART1_CLKSOURCE Peripheral LPUART clock source selection
* @{
*/
#define LL_RCC_LPUART1_CLKSOURCE_PCLK1 0x00000000U /*!< PCLK1 clock used as LPUART1 clock source */
#define LL_RCC_LPUART1_CLKSOURCE_SYSCLK RCC_CCIPR_LPUART1SEL_0 /*!< SYSCLK clock used as LPUART1 clock source */
#define LL_RCC_LPUART1_CLKSOURCE_HSI RCC_CCIPR_LPUART1SEL_1 /*!< HSI clock used as LPUART1 clock source */
#define LL_RCC_LPUART1_CLKSOURCE_LSE RCC_CCIPR_LPUART1SEL /*!< LSE clock used as LPUART1 clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_I2Cx_CLKSOURCE Peripheral I2C clock source selection
* @{
*/
#define LL_RCC_I2C1_CLKSOURCE_PCLK1 (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C1SEL_Pos << 16U)) /*!< PCLK1 clock used as I2C1 clock source */
#define LL_RCC_I2C1_CLKSOURCE_SYSCLK (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C1SEL_Pos << 16U) | (RCC_CCIPR_I2C1SEL_0 >> RCC_CCIPR_I2C1SEL_Pos)) /*!< SYSCLK clock used as I2C1 clock source */
#define LL_RCC_I2C1_CLKSOURCE_HSI (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C1SEL_Pos << 16U) | (RCC_CCIPR_I2C1SEL_1 >> RCC_CCIPR_I2C1SEL_Pos)) /*!< HSI clock used as I2C1 clock source */
#define LL_RCC_I2C2_CLKSOURCE_PCLK1 (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C2SEL_Pos << 16U)) /*!< PCLK1 clock used as I2C2 clock source */
#define LL_RCC_I2C2_CLKSOURCE_SYSCLK (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C2SEL_Pos << 16U) | (RCC_CCIPR_I2C2SEL_0 >> RCC_CCIPR_I2C2SEL_Pos)) /*!< SYSCLK clock used as I2C2 clock source */
#define LL_RCC_I2C2_CLKSOURCE_HSI (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C2SEL_Pos << 16U) | (RCC_CCIPR_I2C2SEL_1 >> RCC_CCIPR_I2C2SEL_Pos)) /*!< HSI clock used as I2C2 clock source */
#define LL_RCC_I2C3_CLKSOURCE_PCLK1 (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C3SEL_Pos << 16U)) /*!< PCLK1 clock used as I2C3 clock source */
#define LL_RCC_I2C3_CLKSOURCE_SYSCLK (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C3SEL_Pos << 16U) | (RCC_CCIPR_I2C3SEL_0 >> RCC_CCIPR_I2C3SEL_Pos)) /*!< SYSCLK clock used as I2C3 clock source */
#define LL_RCC_I2C3_CLKSOURCE_HSI (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C3SEL_Pos << 16U) | (RCC_CCIPR_I2C3SEL_1 >> RCC_CCIPR_I2C3SEL_Pos)) /*!< HSI clock used as I2C3 clock source */
#if defined(RCC_CCIPR2_I2C4SEL)
#define LL_RCC_I2C4_CLKSOURCE_PCLK1 (((uint32_t)RCC_OFFSET_CCIPR2 << 24U) | ((uint32_t)RCC_CCIPR2_I2C4SEL_Pos << 16U)) /*!< PCLK1 clock used as I2C4 clock source */
#define LL_RCC_I2C4_CLKSOURCE_SYSCLK (((uint32_t)RCC_OFFSET_CCIPR2 << 24U) | ((uint32_t)RCC_CCIPR2_I2C4SEL_Pos << 16U) | (RCC_CCIPR2_I2C4SEL_0 >> RCC_CCIPR2_I2C4SEL_Pos)) /*!< SYSCLK clock used as I2C4 clock source */
#define LL_RCC_I2C4_CLKSOURCE_HSI (((uint32_t)RCC_OFFSET_CCIPR2 << 24U) | ((uint32_t)RCC_CCIPR2_I2C4SEL_Pos << 16U) | (RCC_CCIPR2_I2C4SEL_1 >> RCC_CCIPR2_I2C4SEL_Pos)) /*!< HSI clock used as I2C4 clock source */
#endif /* RCC_CCIPR2_I2C4SEL */
/**
* @}
*/
/** @defgroup RCC_LL_EC_LPTIM1_CLKSOURCE Peripheral LPTIM clock source selection
* @{
*/
#define LL_RCC_LPTIM1_CLKSOURCE_PCLK1 0x00000000U /*!< PCLK1 clock used as LPTIM1 clock source */
#define LL_RCC_LPTIM1_CLKSOURCE_LSI RCC_CCIPR_LPTIM1SEL_0 /*!< LSI clock used as LPTIM1 clock source */
#define LL_RCC_LPTIM1_CLKSOURCE_HSI RCC_CCIPR_LPTIM1SEL_1 /*!< HSI clock used as LPTIM1 clock source */
#define LL_RCC_LPTIM1_CLKSOURCE_LSE RCC_CCIPR_LPTIM1SEL /*!< LSE clock used as LPTIM1 clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_SAI1_CLKSOURCE Peripheral SAI clock source selection
* @{
*/
#define LL_RCC_SAI1_CLKSOURCE_SYSCLK 0x00000000U /*!< System clock used as SAI1 clock source */
#define LL_RCC_SAI1_CLKSOURCE_PLL RCC_CCIPR_SAI1SEL_0 /*!< PLL clock used as SAI1 clock source */
#define LL_RCC_SAI1_CLKSOURCE_PIN RCC_CCIPR_SAI1SEL_1 /*!< EXT clock used as SAI1 clock source */
#define LL_RCC_SAI1_CLKSOURCE_HSI (RCC_CCIPR_SAI1SEL_0 | RCC_CCIPR_SAI1SEL_1) /*!< HSI clock used as SAI1 clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_I2S_CLKSOURCE Peripheral I2S clock source selection
* @{
*/
#define LL_RCC_I2S_CLKSOURCE_SYSCLK 0x00000000U /*!< System clock used as I2S clock source */
#define LL_RCC_I2S_CLKSOURCE_PLL RCC_CCIPR_I2S23SEL_0 /*!< PLL clock used as I2S clock source */
#define LL_RCC_I2S_CLKSOURCE_PIN RCC_CCIPR_I2S23SEL_1 /*!< EXT clock used as I2S clock source */
#define LL_RCC_I2S_CLKSOURCE_HSI (RCC_CCIPR_I2S23SEL_0 | RCC_CCIPR_I2S23SEL_1) /*!< HSI clock used as I2S clock source */
/**
* @}
*/
#if defined(FDCAN1)
/** @defgroup RCC_LL_EC_FDCAN_CLKSOURCE Peripheral FDCAN clock source selection
* @{
*/
#define LL_RCC_FDCAN_CLKSOURCE_HSE 0x00000000U /*!< HSE clock used as FDCAN clock source */
#define LL_RCC_FDCAN_CLKSOURCE_PLL RCC_CCIPR_FDCANSEL_0 /*!< PLL clock used as FDCAN clock source */
#define LL_RCC_FDCAN_CLKSOURCE_PCLK1 RCC_CCIPR_FDCANSEL_1 /*!< PCLK1 clock used as FDCAN clock source */
/**
* @}
*/
#endif /* FDCAN1 */
/** @defgroup RCC_LL_EC_RNG_CLKSOURCE Peripheral RNG clock source selection
* @{
*/
#define LL_RCC_RNG_CLKSOURCE_HSI48 0x00000000U /*!< HSI48 clock used as RNG clock source */
#define LL_RCC_RNG_CLKSOURCE_PLL RCC_CCIPR_CLK48SEL_1 /*!< PLL clock used as RNG clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_USB_CLKSOURCE Peripheral USB clock source selection
* @{
*/
#define LL_RCC_USB_CLKSOURCE_HSI48 0x00000000U /*!< HSI48 clock used as USB clock source */
#define LL_RCC_USB_CLKSOURCE_PLL RCC_CCIPR_CLK48SEL_1 /*!< PLL clock used as USB clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_ADC_CLKSOURCE Peripheral ADC clock source selection
* @{
*/
#define LL_RCC_ADC12_CLKSOURCE_NONE (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC12SEL_Pos << 16U)) /*!< No clock used as ADC12 clock source */
#define LL_RCC_ADC12_CLKSOURCE_PLL (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC12SEL_Pos << 16U) | (RCC_CCIPR_ADC12SEL_0 >> RCC_CCIPR_ADC12SEL_Pos)) /*!< PLL clock used as ADC12 clock source */
#define LL_RCC_ADC12_CLKSOURCE_SYSCLK (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC12SEL_Pos << 16U) | (RCC_CCIPR_ADC12SEL_1 >> RCC_CCIPR_ADC12SEL_Pos)) /*!< SYSCLK clock used as ADC12 clock source */
#if defined(RCC_CCIPR_ADC345SEL)
#define LL_RCC_ADC345_CLKSOURCE_NONE (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC345SEL_Pos << 16U)) /*!< No clock used as ADC345 clock source */
#define LL_RCC_ADC345_CLKSOURCE_PLL (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC345SEL_Pos << 16U) | (RCC_CCIPR_ADC345SEL_0 >> RCC_CCIPR_ADC345SEL_Pos)) /*!< PLL clock used as ADC345 clock source */
#define LL_RCC_ADC345_CLKSOURCE_SYSCLK (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC345SEL_Pos << 16U) | (RCC_CCIPR_ADC345SEL_1 >> RCC_CCIPR_ADC345SEL_Pos)) /*!< SYSCLK clock used as ADC345 clock source */
#endif /* RCC_CCIPR_ADC345SEL */
/**
* @}
*/
/** @defgroup RCC_LL_EC_QUADSPI Peripheral QUADSPI get clock source
* @{
*/
#define LL_RCC_QUADSPI_CLKSOURCE_SYSCLK 0x00000000U /*!< SYSCLK used as QuadSPI clock source */
#define LL_RCC_QUADSPI_CLKSOURCE_HSI RCC_CCIPR2_QSPISEL_0 /*!< HSI used as QuadSPI clock source */
#define LL_RCC_QUADSPI_CLKSOURCE_PLL RCC_CCIPR2_QSPISEL_1 /*!< PLL used as QuadSPI clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_USARTx Peripheral USART get clock source
* @{
*/
#define LL_RCC_USART1_CLKSOURCE RCC_CCIPR_USART1SEL /*!< USART1 Clock source selection */
#define LL_RCC_USART2_CLKSOURCE RCC_CCIPR_USART2SEL /*!< USART2 Clock source selection */
#define LL_RCC_USART3_CLKSOURCE RCC_CCIPR_USART3SEL /*!< USART3 Clock source selection */
/**
* @}
*/
/** @defgroup RCC_LL_EC_UARTx Peripheral UART get clock source
* @{
*/
#if defined(RCC_CCIPR_UART4SEL)
#define LL_RCC_UART4_CLKSOURCE RCC_CCIPR_UART4SEL /*!< UART4 Clock source selection */
#endif /* RCC_CCIPR_UART4SEL */
#if defined(RCC_CCIPR_UART5SEL)
#define LL_RCC_UART5_CLKSOURCE RCC_CCIPR_UART5SEL /*!< UART5 Clock source selection */
#endif /* RCC_CCIPR_UART5SEL */
/**
* @}
*/
/** @defgroup RCC_LL_EC_LPUART1 Peripheral LPUART get clock source
* @{
*/
#define LL_RCC_LPUART1_CLKSOURCE RCC_CCIPR_LPUART1SEL /*!< LPUART1 Clock source selection */
/**
* @}
*/
/** @defgroup RCC_LL_EC_I2C1 Peripheral I2C get clock source
* @{
*/
#define LL_RCC_I2C1_CLKSOURCE (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C1SEL_Pos << 16U) | (RCC_CCIPR_I2C1SEL >> RCC_CCIPR_I2C1SEL_Pos)) /*!< I2C1 Clock source selection */
#define LL_RCC_I2C2_CLKSOURCE (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C2SEL_Pos << 16U) | (RCC_CCIPR_I2C2SEL >> RCC_CCIPR_I2C2SEL_Pos)) /*!< I2C2 Clock source selection */
#define LL_RCC_I2C3_CLKSOURCE (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_I2C3SEL_Pos << 16U) | (RCC_CCIPR_I2C3SEL >> RCC_CCIPR_I2C3SEL_Pos)) /*!< I2C3 Clock source selection */
#if defined(RCC_CCIPR2_I2C4SEL)
#define LL_RCC_I2C4_CLKSOURCE (((uint32_t)RCC_OFFSET_CCIPR2 << 24U) | ((uint32_t)RCC_CCIPR2_I2C4SEL_Pos << 16U) | (RCC_CCIPR2_I2C4SEL >> RCC_CCIPR2_I2C4SEL_Pos)) /*!< I2C4 Clock source selection */
#endif /* RCC_CCIPR2_I2C4SEL */
/**
* @}
*/
/** @defgroup RCC_LL_EC_LPTIM1 Peripheral LPTIM get clock source
* @{
*/
#define LL_RCC_LPTIM1_CLKSOURCE RCC_CCIPR_LPTIM1SEL /*!< LPTIM1 Clock source selection */
/**
* @}
*/
/** @defgroup RCC_LL_EC_SAI1 Peripheral SAI get clock source
* @{
*/
#define LL_RCC_SAI1_CLKSOURCE RCC_CCIPR_SAI1SEL /*!< SAI1 Clock source selection */
/**
* @}
*/
/** @defgroup RCC_LL_EC_I2S Peripheral I2S get clock source
* @{
*/
#define LL_RCC_I2S_CLKSOURCE RCC_CCIPR_I2S23SEL /*!< I2S Clock source selection */
/**
* @}
*/
#if defined(FDCAN1)
/** @defgroup RCC_LL_EC_FDCAN Peripheral FDCAN get clock source
* @{
*/
#define LL_RCC_FDCAN_CLKSOURCE RCC_CCIPR_FDCANSEL /*!< FDCAN Clock source selection */
#endif /* FDCAN1 */
/**
* @}
*/
/** @defgroup RCC_LL_EC_RNG Peripheral RNG get clock source
* @{
*/
#define LL_RCC_RNG_CLKSOURCE RCC_CCIPR_CLK48SEL /*!< RNG Clock source selection */
/**
* @}
*/
/** @defgroup RCC_LL_EC_USB Peripheral USB get clock source
* @{
*/
#define LL_RCC_USB_CLKSOURCE RCC_CCIPR_CLK48SEL /*!< USB Clock source selection */
/**
* @}
*/
/** @defgroup RCC_LL_EC_ADC Peripheral ADC get clock source
* @{
*/
#define LL_RCC_ADC12_CLKSOURCE (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC12SEL_Pos << 16U) | (RCC_CCIPR_ADC12SEL >> RCC_CCIPR_ADC12SEL_Pos)) /*!< ADC12 Clock source selection */
#if defined(RCC_CCIPR_ADC345SEL_Pos)
#define LL_RCC_ADC345_CLKSOURCE (((uint32_t)RCC_OFFSET_CCIPR << 24U) | ((uint32_t)RCC_CCIPR_ADC345SEL_Pos << 16U) | (RCC_CCIPR_ADC345SEL >> RCC_CCIPR_ADC345SEL_Pos)) /*!< ADC345 Clock source selection */
#endif /* RCC_CCIPR_ADC345SEL_Pos */
/**
* @}
*/
/** @defgroup RCC_LL_EC_QUADSPI Peripheral QUADSPI get clock source
* @{
*/
#define LL_RCC_QUADSPI_CLKSOURCE RCC_CCIPR2_QSPISEL /*!< QuadSPI Clock source selection */
/**
* @}
*/
/** @defgroup RCC_LL_EC_RTC_CLKSOURCE RTC clock source selection
* @{
*/
#define LL_RCC_RTC_CLKSOURCE_NONE 0x00000000U /*!< No clock used as RTC clock */
#define LL_RCC_RTC_CLKSOURCE_LSE RCC_BDCR_RTCSEL_0 /*!< LSE oscillator clock used as RTC clock */
#define LL_RCC_RTC_CLKSOURCE_LSI RCC_BDCR_RTCSEL_1 /*!< LSI oscillator clock used as RTC clock */
#define LL_RCC_RTC_CLKSOURCE_HSE_DIV32 RCC_BDCR_RTCSEL /*!< HSE oscillator clock divided by 32 used as RTC clock */
/**
* @}
*/
/** @defgroup RCC_LL_EC_PLLSOURCE PLL entry clock source
* @{
*/
#define LL_RCC_PLLSOURCE_NONE 0x00000000U /*!< No clock */
#define LL_RCC_PLLSOURCE_HSI RCC_PLLCFGR_PLLSRC_HSI /*!< HSI16 clock selected as PLL entry clock source */
#define LL_RCC_PLLSOURCE_HSE RCC_PLLCFGR_PLLSRC_HSE /*!< HSE clock selected as PLL entry clock source */
/**
* @}
*/
/** @defgroup RCC_LL_EC_PLLM_DIV PLL division factor
* @{
*/
#define LL_RCC_PLLM_DIV_1 0x00000000U /*!< PLL division factor by 1 */
#define LL_RCC_PLLM_DIV_2 RCC_PLLCFGR_PLLM_0 /*!< PLL division factor by 2 */
#define LL_RCC_PLLM_DIV_3 RCC_PLLCFGR_PLLM_1 /*!< PLL division factor by 3 */
#define LL_RCC_PLLM_DIV_4 (RCC_PLLCFGR_PLLM_1 | RCC_PLLCFGR_PLLM_0) /*!< PLL division factor by 4 */
#define LL_RCC_PLLM_DIV_5 RCC_PLLCFGR_PLLM_2 /*!< PLL division factor by 5 */
#define LL_RCC_PLLM_DIV_6 (RCC_PLLCFGR_PLLM_2 | RCC_PLLCFGR_PLLM_0) /*!< PLL division factor by 6 */
#define LL_RCC_PLLM_DIV_7 (RCC_PLLCFGR_PLLM_2 | RCC_PLLCFGR_PLLM_1) /*!< PLL division factor by 7 */
#define LL_RCC_PLLM_DIV_8 (RCC_PLLCFGR_PLLM_2 | RCC_PLLCFGR_PLLM_1 | RCC_PLLCFGR_PLLM_0) /*!< PLL division factor by 8 */
#define LL_RCC_PLLM_DIV_9 RCC_PLLCFGR_PLLM_3 /*!< PLL division factor by 9 */
#define LL_RCC_PLLM_DIV_10 (RCC_PLLCFGR_PLLM_3 | RCC_PLLCFGR_PLLM_0) /*!< PLL division factor by 10 */
#define LL_RCC_PLLM_DIV_11 (RCC_PLLCFGR_PLLM_3 | RCC_PLLCFGR_PLLM_1) /*!< PLL division factor by 11 */
#define LL_RCC_PLLM_DIV_12 (RCC_PLLCFGR_PLLM_3 | RCC_PLLCFGR_PLLM_1 | RCC_PLLCFGR_PLLM_0) /*!< PLL division factor by 12 */
#define LL_RCC_PLLM_DIV_13 (RCC_PLLCFGR_PLLM_3 | RCC_PLLCFGR_PLLM_2) /*!< PLL division factor by 13 */
#define LL_RCC_PLLM_DIV_14 (RCC_PLLCFGR_PLLM_3 | RCC_PLLCFGR_PLLM_2 | RCC_PLLCFGR_PLLM_0) /*!< PLL division factor by 14 */
#define LL_RCC_PLLM_DIV_15 (RCC_PLLCFGR_PLLM_3 | RCC_PLLCFGR_PLLM_2 | RCC_PLLCFGR_PLLM_1) /*!< PLL division factor by 15 */
#define LL_RCC_PLLM_DIV_16 (RCC_PLLCFGR_PLLM_3 | RCC_PLLCFGR_PLLM_2 | RCC_PLLCFGR_PLLM_1 | RCC_PLLCFGR_PLLM_0) /*!< PLL division factor by 16 */
/**
* @}
*/
/** @defgroup RCC_LL_EC_PLLR_DIV PLL division factor (PLLR)
* @{
*/
#define LL_RCC_PLLR_DIV_2 0x00000000U /*!< Main PLL division factor for PLLCLK (system clock) by 2 */
#define LL_RCC_PLLR_DIV_4 (RCC_PLLCFGR_PLLR_0) /*!< Main PLL division factor for PLLCLK (system clock) by 4 */
#define LL_RCC_PLLR_DIV_6 (RCC_PLLCFGR_PLLR_1) /*!< Main PLL division factor for PLLCLK (system clock) by 6 */
#define LL_RCC_PLLR_DIV_8 (RCC_PLLCFGR_PLLR) /*!< Main PLL division factor for PLLCLK (system clock) by 8 */
/**
* @}
*/
/** @defgroup RCC_LL_EC_PLLP_DIV PLL division factor (PLLP)
* @{
*/
#define LL_RCC_PLLP_DIV_2 (RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 2 */
#define LL_RCC_PLLP_DIV_3 (RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 3 */
#define LL_RCC_PLLP_DIV_4 (RCC_PLLCFGR_PLLPDIV_2) /*!< Main PLL division factor for PLLP output by 4 */
#define LL_RCC_PLLP_DIV_5 (RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 5 */
#define LL_RCC_PLLP_DIV_6 (RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 6 */
#define LL_RCC_PLLP_DIV_7 (RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 7 */
#define LL_RCC_PLLP_DIV_8 (RCC_PLLCFGR_PLLPDIV_3) /*!< Main PLL division factor for PLLP output by 8 */
#define LL_RCC_PLLP_DIV_9 (RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 9 */
#define LL_RCC_PLLP_DIV_10 (RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 10 */
#define LL_RCC_PLLP_DIV_11 (RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 11 */
#define LL_RCC_PLLP_DIV_12 (RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2) /*!< Main PLL division factor for PLLP output by 12 */
#define LL_RCC_PLLP_DIV_13 (RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 13 */
#define LL_RCC_PLLP_DIV_14 (RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 14 */
#define LL_RCC_PLLP_DIV_15 (RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 15 */
#define LL_RCC_PLLP_DIV_16 (RCC_PLLCFGR_PLLPDIV_4) /*!< Main PLL division factor for PLLP output by 16 */
#define LL_RCC_PLLP_DIV_17 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 17 */
#define LL_RCC_PLLP_DIV_18 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 18 */
#define LL_RCC_PLLP_DIV_19 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 19 */
#define LL_RCC_PLLP_DIV_20 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_2) /*!< Main PLL division factor for PLLP output by 20 */
#define LL_RCC_PLLP_DIV_21 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 21 */
#define LL_RCC_PLLP_DIV_22 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 22 */
#define LL_RCC_PLLP_DIV_23 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 23 */
#define LL_RCC_PLLP_DIV_24 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3) /*!< Main PLL division factor for PLLP output by 24 */
#define LL_RCC_PLLP_DIV_25 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 25 */
#define LL_RCC_PLLP_DIV_26 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 26 */
#define LL_RCC_PLLP_DIV_27 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 27 */
#define LL_RCC_PLLP_DIV_28 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2) /*!< Main PLL division factor for PLLP output by 28 */
#define LL_RCC_PLLP_DIV_29 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 29 */
#define LL_RCC_PLLP_DIV_30 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1) /*!< Main PLL division factor for PLLP output by 30 */
#define LL_RCC_PLLP_DIV_31 (RCC_PLLCFGR_PLLPDIV_4|RCC_PLLCFGR_PLLPDIV_3|RCC_PLLCFGR_PLLPDIV_2|RCC_PLLCFGR_PLLPDIV_1|RCC_PLLCFGR_PLLPDIV_0) /*!< Main PLL division factor for PLLP output by 31 */
/**
* @}
*/
/** @defgroup RCC_LL_EC_PLLQ_DIV PLL division factor (PLLQ)
* @{
*/
#define LL_RCC_PLLQ_DIV_2 0x00000000U /*!< Main PLL division factor for PLLQ output by 2 */
#define LL_RCC_PLLQ_DIV_4 (RCC_PLLCFGR_PLLQ_0) /*!< Main PLL division factor for PLLQ output by 4 */
#define LL_RCC_PLLQ_DIV_6 (RCC_PLLCFGR_PLLQ_1) /*!< Main PLL division factor for PLLQ output by 6 */
#define LL_RCC_PLLQ_DIV_8 (RCC_PLLCFGR_PLLQ) /*!< Main PLL division factor for PLLQ output by 8 */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/** @defgroup RCC_LL_Exported_Macros RCC Exported Macros
* @{
*/
/** @defgroup RCC_LL_EM_WRITE_READ Common Write and read registers Macros
* @{
*/
/**
* @brief Write a value in RCC register
* @param __REG__ Register to be written
* @param __VALUE__ Value to be written in the register
* @retval None
*/
#define LL_RCC_WriteReg(__REG__, __VALUE__) WRITE_REG(RCC->__REG__, __VALUE__)
/**
* @brief Read a value in RCC register
* @param __REG__ Register to be read
* @retval Register value
*/
#define LL_RCC_ReadReg(__REG__) READ_REG(RCC->__REG__)
/**
* @}
*/
/** @defgroup RCC_LL_EM_CALC_FREQ Calculate frequencies
* @{
*/
/**
* @brief Helper macro to calculate the PLLCLK frequency on system domain
* @note ex: @ref __LL_RCC_CALC_PLLCLK_FREQ (HSE_VALUE,@ref LL_RCC_PLL_GetDivider (),
* @ref LL_RCC_PLL_GetN (), @ref LL_RCC_PLL_GetR ());
* @param __INPUTFREQ__ PLL Input frequency (based on HSE/HSI)
* @param __PLLM__ This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLM_DIV_1
* @arg @ref LL_RCC_PLLM_DIV_2
* @arg @ref LL_RCC_PLLM_DIV_3
* @arg @ref LL_RCC_PLLM_DIV_4
* @arg @ref LL_RCC_PLLM_DIV_5
* @arg @ref LL_RCC_PLLM_DIV_6
* @arg @ref LL_RCC_PLLM_DIV_7
* @arg @ref LL_RCC_PLLM_DIV_8
* @arg @ref LL_RCC_PLLM_DIV_9
* @arg @ref LL_RCC_PLLM_DIV_10
* @arg @ref LL_RCC_PLLM_DIV_11
* @arg @ref LL_RCC_PLLM_DIV_12
* @arg @ref LL_RCC_PLLM_DIV_13
* @arg @ref LL_RCC_PLLM_DIV_14
* @arg @ref LL_RCC_PLLM_DIV_15
* @arg @ref LL_RCC_PLLM_DIV_16
* @param __PLLN__ Between Min_Data = 8 and Max_Data = 127
* @param __PLLR__ This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLR_DIV_2
* @arg @ref LL_RCC_PLLR_DIV_4
* @arg @ref LL_RCC_PLLR_DIV_6
* @arg @ref LL_RCC_PLLR_DIV_8
* @retval PLL clock frequency (in Hz)
*/
#define __LL_RCC_CALC_PLLCLK_FREQ(__INPUTFREQ__, __PLLM__, __PLLN__, __PLLR__) ((__INPUTFREQ__) * (__PLLN__) / ((((__PLLM__)>> RCC_PLLCFGR_PLLM_Pos) + 1U)) / \
((((__PLLR__) >> RCC_PLLCFGR_PLLR_Pos) + 1U) * 2U))
/**
* @brief Helper macro to calculate the PLLCLK frequency used on ADC domain
* @note ex: @ref __LL_RCC_CALC_PLLCLK_ADC_FREQ (HSE_VALUE,@ref LL_RCC_PLL_GetDivider (),
* @ref LL_RCC_PLL_GetN (), @ref LL_RCC_PLL_GetP ());
* @param __INPUTFREQ__ PLL Input frequency (based on HSE/HSI)
* @param __PLLM__ This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLM_DIV_1
* @arg @ref LL_RCC_PLLM_DIV_2
* @arg @ref LL_RCC_PLLM_DIV_3
* @arg @ref LL_RCC_PLLM_DIV_4
* @arg @ref LL_RCC_PLLM_DIV_5
* @arg @ref LL_RCC_PLLM_DIV_6
* @arg @ref LL_RCC_PLLM_DIV_7
* @arg @ref LL_RCC_PLLM_DIV_8
* @arg @ref LL_RCC_PLLM_DIV_9
* @arg @ref LL_RCC_PLLM_DIV_10
* @arg @ref LL_RCC_PLLM_DIV_11
* @arg @ref LL_RCC_PLLM_DIV_12
* @arg @ref LL_RCC_PLLM_DIV_13
* @arg @ref LL_RCC_PLLM_DIV_14
* @arg @ref LL_RCC_PLLM_DIV_15
* @arg @ref LL_RCC_PLLM_DIV_16
* @param __PLLN__ Between Min_Data = 8 and Max_Data = 127
* @param __PLLP__ This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLP_DIV_2
* @arg @ref LL_RCC_PLLP_DIV_3
* @arg @ref LL_RCC_PLLP_DIV_4
* @arg @ref LL_RCC_PLLP_DIV_5
* @arg @ref LL_RCC_PLLP_DIV_6
* @arg @ref LL_RCC_PLLP_DIV_7
* @arg @ref LL_RCC_PLLP_DIV_8
* @arg @ref LL_RCC_PLLP_DIV_9
* @arg @ref LL_RCC_PLLP_DIV_10
* @arg @ref LL_RCC_PLLP_DIV_11
* @arg @ref LL_RCC_PLLP_DIV_12
* @arg @ref LL_RCC_PLLP_DIV_13
* @arg @ref LL_RCC_PLLP_DIV_14
* @arg @ref LL_RCC_PLLP_DIV_15
* @arg @ref LL_RCC_PLLP_DIV_16
* @arg @ref LL_RCC_PLLP_DIV_17
* @arg @ref LL_RCC_PLLP_DIV_18
* @arg @ref LL_RCC_PLLP_DIV_19
* @arg @ref LL_RCC_PLLP_DIV_20
* @arg @ref LL_RCC_PLLP_DIV_21
* @arg @ref LL_RCC_PLLP_DIV_22
* @arg @ref LL_RCC_PLLP_DIV_23
* @arg @ref LL_RCC_PLLP_DIV_24
* @arg @ref LL_RCC_PLLP_DIV_25
* @arg @ref LL_RCC_PLLP_DIV_26
* @arg @ref LL_RCC_PLLP_DIV_27
* @arg @ref LL_RCC_PLLP_DIV_28
* @arg @ref LL_RCC_PLLP_DIV_29
* @arg @ref LL_RCC_PLLP_DIV_30
* @arg @ref LL_RCC_PLLP_DIV_31
* @retval PLL clock frequency (in Hz)
*/
#define __LL_RCC_CALC_PLLCLK_ADC_FREQ(__INPUTFREQ__, __PLLM__, __PLLN__, __PLLP__) ((__INPUTFREQ__) * (__PLLN__) / ((((__PLLM__)>> RCC_PLLCFGR_PLLM_Pos) + 1U)) / \
((__PLLP__) >> RCC_PLLCFGR_PLLPDIV_Pos))
/**
* @brief Helper macro to calculate the PLLCLK frequency used on 48M domain
* @note ex: @ref __LL_RCC_CALC_PLLCLK_48M_FREQ (HSE_VALUE,@ref LL_RCC_PLL_GetDivider (),
* @ref LL_RCC_PLL_GetN (), @ref LL_RCC_PLL_GetQ ());
* @param __INPUTFREQ__ PLL Input frequency (based on HSE/HSI)
* @param __PLLM__ This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLM_DIV_1
* @arg @ref LL_RCC_PLLM_DIV_2
* @arg @ref LL_RCC_PLLM_DIV_3
* @arg @ref LL_RCC_PLLM_DIV_4
* @arg @ref LL_RCC_PLLM_DIV_5
* @arg @ref LL_RCC_PLLM_DIV_6
* @arg @ref LL_RCC_PLLM_DIV_7
* @arg @ref LL_RCC_PLLM_DIV_8
* @arg @ref LL_RCC_PLLM_DIV_9
* @arg @ref LL_RCC_PLLM_DIV_10
* @arg @ref LL_RCC_PLLM_DIV_11
* @arg @ref LL_RCC_PLLM_DIV_12
* @arg @ref LL_RCC_PLLM_DIV_13
* @arg @ref LL_RCC_PLLM_DIV_14
* @arg @ref LL_RCC_PLLM_DIV_15
* @arg @ref LL_RCC_PLLM_DIV_16
* @param __PLLN__ Between Min_Data = 8 and Max_Data = 127
* @param __PLLQ__ This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLQ_DIV_2
* @arg @ref LL_RCC_PLLQ_DIV_4
* @arg @ref LL_RCC_PLLQ_DIV_6
* @arg @ref LL_RCC_PLLQ_DIV_8
* @retval PLL clock frequency (in Hz)
*/
#define __LL_RCC_CALC_PLLCLK_48M_FREQ(__INPUTFREQ__, __PLLM__, __PLLN__, __PLLQ__) ((__INPUTFREQ__) * (__PLLN__) / ((((__PLLM__)>> RCC_PLLCFGR_PLLM_Pos) + 1U)) / \
((((__PLLQ__) >> RCC_PLLCFGR_PLLQ_Pos) + 1U) << 1U))
/**
* @brief Helper macro to calculate the HCLK frequency
* @param __SYSCLKFREQ__ SYSCLK frequency (based on HSE/HSI/PLLCLK)
* @param __AHBPRESCALER__ This parameter can be one of the following values:
* @arg @ref LL_RCC_SYSCLK_DIV_1
* @arg @ref LL_RCC_SYSCLK_DIV_2
* @arg @ref LL_RCC_SYSCLK_DIV_4
* @arg @ref LL_RCC_SYSCLK_DIV_8
* @arg @ref LL_RCC_SYSCLK_DIV_16
* @arg @ref LL_RCC_SYSCLK_DIV_64
* @arg @ref LL_RCC_SYSCLK_DIV_128
* @arg @ref LL_RCC_SYSCLK_DIV_256
* @arg @ref LL_RCC_SYSCLK_DIV_512
* @retval HCLK clock frequency (in Hz)
*/
#define __LL_RCC_CALC_HCLK_FREQ(__SYSCLKFREQ__,__AHBPRESCALER__) ((__SYSCLKFREQ__) >> (AHBPrescTable[((__AHBPRESCALER__) & RCC_CFGR_HPRE) >> RCC_CFGR_HPRE_Pos] & 0x1FU))
/**
* @brief Helper macro to calculate the PCLK1 frequency (ABP1)
* @param __HCLKFREQ__ HCLK frequency
* @param __APB1PRESCALER__ This parameter can be one of the following values:
* @arg @ref LL_RCC_APB1_DIV_1
* @arg @ref LL_RCC_APB1_DIV_2
* @arg @ref LL_RCC_APB1_DIV_4
* @arg @ref LL_RCC_APB1_DIV_8
* @arg @ref LL_RCC_APB1_DIV_16
* @retval PCLK1 clock frequency (in Hz)
*/
#define __LL_RCC_CALC_PCLK1_FREQ(__HCLKFREQ__, __APB1PRESCALER__) ((__HCLKFREQ__) >> (APBPrescTable[(__APB1PRESCALER__) >> RCC_CFGR_PPRE1_Pos] & 0x1FU))
/**
* @brief Helper macro to calculate the PCLK2 frequency (ABP2)
* @param __HCLKFREQ__ HCLK frequency
* @param __APB2PRESCALER__ This parameter can be one of the following values:
* @arg @ref LL_RCC_APB2_DIV_1
* @arg @ref LL_RCC_APB2_DIV_2
* @arg @ref LL_RCC_APB2_DIV_4
* @arg @ref LL_RCC_APB2_DIV_8
* @arg @ref LL_RCC_APB2_DIV_16
* @retval PCLK2 clock frequency (in Hz)
*/
#define __LL_RCC_CALC_PCLK2_FREQ(__HCLKFREQ__, __APB2PRESCALER__) ((__HCLKFREQ__) >> (APBPrescTable[(__APB2PRESCALER__) >> RCC_CFGR_PPRE2_Pos] & 0x1FU))
/**
* @}
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup RCC_LL_Exported_Functions RCC Exported Functions
* @{
*/
/** @defgroup RCC_LL_EF_HSE HSE
* @{
*/
/**
* @brief Enable the Clock Security System.
* @rmtoll CR CSSON LL_RCC_HSE_EnableCSS
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSE_EnableCSS(void)
{
SET_BIT(RCC->CR, RCC_CR_CSSON);
}
/**
* @brief Enable HSE external oscillator (HSE Bypass)
* @rmtoll CR HSEBYP LL_RCC_HSE_EnableBypass
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSE_EnableBypass(void)
{
SET_BIT(RCC->CR, RCC_CR_HSEBYP);
}
/**
* @brief Disable HSE external oscillator (HSE Bypass)
* @rmtoll CR HSEBYP LL_RCC_HSE_DisableBypass
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSE_DisableBypass(void)
{
CLEAR_BIT(RCC->CR, RCC_CR_HSEBYP);
}
/**
* @brief Enable HSE crystal oscillator (HSE ON)
* @rmtoll CR HSEON LL_RCC_HSE_Enable
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSE_Enable(void)
{
SET_BIT(RCC->CR, RCC_CR_HSEON);
}
/**
* @brief Disable HSE crystal oscillator (HSE ON)
* @rmtoll CR HSEON LL_RCC_HSE_Disable
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSE_Disable(void)
{
CLEAR_BIT(RCC->CR, RCC_CR_HSEON);
}
/**
* @brief Check if HSE oscillator Ready
* @rmtoll CR HSERDY LL_RCC_HSE_IsReady
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_HSE_IsReady(void)
{
return ((READ_BIT(RCC->CR, RCC_CR_HSERDY) == (RCC_CR_HSERDY)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_HSI HSI
* @{
*/
/**
* @brief Enable HSI even in stop mode
* @note HSI oscillator is forced ON even in Stop mode
* @rmtoll CR HSIKERON LL_RCC_HSI_EnableInStopMode
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSI_EnableInStopMode(void)
{
SET_BIT(RCC->CR, RCC_CR_HSIKERON);
}
/**
* @brief Disable HSI in stop mode
* @rmtoll CR HSIKERON LL_RCC_HSI_DisableInStopMode
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSI_DisableInStopMode(void)
{
CLEAR_BIT(RCC->CR, RCC_CR_HSIKERON);
}
/**
* @brief Enable HSI oscillator
* @rmtoll CR HSION LL_RCC_HSI_Enable
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSI_Enable(void)
{
SET_BIT(RCC->CR, RCC_CR_HSION);
}
/**
* @brief Disable HSI oscillator
* @rmtoll CR HSION LL_RCC_HSI_Disable
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSI_Disable(void)
{
CLEAR_BIT(RCC->CR, RCC_CR_HSION);
}
/**
* @brief Check if HSI clock is ready
* @rmtoll CR HSIRDY LL_RCC_HSI_IsReady
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_HSI_IsReady(void)
{
return ((READ_BIT(RCC->CR, RCC_CR_HSIRDY) == (RCC_CR_HSIRDY)) ? 1UL : 0UL);
}
/**
* @brief Get HSI Calibration value
* @note When HSITRIM is written, HSICAL is updated with the sum of
* HSITRIM and the factory trim value
* @rmtoll ICSCR HSICAL LL_RCC_HSI_GetCalibration
* @retval Between Min_Data = 0x00 and Max_Data = 0xFF
*/
__STATIC_INLINE uint32_t LL_RCC_HSI_GetCalibration(void)
{
return (uint32_t)(READ_BIT(RCC->ICSCR, RCC_ICSCR_HSICAL) >> RCC_ICSCR_HSICAL_Pos);
}
/**
* @brief Set HSI Calibration trimming
* @note user-programmable trimming value that is added to the HSICAL
* @note Default value is 16, which, when added to the HSICAL value,
* should trim the HSI to 16 MHz +/- 1 %
* @rmtoll ICSCR HSITRIM LL_RCC_HSI_SetCalibTrimming
* @param Value Between Min_Data = 0 and Max_Data = 127
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSI_SetCalibTrimming(uint32_t Value)
{
MODIFY_REG(RCC->ICSCR, RCC_ICSCR_HSITRIM, Value << RCC_ICSCR_HSITRIM_Pos);
}
/**
* @brief Get HSI Calibration trimming
* @rmtoll ICSCR HSITRIM LL_RCC_HSI_GetCalibTrimming
* @retval Between Min_Data = 0 and Max_Data = 127
*/
__STATIC_INLINE uint32_t LL_RCC_HSI_GetCalibTrimming(void)
{
return (uint32_t)(READ_BIT(RCC->ICSCR, RCC_ICSCR_HSITRIM) >> RCC_ICSCR_HSITRIM_Pos);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_HSI48 HSI48
* @{
*/
/**
* @brief Enable HSI48
* @rmtoll CRRCR HSI48ON LL_RCC_HSI48_Enable
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSI48_Enable(void)
{
SET_BIT(RCC->CRRCR, RCC_CRRCR_HSI48ON);
}
/**
* @brief Disable HSI48
* @rmtoll CRRCR HSI48ON LL_RCC_HSI48_Disable
* @retval None
*/
__STATIC_INLINE void LL_RCC_HSI48_Disable(void)
{
CLEAR_BIT(RCC->CRRCR, RCC_CRRCR_HSI48ON);
}
/**
* @brief Check if HSI48 oscillator Ready
* @rmtoll CRRCR HSI48RDY LL_RCC_HSI48_IsReady
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_HSI48_IsReady(void)
{
return ((READ_BIT(RCC->CRRCR, RCC_CRRCR_HSI48RDY) == (RCC_CRRCR_HSI48RDY)) ? 1UL : 0UL);
}
/**
* @brief Get HSI48 Calibration value
* @rmtoll CRRCR HSI48CAL LL_RCC_HSI48_GetCalibration
* @retval Between Min_Data = 0x00 and Max_Data = 0x1FF
*/
__STATIC_INLINE uint32_t LL_RCC_HSI48_GetCalibration(void)
{
return (uint32_t)(READ_BIT(RCC->CRRCR, RCC_CRRCR_HSI48CAL) >> RCC_CRRCR_HSI48CAL_Pos);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_LSE LSE
* @{
*/
/**
* @brief Enable Low Speed External (LSE) crystal.
* @rmtoll BDCR LSEON LL_RCC_LSE_Enable
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSE_Enable(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_LSEON);
}
/**
* @brief Disable Low Speed External (LSE) crystal.
* @rmtoll BDCR LSEON LL_RCC_LSE_Disable
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSE_Disable(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEON);
}
/**
* @brief Enable external clock source (LSE bypass).
* @rmtoll BDCR LSEBYP LL_RCC_LSE_EnableBypass
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSE_EnableBypass(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_LSEBYP);
}
/**
* @brief Disable external clock source (LSE bypass).
* @rmtoll BDCR LSEBYP LL_RCC_LSE_DisableBypass
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSE_DisableBypass(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSEBYP);
}
/**
* @brief Set LSE oscillator drive capability
* @note The oscillator is in Xtal mode when it is not in bypass mode.
* @rmtoll BDCR LSEDRV LL_RCC_LSE_SetDriveCapability
* @param LSEDrive This parameter can be one of the following values:
* @arg @ref LL_RCC_LSEDRIVE_LOW
* @arg @ref LL_RCC_LSEDRIVE_MEDIUMLOW
* @arg @ref LL_RCC_LSEDRIVE_MEDIUMHIGH
* @arg @ref LL_RCC_LSEDRIVE_HIGH
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSE_SetDriveCapability(uint32_t LSEDrive)
{
MODIFY_REG(RCC->BDCR, RCC_BDCR_LSEDRV, LSEDrive);
}
/**
* @brief Get LSE oscillator drive capability
* @rmtoll BDCR LSEDRV LL_RCC_LSE_GetDriveCapability
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_LSEDRIVE_LOW
* @arg @ref LL_RCC_LSEDRIVE_MEDIUMLOW
* @arg @ref LL_RCC_LSEDRIVE_MEDIUMHIGH
* @arg @ref LL_RCC_LSEDRIVE_HIGH
*/
__STATIC_INLINE uint32_t LL_RCC_LSE_GetDriveCapability(void)
{
return (uint32_t)(READ_BIT(RCC->BDCR, RCC_BDCR_LSEDRV));
}
/**
* @brief Enable Clock security system on LSE.
* @rmtoll BDCR LSECSSON LL_RCC_LSE_EnableCSS
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSE_EnableCSS(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_LSECSSON);
}
/**
* @brief Disable Clock security system on LSE.
* @note Clock security system can be disabled only after a LSE
* failure detection. In that case it MUST be disabled by software.
* @rmtoll BDCR LSECSSON LL_RCC_LSE_DisableCSS
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSE_DisableCSS(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSECSSON);
}
/**
* @brief Check if LSE oscillator Ready
* @rmtoll BDCR LSERDY LL_RCC_LSE_IsReady
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_LSE_IsReady(void)
{
return ((READ_BIT(RCC->BDCR, RCC_BDCR_LSERDY) == (RCC_BDCR_LSERDY)) ? 1UL : 0UL);
}
/**
* @brief Check if CSS on LSE failure Detection
* @rmtoll BDCR LSECSSD LL_RCC_LSE_IsCSSDetected
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_LSE_IsCSSDetected(void)
{
return ((READ_BIT(RCC->BDCR, RCC_BDCR_LSECSSD) == (RCC_BDCR_LSECSSD)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_LSI LSI
* @{
*/
/**
* @brief Enable LSI Oscillator
* @rmtoll CSR LSION LL_RCC_LSI_Enable
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSI_Enable(void)
{
SET_BIT(RCC->CSR, RCC_CSR_LSION);
}
/**
* @brief Disable LSI Oscillator
* @rmtoll CSR LSION LL_RCC_LSI_Disable
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSI_Disable(void)
{
CLEAR_BIT(RCC->CSR, RCC_CSR_LSION);
}
/**
* @brief Check if LSI is Ready
* @rmtoll CSR LSIRDY LL_RCC_LSI_IsReady
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_LSI_IsReady(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_LSIRDY) == (RCC_CSR_LSIRDY)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_LSCO LSCO
* @{
*/
/**
* @brief Enable Low speed clock
* @rmtoll BDCR LSCOEN LL_RCC_LSCO_Enable
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSCO_Enable(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_LSCOEN);
}
/**
* @brief Disable Low speed clock
* @rmtoll BDCR LSCOEN LL_RCC_LSCO_Disable
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSCO_Disable(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_LSCOEN);
}
/**
* @brief Configure Low speed clock selection
* @rmtoll BDCR LSCOSEL LL_RCC_LSCO_SetSource
* @param Source This parameter can be one of the following values:
* @arg @ref LL_RCC_LSCO_CLKSOURCE_LSI
* @arg @ref LL_RCC_LSCO_CLKSOURCE_LSE
* @retval None
*/
__STATIC_INLINE void LL_RCC_LSCO_SetSource(uint32_t Source)
{
MODIFY_REG(RCC->BDCR, RCC_BDCR_LSCOSEL, Source);
}
/**
* @brief Get Low speed clock selection
* @rmtoll BDCR LSCOSEL LL_RCC_LSCO_GetSource
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_LSCO_CLKSOURCE_LSI
* @arg @ref LL_RCC_LSCO_CLKSOURCE_LSE
*/
__STATIC_INLINE uint32_t LL_RCC_LSCO_GetSource(void)
{
return (uint32_t)(READ_BIT(RCC->BDCR, RCC_BDCR_LSCOSEL));
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_System System
* @{
*/
/**
* @brief Configure the system clock source
* @rmtoll CFGR SW LL_RCC_SetSysClkSource
* @param Source This parameter can be one of the following values:
* @arg @ref LL_RCC_SYS_CLKSOURCE_HSI
* @arg @ref LL_RCC_SYS_CLKSOURCE_HSE
* @arg @ref LL_RCC_SYS_CLKSOURCE_PLL
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetSysClkSource(uint32_t Source)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_SW, Source);
}
/**
* @brief Get the system clock source
* @rmtoll CFGR SWS LL_RCC_GetSysClkSource
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_SYS_CLKSOURCE_STATUS_HSI
* @arg @ref LL_RCC_SYS_CLKSOURCE_STATUS_HSE
* @arg @ref LL_RCC_SYS_CLKSOURCE_STATUS_PLL
*/
__STATIC_INLINE uint32_t LL_RCC_GetSysClkSource(void)
{
return (uint32_t)(READ_BIT(RCC->CFGR, RCC_CFGR_SWS));
}
/**
* @brief Set AHB prescaler
* @rmtoll CFGR HPRE LL_RCC_SetAHBPrescaler
* @param Prescaler This parameter can be one of the following values:
* @arg @ref LL_RCC_SYSCLK_DIV_1
* @arg @ref LL_RCC_SYSCLK_DIV_2
* @arg @ref LL_RCC_SYSCLK_DIV_4
* @arg @ref LL_RCC_SYSCLK_DIV_8
* @arg @ref LL_RCC_SYSCLK_DIV_16
* @arg @ref LL_RCC_SYSCLK_DIV_64
* @arg @ref LL_RCC_SYSCLK_DIV_128
* @arg @ref LL_RCC_SYSCLK_DIV_256
* @arg @ref LL_RCC_SYSCLK_DIV_512
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetAHBPrescaler(uint32_t Prescaler)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_HPRE, Prescaler);
}
/**
* @brief Set APB1 prescaler
* @rmtoll CFGR PPRE1 LL_RCC_SetAPB1Prescaler
* @param Prescaler This parameter can be one of the following values:
* @arg @ref LL_RCC_APB1_DIV_1
* @arg @ref LL_RCC_APB1_DIV_2
* @arg @ref LL_RCC_APB1_DIV_4
* @arg @ref LL_RCC_APB1_DIV_8
* @arg @ref LL_RCC_APB1_DIV_16
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetAPB1Prescaler(uint32_t Prescaler)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE1, Prescaler);
}
/**
* @brief Set APB2 prescaler
* @rmtoll CFGR PPRE2 LL_RCC_SetAPB2Prescaler
* @param Prescaler This parameter can be one of the following values:
* @arg @ref LL_RCC_APB2_DIV_1
* @arg @ref LL_RCC_APB2_DIV_2
* @arg @ref LL_RCC_APB2_DIV_4
* @arg @ref LL_RCC_APB2_DIV_8
* @arg @ref LL_RCC_APB2_DIV_16
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetAPB2Prescaler(uint32_t Prescaler)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_PPRE2, Prescaler);
}
/**
* @brief Get AHB prescaler
* @rmtoll CFGR HPRE LL_RCC_GetAHBPrescaler
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_SYSCLK_DIV_1
* @arg @ref LL_RCC_SYSCLK_DIV_2
* @arg @ref LL_RCC_SYSCLK_DIV_4
* @arg @ref LL_RCC_SYSCLK_DIV_8
* @arg @ref LL_RCC_SYSCLK_DIV_16
* @arg @ref LL_RCC_SYSCLK_DIV_64
* @arg @ref LL_RCC_SYSCLK_DIV_128
* @arg @ref LL_RCC_SYSCLK_DIV_256
* @arg @ref LL_RCC_SYSCLK_DIV_512
*/
__STATIC_INLINE uint32_t LL_RCC_GetAHBPrescaler(void)
{
return (uint32_t)(READ_BIT(RCC->CFGR, RCC_CFGR_HPRE));
}
/**
* @brief Get APB1 prescaler
* @rmtoll CFGR PPRE1 LL_RCC_GetAPB1Prescaler
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_APB1_DIV_1
* @arg @ref LL_RCC_APB1_DIV_2
* @arg @ref LL_RCC_APB1_DIV_4
* @arg @ref LL_RCC_APB1_DIV_8
* @arg @ref LL_RCC_APB1_DIV_16
*/
__STATIC_INLINE uint32_t LL_RCC_GetAPB1Prescaler(void)
{
return (uint32_t)(READ_BIT(RCC->CFGR, RCC_CFGR_PPRE1));
}
/**
* @brief Get APB2 prescaler
* @rmtoll CFGR PPRE2 LL_RCC_GetAPB2Prescaler
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_APB2_DIV_1
* @arg @ref LL_RCC_APB2_DIV_2
* @arg @ref LL_RCC_APB2_DIV_4
* @arg @ref LL_RCC_APB2_DIV_8
* @arg @ref LL_RCC_APB2_DIV_16
*/
__STATIC_INLINE uint32_t LL_RCC_GetAPB2Prescaler(void)
{
return (uint32_t)(READ_BIT(RCC->CFGR, RCC_CFGR_PPRE2));
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_MCO MCO
* @{
*/
/**
* @brief Configure MCOx
* @rmtoll CFGR MCOSEL LL_RCC_ConfigMCO\n
* CFGR MCOPRE LL_RCC_ConfigMCO
* @param MCOxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_MCO1SOURCE_NOCLOCK
* @arg @ref LL_RCC_MCO1SOURCE_SYSCLK
* @arg @ref LL_RCC_MCO1SOURCE_HSI
* @arg @ref LL_RCC_MCO1SOURCE_HSE
* @arg @ref LL_RCC_MCO1SOURCE_HSI48
* @arg @ref LL_RCC_MCO1SOURCE_PLLCLK
* @arg @ref LL_RCC_MCO1SOURCE_LSI
* @arg @ref LL_RCC_MCO1SOURCE_LSE
*
* (*) value not defined in all devices.
* @param MCOxPrescaler This parameter can be one of the following values:
* @arg @ref LL_RCC_MCO1_DIV_1
* @arg @ref LL_RCC_MCO1_DIV_2
* @arg @ref LL_RCC_MCO1_DIV_4
* @arg @ref LL_RCC_MCO1_DIV_8
* @arg @ref LL_RCC_MCO1_DIV_16
* @retval None
*/
__STATIC_INLINE void LL_RCC_ConfigMCO(uint32_t MCOxSource, uint32_t MCOxPrescaler)
{
MODIFY_REG(RCC->CFGR, RCC_CFGR_MCOSEL | RCC_CFGR_MCOPRE, MCOxSource | MCOxPrescaler);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_Peripheral_Clock_Source Peripheral Clock Source
* @{
*/
/**
* @brief Configure USARTx clock source
* @rmtoll CCIPR USARTxSEL LL_RCC_SetUSARTClockSource
* @param USARTxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_USART1_CLKSOURCE_PCLK2
* @arg @ref LL_RCC_USART1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_USART1_CLKSOURCE_HSI
* @arg @ref LL_RCC_USART1_CLKSOURCE_LSE
* @arg @ref LL_RCC_USART2_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_USART2_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_USART2_CLKSOURCE_HSI
* @arg @ref LL_RCC_USART2_CLKSOURCE_LSE
* @arg @ref LL_RCC_USART3_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_USART3_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_USART3_CLKSOURCE_HSI
* @arg @ref LL_RCC_USART3_CLKSOURCE_LSE
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetUSARTClockSource(uint32_t USARTxSource)
{
MODIFY_REG(RCC->CCIPR, (USARTxSource >> 16U), (USARTxSource & 0x0000FFFFU));
}
#if defined(UART4)
/**
* @brief Configure UARTx clock source
* @rmtoll CCIPR UARTxSEL LL_RCC_SetUARTClockSource
* @param UARTxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_UART4_CLKSOURCE_PCLK1 (*)
* @arg @ref LL_RCC_UART4_CLKSOURCE_SYSCLK (*)
* @arg @ref LL_RCC_UART4_CLKSOURCE_HSI (*)
* @arg @ref LL_RCC_UART4_CLKSOURCE_LSE (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_PCLK1 (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_SYSCLK (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_HSI (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_LSE (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetUARTClockSource(uint32_t UARTxSource)
{
MODIFY_REG(RCC->CCIPR, (UARTxSource >> 16U), (UARTxSource & 0x0000FFFFU));
}
#endif /* UART4 */
/**
* @brief Configure LPUART1x clock source
* @rmtoll CCIPR LPUART1SEL LL_RCC_SetLPUARTClockSource
* @param LPUARTxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_HSI
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_LSE
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetLPUARTClockSource(uint32_t LPUARTxSource)
{
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_LPUART1SEL, LPUARTxSource);
}
/**
* @brief Configure I2Cx clock source
* @rmtoll CCIPR I2CxSEL LL_RCC_SetI2CClockSource
* @param I2CxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_I2C1_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_I2C1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2C1_CLKSOURCE_HSI
* @arg @ref LL_RCC_I2C2_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_I2C2_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2C2_CLKSOURCE_HSI
* @arg @ref LL_RCC_I2C3_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_I2C3_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2C3_CLKSOURCE_HSI
* @arg @ref LL_RCC_I2C4_CLKSOURCE_PCLK1 (*)
* @arg @ref LL_RCC_I2C4_CLKSOURCE_SYSCLK (*)
* @arg @ref LL_RCC_I2C4_CLKSOURCE_HSI (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetI2CClockSource(uint32_t I2CxSource)
{
__IO uint32_t *reg = (__IO uint32_t *)(uint32_t)(RCC_BASE + 0x88U + (I2CxSource >> 24U));
MODIFY_REG(*reg, 3UL << ((I2CxSource & 0x001F0000U) >> 16U), ((I2CxSource & 0x000000FFU) << ((I2CxSource & 0x001F0000U) >> 16U)));
}
/**
* @brief Configure LPTIMx clock source
* @rmtoll CCIPR LPTIM1SEL LL_RCC_SetLPTIMClockSource
* @param LPTIMxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_LSI
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_HSI
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_LSE
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetLPTIMClockSource(uint32_t LPTIMxSource)
{
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_LPTIM1SEL, LPTIMxSource);
}
/**
* @brief Configure SAIx clock source
* @rmtoll CCIPR SAI1SEL LL_RCC_SetSAIClockSource
* @param SAIxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_SAI1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_SAI1_CLKSOURCE_PLL
* @arg @ref LL_RCC_SAI1_CLKSOURCE_PIN
* @arg @ref LL_RCC_SAI1_CLKSOURCE_HSI
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetSAIClockSource(uint32_t SAIxSource)
{
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_SAI1SEL, SAIxSource);
}
/**
* @brief Configure I2S clock source
* @rmtoll CCIPR I2S23SEL LL_RCC_SetI2SClockSource
* @param I2SxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_I2S_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2S_CLKSOURCE_PLL
* @arg @ref LL_RCC_I2S_CLKSOURCE_PIN
* @arg @ref LL_RCC_I2S_CLKSOURCE_HSI
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetI2SClockSource(uint32_t I2SxSource)
{
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_I2S23SEL, I2SxSource);
}
#if defined(FDCAN1)
/**
* @brief Configure FDCAN clock source
* @rmtoll CCIPR FDCANSEL LL_RCC_SetFDCANClockSource
* @param FDCANxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_FDCAN_CLKSOURCE_HSE
* @arg @ref LL_RCC_FDCAN_CLKSOURCE_PLL
* @arg @ref LL_RCC_FDCAN_CLKSOURCE_PCLK1
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetFDCANClockSource(uint32_t FDCANxSource)
{
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_FDCANSEL, FDCANxSource);
}
#endif /* FDCAN1 */
/**
* @brief Configure RNG clock source
* @rmtoll CCIPR CLK48SEL LL_RCC_SetRNGClockSource
* @param RNGxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_RNG_CLKSOURCE_HSI48
* @arg @ref LL_RCC_RNG_CLKSOURCE_PLL
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetRNGClockSource(uint32_t RNGxSource)
{
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_CLK48SEL, RNGxSource);
}
/**
* @brief Configure USB clock source
* @rmtoll CCIPR CLK48SEL LL_RCC_SetUSBClockSource
* @param USBxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_USB_CLKSOURCE_HSI48
* @arg @ref LL_RCC_USB_CLKSOURCE_PLL
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetUSBClockSource(uint32_t USBxSource)
{
MODIFY_REG(RCC->CCIPR, RCC_CCIPR_CLK48SEL, USBxSource);
}
/**
* @brief Configure ADC clock source
* @rmtoll CCIPR ADC12SEL LL_RCC_SetADCClockSource\n
* CCIPR ADC345SEL LL_RCC_SetADCClockSource
* @param ADCxSource This parameter can be one of the following values:
* @arg @ref LL_RCC_ADC12_CLKSOURCE_NONE
* @arg @ref LL_RCC_ADC12_CLKSOURCE_PLL
* @arg @ref LL_RCC_ADC12_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_ADC345_CLKSOURCE_NONE (*)
* @arg @ref LL_RCC_ADC345_CLKSOURCE_PLL (*)
* @arg @ref LL_RCC_ADC345_CLKSOURCE_SYSCLK (*)
*
* (*) value not defined in all devices.
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetADCClockSource(uint32_t ADCxSource)
{
MODIFY_REG(RCC->CCIPR, 3U << ((ADCxSource & 0x001F0000U) >> 16U), ((ADCxSource & 0x000000FFU) << ((ADCxSource & 0x001F0000U) >> 16U)));
}
#if defined(QUADSPI)
/**
* @brief Configure QUADSPI clock source
* @rmtoll CCIPR2 QSPISEL LL_RCC_SetQUADSPIClockSource
* @param Source This parameter can be one of the following values:
* @arg @ref LL_RCC_QUADSPI_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_QUADSPI_CLKSOURCE_HSI
* @arg @ref LL_RCC_QUADSPI_CLKSOURCE_PLL
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetQUADSPIClockSource(uint32_t Source)
{
MODIFY_REG(RCC->CCIPR2, RCC_CCIPR2_QSPISEL, Source);
}
#endif /* QUADSPI */
/**
* @brief Get USARTx clock source
* @rmtoll CCIPR USARTxSEL LL_RCC_GetUSARTClockSource
* @param USARTx This parameter can be one of the following values:
* @arg @ref LL_RCC_USART1_CLKSOURCE
* @arg @ref LL_RCC_USART2_CLKSOURCE
* @arg @ref LL_RCC_USART3_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_USART1_CLKSOURCE_PCLK2
* @arg @ref LL_RCC_USART1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_USART1_CLKSOURCE_HSI
* @arg @ref LL_RCC_USART1_CLKSOURCE_LSE
* @arg @ref LL_RCC_USART2_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_USART2_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_USART2_CLKSOURCE_HSI
* @arg @ref LL_RCC_USART2_CLKSOURCE_LSE
* @arg @ref LL_RCC_USART3_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_USART3_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_USART3_CLKSOURCE_HSI
* @arg @ref LL_RCC_USART3_CLKSOURCE_LSE
*/
__STATIC_INLINE uint32_t LL_RCC_GetUSARTClockSource(uint32_t USARTx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, USARTx) | (USARTx << 16U));
}
#if defined(UART4)
/**
* @brief Get UARTx clock source
* @rmtoll CCIPR UARTxSEL LL_RCC_GetUARTClockSource
* @param UARTx This parameter can be one of the following values:
* @arg @ref LL_RCC_UART4_CLKSOURCE (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE (*)
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_UART4_CLKSOURCE_PCLK1 (*)
* @arg @ref LL_RCC_UART4_CLKSOURCE_SYSCLK (*)
* @arg @ref LL_RCC_UART4_CLKSOURCE_HSI (*)
* @arg @ref LL_RCC_UART4_CLKSOURCE_LSE (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_PCLK1 (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_SYSCLK (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_HSI (*)
* @arg @ref LL_RCC_UART5_CLKSOURCE_LSE (*)
*
* (*) value not defined in all devices.
*/
__STATIC_INLINE uint32_t LL_RCC_GetUARTClockSource(uint32_t UARTx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, UARTx) | (UARTx << 16U));
}
#endif /* UART4 */
/**
* @brief Get LPUARTx clock source
* @rmtoll CCIPR LPUART1SEL LL_RCC_GetLPUARTClockSource
* @param LPUARTx This parameter can be one of the following values:
* @arg @ref LL_RCC_LPUART1_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_HSI
* @arg @ref LL_RCC_LPUART1_CLKSOURCE_LSE
*/
__STATIC_INLINE uint32_t LL_RCC_GetLPUARTClockSource(uint32_t LPUARTx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, LPUARTx));
}
/**
* @brief Get I2Cx clock source
* @rmtoll CCIPR I2CxSEL LL_RCC_GetI2CClockSource
* @param I2Cx This parameter can be one of the following values:
* @arg @ref LL_RCC_I2C1_CLKSOURCE
* @arg @ref LL_RCC_I2C2_CLKSOURCE
* @arg @ref LL_RCC_I2C3_CLKSOURCE
* @arg @ref LL_RCC_I2C4_CLKSOURCE (*)
*
* (*) value not defined in all devices.
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_I2C1_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_I2C1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2C1_CLKSOURCE_HSI
* @arg @ref LL_RCC_I2C2_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_I2C2_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2C2_CLKSOURCE_HSI
* @arg @ref LL_RCC_I2C3_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_I2C3_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2C3_CLKSOURCE_HSI
* @arg @ref LL_RCC_I2C4_CLKSOURCE_PCLK1 (*)
* @arg @ref LL_RCC_I2C4_CLKSOURCE_SYSCLK (*)
* @arg @ref LL_RCC_I2C4_CLKSOURCE_HSI (*)
*
* (*) value not defined in all devices.
*/
__STATIC_INLINE uint32_t LL_RCC_GetI2CClockSource(uint32_t I2Cx)
{
__IO const uint32_t *reg = (__IO uint32_t *)(uint32_t)(RCC_BASE + 0x88U + (I2Cx >> 24U));
return (uint32_t)((READ_BIT(*reg, 3UL << ((I2Cx & 0x001F0000U) >> 16U)) >> ((I2Cx & 0x001F0000U) >> 16U)) | (I2Cx & 0xFFFF0000U));
}
/**
* @brief Get LPTIMx clock source
* @rmtoll CCIPR LPTIMxSEL LL_RCC_GetLPTIMClockSource
* @param LPTIMx This parameter can be one of the following values:
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_PCLK1
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_LSI
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_HSI
* @arg @ref LL_RCC_LPTIM1_CLKSOURCE_LSE
*/
__STATIC_INLINE uint32_t LL_RCC_GetLPTIMClockSource(uint32_t LPTIMx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, LPTIMx));
}
/**
* @brief Get SAIx clock source
* @rmtoll CCIPR SAI1SEL LL_RCC_GetSAIClockSource
* @param SAIx This parameter can be one of the following values:
* @arg @ref LL_RCC_SAI1_CLKSOURCE
*
* (*) value not defined in all devices.
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_SAI1_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_SAI1_CLKSOURCE_PLL
* @arg @ref LL_RCC_SAI1_CLKSOURCE_PIN
* @arg @ref LL_RCC_SAI1_CLKSOURCE_HSI
*
* (*) value not defined in all devices.
*/
__STATIC_INLINE uint32_t LL_RCC_GetSAIClockSource(uint32_t SAIx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, SAIx));
}
/**
* @brief Get I2Sx clock source
* @rmtoll CCIPR I2S23SEL LL_RCC_GetI2SClockSource
* @param I2Sx This parameter can be one of the following values:
* @arg @ref LL_RCC_I2S_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_I2S_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_I2S_CLKSOURCE_PLL
* @arg @ref LL_RCC_I2S_CLKSOURCE_PIN
* @arg @ref LL_RCC_I2S_CLKSOURCE_HSI
*/
__STATIC_INLINE uint32_t LL_RCC_GetI2SClockSource(uint32_t I2Sx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, I2Sx));
}
#if defined(FDCAN1)
/**
* @brief Get FDCANx clock source
* @rmtoll CCIPR FDCANSEL LL_RCC_GetFDCANClockSource
* @param FDCANx This parameter can be one of the following values:
* @arg @ref LL_RCC_FDCAN_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_FDCAN_CLKSOURCE_HSE
* @arg @ref LL_RCC_FDCAN_CLKSOURCE_PLL
* @arg @ref LL_RCC_FDCAN_CLKSOURCE_PCLK1
* @retval None
*/
__STATIC_INLINE uint32_t LL_RCC_GetFDCANClockSource(uint32_t FDCANx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, FDCANx));
}
#endif /* FDCAN1 */
/**
* @brief Get RNGx clock source
* @rmtoll CCIPR CLK48SEL LL_RCC_GetRNGClockSource
* @param RNGx This parameter can be one of the following values:
* @arg @ref LL_RCC_RNG_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_RNG_CLKSOURCE_HSI48
* @arg @ref LL_RCC_RNG_CLKSOURCE_PLL
*/
__STATIC_INLINE uint32_t LL_RCC_GetRNGClockSource(uint32_t RNGx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, RNGx));
}
/**
* @brief Get USBx clock source
* @rmtoll CCIPR CLK48SEL LL_RCC_GetUSBClockSource
* @param USBx This parameter can be one of the following values:
* @arg @ref LL_RCC_USB_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_USB_CLKSOURCE_HSI48
* @arg @ref LL_RCC_USB_CLKSOURCE_PLL
*/
__STATIC_INLINE uint32_t LL_RCC_GetUSBClockSource(uint32_t USBx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR, USBx));
}
/**
* @brief Get ADCx clock source
* @rmtoll CCIPR ADCSEL LL_RCC_GetADCClockSource
* @param ADCx This parameter can be one of the following values:
* @arg @ref LL_RCC_ADC12_CLKSOURCE
* @arg @ref LL_RCC_ADC345_CLKSOURCE (*)
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_ADC12_CLKSOURCE_NONE
* @arg @ref LL_RCC_ADC12_CLKSOURCE_PLL
* @arg @ref LL_RCC_ADC12_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_ADC345_CLKSOURCE_NONE (*)
* @arg @ref LL_RCC_ADC345_CLKSOURCE_PLL (*)
* @arg @ref LL_RCC_ADC345_CLKSOURCE_SYSCLK (*)
*
* (*) value not defined in all devices.
*/
__STATIC_INLINE uint32_t LL_RCC_GetADCClockSource(uint32_t ADCx)
{
return (uint32_t)((READ_BIT(RCC->CCIPR, 3UL << ((ADCx & 0x001F0000U) >> 16U)) >> ((ADCx & 0x001F0000U) >> 16U)) | (ADCx & 0xFFFF0000U));
}
#if defined(QUADSPI)
/**
* @brief Get QUADSPI clock source
* @rmtoll CCIPR2 QSPISEL LL_RCC_GetQUADSPIClockSource
* @param QUADSPIx This parameter can be one of the following values:
* @arg @ref LL_RCC_QUADSPI_CLKSOURCE
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_QUADSPI_CLKSOURCE_SYSCLK
* @arg @ref LL_RCC_QUADSPI_CLKSOURCE_HSI
* @arg @ref LL_RCC_QUADSPI_CLKSOURCE_PLL
*/
__STATIC_INLINE uint32_t LL_RCC_GetQUADSPIClockSource(uint32_t QUADSPIx)
{
return (uint32_t)(READ_BIT(RCC->CCIPR2, QUADSPIx));
}
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup RCC_LL_EF_RTC RTC
* @{
*/
/**
* @brief Set RTC Clock Source
* @note Once the RTC clock source has been selected, it cannot be changed anymore unless
* the Backup domain is reset, or unless a failure is detected on LSE (LSECSSD is
* set). The BDRST bit can be used to reset them.
* @rmtoll BDCR RTCSEL LL_RCC_SetRTCClockSource
* @param Source This parameter can be one of the following values:
* @arg @ref LL_RCC_RTC_CLKSOURCE_NONE
* @arg @ref LL_RCC_RTC_CLKSOURCE_LSE
* @arg @ref LL_RCC_RTC_CLKSOURCE_LSI
* @arg @ref LL_RCC_RTC_CLKSOURCE_HSE_DIV32
* @retval None
*/
__STATIC_INLINE void LL_RCC_SetRTCClockSource(uint32_t Source)
{
MODIFY_REG(RCC->BDCR, RCC_BDCR_RTCSEL, Source);
}
/**
* @brief Get RTC Clock Source
* @rmtoll BDCR RTCSEL LL_RCC_GetRTCClockSource
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_RTC_CLKSOURCE_NONE
* @arg @ref LL_RCC_RTC_CLKSOURCE_LSE
* @arg @ref LL_RCC_RTC_CLKSOURCE_LSI
* @arg @ref LL_RCC_RTC_CLKSOURCE_HSE_DIV32
*/
__STATIC_INLINE uint32_t LL_RCC_GetRTCClockSource(void)
{
return (uint32_t)(READ_BIT(RCC->BDCR, RCC_BDCR_RTCSEL));
}
/**
* @brief Enable RTC
* @rmtoll BDCR RTCEN LL_RCC_EnableRTC
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableRTC(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_RTCEN);
}
/**
* @brief Disable RTC
* @rmtoll BDCR RTCEN LL_RCC_DisableRTC
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableRTC(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_RTCEN);
}
/**
* @brief Check if RTC has been enabled or not
* @rmtoll BDCR RTCEN LL_RCC_IsEnabledRTC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledRTC(void)
{
return ((READ_BIT(RCC->BDCR, RCC_BDCR_RTCEN) == (RCC_BDCR_RTCEN)) ? 1UL : 0UL);
}
/**
* @brief Force the Backup domain reset
* @rmtoll BDCR BDRST LL_RCC_ForceBackupDomainReset
* @retval None
*/
__STATIC_INLINE void LL_RCC_ForceBackupDomainReset(void)
{
SET_BIT(RCC->BDCR, RCC_BDCR_BDRST);
}
/**
* @brief Release the Backup domain reset
* @rmtoll BDCR BDRST LL_RCC_ReleaseBackupDomainReset
* @retval None
*/
__STATIC_INLINE void LL_RCC_ReleaseBackupDomainReset(void)
{
CLEAR_BIT(RCC->BDCR, RCC_BDCR_BDRST);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_PLL PLL
* @{
*/
/**
* @brief Enable PLL
* @rmtoll CR PLLON LL_RCC_PLL_Enable
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_Enable(void)
{
SET_BIT(RCC->CR, RCC_CR_PLLON);
}
/**
* @brief Disable PLL
* @note Cannot be disabled if the PLL clock is used as the system clock
* @rmtoll CR PLLON LL_RCC_PLL_Disable
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_Disable(void)
{
CLEAR_BIT(RCC->CR, RCC_CR_PLLON);
}
/**
* @brief Check if PLL Ready
* @rmtoll CR PLLRDY LL_RCC_PLL_IsReady
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_IsReady(void)
{
return ((READ_BIT(RCC->CR, RCC_CR_PLLRDY) == (RCC_CR_PLLRDY)) ? 1UL : 0UL);
}
/**
* @brief Configure PLL used for SYSCLK Domain
* @note PLL Source and PLLM Divider can be written only when PLL
* is disabled.
* @note PLLN/PLLR can be written only when PLL is disabled.
* @rmtoll PLLCFGR PLLSRC LL_RCC_PLL_ConfigDomain_SYS\n
* PLLCFGR PLLM LL_RCC_PLL_ConfigDomain_SYS\n
* PLLCFGR PLLN LL_RCC_PLL_ConfigDomain_SYS\n
* PLLCFGR PLLR LL_RCC_PLL_ConfigDomain_SYS
* @param Source This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLSOURCE_NONE
* @arg @ref LL_RCC_PLLSOURCE_HSI
* @arg @ref LL_RCC_PLLSOURCE_HSE
* @param PLLM This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLM_DIV_1
* @arg @ref LL_RCC_PLLM_DIV_2
* @arg @ref LL_RCC_PLLM_DIV_3
* @arg @ref LL_RCC_PLLM_DIV_4
* @arg @ref LL_RCC_PLLM_DIV_5
* @arg @ref LL_RCC_PLLM_DIV_6
* @arg @ref LL_RCC_PLLM_DIV_7
* @arg @ref LL_RCC_PLLM_DIV_8
* @arg @ref LL_RCC_PLLM_DIV_9
* @arg @ref LL_RCC_PLLM_DIV_10
* @arg @ref LL_RCC_PLLM_DIV_11
* @arg @ref LL_RCC_PLLM_DIV_12
* @arg @ref LL_RCC_PLLM_DIV_13
* @arg @ref LL_RCC_PLLM_DIV_14
* @arg @ref LL_RCC_PLLM_DIV_15
* @arg @ref LL_RCC_PLLM_DIV_16
* @param PLLN Between Min_Data = 8 and Max_Data = 127
* @param PLLR This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLR_DIV_2
* @arg @ref LL_RCC_PLLR_DIV_4
* @arg @ref LL_RCC_PLLR_DIV_6
* @arg @ref LL_RCC_PLLR_DIV_8
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_ConfigDomain_SYS(uint32_t Source, uint32_t PLLM, uint32_t PLLN, uint32_t PLLR)
{
MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC | RCC_PLLCFGR_PLLM | RCC_PLLCFGR_PLLN | RCC_PLLCFGR_PLLR,
Source | PLLM | (PLLN << RCC_PLLCFGR_PLLN_Pos) | PLLR);
}
/**
* @brief Configure PLL used for ADC domain clock
* @note PLL Source and PLLM Divider can be written only when PLL
* is disabled.
* @note PLLN/PLLP can be written only when PLL is disabled.
* @rmtoll PLLCFGR PLLSRC LL_RCC_PLL_ConfigDomain_ADC\n
* PLLCFGR PLLM LL_RCC_PLL_ConfigDomain_ADC\n
* PLLCFGR PLLN LL_RCC_PLL_ConfigDomain_ADC\n
* PLLCFGR PLLPDIV LL_RCC_PLL_ConfigDomain_ADC
* @param Source This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLSOURCE_NONE
* @arg @ref LL_RCC_PLLSOURCE_HSI
* @arg @ref LL_RCC_PLLSOURCE_HSE
* @param PLLM This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLM_DIV_1
* @arg @ref LL_RCC_PLLM_DIV_2
* @arg @ref LL_RCC_PLLM_DIV_3
* @arg @ref LL_RCC_PLLM_DIV_4
* @arg @ref LL_RCC_PLLM_DIV_5
* @arg @ref LL_RCC_PLLM_DIV_6
* @arg @ref LL_RCC_PLLM_DIV_7
* @arg @ref LL_RCC_PLLM_DIV_8
* @arg @ref LL_RCC_PLLM_DIV_9
* @arg @ref LL_RCC_PLLM_DIV_10
* @arg @ref LL_RCC_PLLM_DIV_11
* @arg @ref LL_RCC_PLLM_DIV_12
* @arg @ref LL_RCC_PLLM_DIV_13
* @arg @ref LL_RCC_PLLM_DIV_14
* @arg @ref LL_RCC_PLLM_DIV_15
* @arg @ref LL_RCC_PLLM_DIV_16
* @param PLLN Between Min_Data = 8 and Max_Data = 127
* @param PLLP This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLP_DIV_2
* @arg @ref LL_RCC_PLLP_DIV_3
* @arg @ref LL_RCC_PLLP_DIV_4
* @arg @ref LL_RCC_PLLP_DIV_5
* @arg @ref LL_RCC_PLLP_DIV_6
* @arg @ref LL_RCC_PLLP_DIV_7
* @arg @ref LL_RCC_PLLP_DIV_8
* @arg @ref LL_RCC_PLLP_DIV_9
* @arg @ref LL_RCC_PLLP_DIV_10
* @arg @ref LL_RCC_PLLP_DIV_11
* @arg @ref LL_RCC_PLLP_DIV_12
* @arg @ref LL_RCC_PLLP_DIV_13
* @arg @ref LL_RCC_PLLP_DIV_14
* @arg @ref LL_RCC_PLLP_DIV_15
* @arg @ref LL_RCC_PLLP_DIV_16
* @arg @ref LL_RCC_PLLP_DIV_17
* @arg @ref LL_RCC_PLLP_DIV_18
* @arg @ref LL_RCC_PLLP_DIV_19
* @arg @ref LL_RCC_PLLP_DIV_20
* @arg @ref LL_RCC_PLLP_DIV_21
* @arg @ref LL_RCC_PLLP_DIV_22
* @arg @ref LL_RCC_PLLP_DIV_23
* @arg @ref LL_RCC_PLLP_DIV_24
* @arg @ref LL_RCC_PLLP_DIV_25
* @arg @ref LL_RCC_PLLP_DIV_26
* @arg @ref LL_RCC_PLLP_DIV_27
* @arg @ref LL_RCC_PLLP_DIV_28
* @arg @ref LL_RCC_PLLP_DIV_29
* @arg @ref LL_RCC_PLLP_DIV_30
* @arg @ref LL_RCC_PLLP_DIV_31
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_ConfigDomain_ADC(uint32_t Source, uint32_t PLLM, uint32_t PLLN, uint32_t PLLP)
{
MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC | RCC_PLLCFGR_PLLM | RCC_PLLCFGR_PLLN | RCC_PLLCFGR_PLLPDIV,
Source | PLLM | (PLLN << RCC_PLLCFGR_PLLN_Pos) | PLLP);
}
/**
* @brief Configure PLL used for 48Mhz domain clock
* @note PLL Source and PLLM Divider can be written only when PLL,
* is disabled.
* @note PLLN/PLLQ can be written only when PLL is disabled.
* @note This can be selected for USB, RNG
* @rmtoll PLLCFGR PLLSRC LL_RCC_PLL_ConfigDomain_48M\n
* PLLCFGR PLLM LL_RCC_PLL_ConfigDomain_48M\n
* PLLCFGR PLLN LL_RCC_PLL_ConfigDomain_48M\n
* PLLCFGR PLLQ LL_RCC_PLL_ConfigDomain_48M
* @param Source This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLSOURCE_NONE
* @arg @ref LL_RCC_PLLSOURCE_HSI
* @arg @ref LL_RCC_PLLSOURCE_HSE
* @param PLLM This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLM_DIV_1
* @arg @ref LL_RCC_PLLM_DIV_2
* @arg @ref LL_RCC_PLLM_DIV_3
* @arg @ref LL_RCC_PLLM_DIV_4
* @arg @ref LL_RCC_PLLM_DIV_5
* @arg @ref LL_RCC_PLLM_DIV_6
* @arg @ref LL_RCC_PLLM_DIV_7
* @arg @ref LL_RCC_PLLM_DIV_8
* @arg @ref LL_RCC_PLLM_DIV_9
* @arg @ref LL_RCC_PLLM_DIV_10
* @arg @ref LL_RCC_PLLM_DIV_11
* @arg @ref LL_RCC_PLLM_DIV_12
* @arg @ref LL_RCC_PLLM_DIV_13
* @arg @ref LL_RCC_PLLM_DIV_14
* @arg @ref LL_RCC_PLLM_DIV_15
* @arg @ref LL_RCC_PLLM_DIV_16
* @param PLLN Between Min_Data = 8 and Max_Data = 127
* @param PLLQ This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLQ_DIV_2
* @arg @ref LL_RCC_PLLQ_DIV_4
* @arg @ref LL_RCC_PLLQ_DIV_6
* @arg @ref LL_RCC_PLLQ_DIV_8
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_ConfigDomain_48M(uint32_t Source, uint32_t PLLM, uint32_t PLLN, uint32_t PLLQ)
{
MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC | RCC_PLLCFGR_PLLM | RCC_PLLCFGR_PLLN | RCC_PLLCFGR_PLLQ,
Source | PLLM | (PLLN << RCC_PLLCFGR_PLLN_Pos) | PLLQ);
}
/**
* @brief Configure PLL clock source
* @rmtoll PLLCFGR PLLSRC LL_RCC_PLL_SetMainSource
* @param PLLSource This parameter can be one of the following values:
* @arg @ref LL_RCC_PLLSOURCE_NONE
* @arg @ref LL_RCC_PLLSOURCE_HSI
* @arg @ref LL_RCC_PLLSOURCE_HSE
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_SetMainSource(uint32_t PLLSource)
{
MODIFY_REG(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC, PLLSource);
}
/**
* @brief Get the oscillator used as PLL clock source.
* @rmtoll PLLCFGR PLLSRC LL_RCC_PLL_GetMainSource
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_PLLSOURCE_NONE
* @arg @ref LL_RCC_PLLSOURCE_HSI
* @arg @ref LL_RCC_PLLSOURCE_HSE
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_GetMainSource(void)
{
return (uint32_t)(READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLSRC));
}
/**
* @brief Get Main PLL multiplication factor for VCO
* @rmtoll PLLCFGR PLLN LL_RCC_PLL_GetN
* @retval Between Min_Data = 8 and Max_Data = 127
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_GetN(void)
{
return (uint32_t)(READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLN) >> RCC_PLLCFGR_PLLN_Pos);
}
/**
* @brief Get Main PLL division factor for PLLP
* @note Used for PLLADCCLK (ADC clock)
* @rmtoll PLLCFGR PLLPDIV LL_RCC_PLL_GetP\n
* @rmtoll PLLCFGR PLLP LL_RCC_PLL_GetP
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_PLLP_DIV_2
* @arg @ref LL_RCC_PLLP_DIV_3
* @arg @ref LL_RCC_PLLP_DIV_4
* @arg @ref LL_RCC_PLLP_DIV_5
* @arg @ref LL_RCC_PLLP_DIV_6
* @arg @ref LL_RCC_PLLP_DIV_7
* @arg @ref LL_RCC_PLLP_DIV_8
* @arg @ref LL_RCC_PLLP_DIV_9
* @arg @ref LL_RCC_PLLP_DIV_10
* @arg @ref LL_RCC_PLLP_DIV_11
* @arg @ref LL_RCC_PLLP_DIV_12
* @arg @ref LL_RCC_PLLP_DIV_13
* @arg @ref LL_RCC_PLLP_DIV_14
* @arg @ref LL_RCC_PLLP_DIV_15
* @arg @ref LL_RCC_PLLP_DIV_16
* @arg @ref LL_RCC_PLLP_DIV_17
* @arg @ref LL_RCC_PLLP_DIV_18
* @arg @ref LL_RCC_PLLP_DIV_19
* @arg @ref LL_RCC_PLLP_DIV_20
* @arg @ref LL_RCC_PLLP_DIV_21
* @arg @ref LL_RCC_PLLP_DIV_22
* @arg @ref LL_RCC_PLLP_DIV_23
* @arg @ref LL_RCC_PLLP_DIV_24
* @arg @ref LL_RCC_PLLP_DIV_25
* @arg @ref LL_RCC_PLLP_DIV_26
* @arg @ref LL_RCC_PLLP_DIV_27
* @arg @ref LL_RCC_PLLP_DIV_28
* @arg @ref LL_RCC_PLLP_DIV_29
* @arg @ref LL_RCC_PLLP_DIV_30
* @arg @ref LL_RCC_PLLP_DIV_31
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_GetP(void)
{
return (uint32_t) ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPDIV) != 0U) ? READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPDIV) : ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLP) == RCC_PLLCFGR_PLLP) ? LL_RCC_PLLP_DIV_17 : LL_RCC_PLLP_DIV_7) );
}
/**
* @brief Get Main PLL division factor for PLLQ
* @note Used for PLL48M1CLK selected for USB, RNG (48 MHz clock)
* @rmtoll PLLCFGR PLLQ LL_RCC_PLL_GetQ
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_PLLQ_DIV_2
* @arg @ref LL_RCC_PLLQ_DIV_4
* @arg @ref LL_RCC_PLLQ_DIV_6
* @arg @ref LL_RCC_PLLQ_DIV_8
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_GetQ(void)
{
return (uint32_t)(READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQ));
}
/**
* @brief Get Main PLL division factor for PLLR
* @note Used for PLLCLK (system clock)
* @rmtoll PLLCFGR PLLR LL_RCC_PLL_GetR
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_PLLR_DIV_2
* @arg @ref LL_RCC_PLLR_DIV_4
* @arg @ref LL_RCC_PLLR_DIV_6
* @arg @ref LL_RCC_PLLR_DIV_8
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_GetR(void)
{
return (uint32_t)(READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLR));
}
/**
* @brief Get Division factor for the main PLL and other PLL
* @rmtoll PLLCFGR PLLM LL_RCC_PLL_GetDivider
* @retval Returned value can be one of the following values:
* @arg @ref LL_RCC_PLLM_DIV_1
* @arg @ref LL_RCC_PLLM_DIV_2
* @arg @ref LL_RCC_PLLM_DIV_3
* @arg @ref LL_RCC_PLLM_DIV_4
* @arg @ref LL_RCC_PLLM_DIV_5
* @arg @ref LL_RCC_PLLM_DIV_6
* @arg @ref LL_RCC_PLLM_DIV_7
* @arg @ref LL_RCC_PLLM_DIV_8
* @arg @ref LL_RCC_PLLM_DIV_9
* @arg @ref LL_RCC_PLLM_DIV_10
* @arg @ref LL_RCC_PLLM_DIV_11
* @arg @ref LL_RCC_PLLM_DIV_12
* @arg @ref LL_RCC_PLLM_DIV_13
* @arg @ref LL_RCC_PLLM_DIV_14
* @arg @ref LL_RCC_PLLM_DIV_15
* @arg @ref LL_RCC_PLLM_DIV_16
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_GetDivider(void)
{
return (uint32_t)(READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLM));
}
/**
* @brief Enable PLL output mapped on ADC domain clock
* @rmtoll PLLCFGR PLLPEN LL_RCC_PLL_EnableDomain_ADC
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_EnableDomain_ADC(void)
{
SET_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPEN);
}
/**
* @brief Disable PLL output mapped on ADC domain clock
* @note Cannot be disabled if the PLL clock is used as the system
* clock
* @note In order to save power, when the PLLCLK of the PLL is
* not used, should be 0
* @rmtoll PLLCFGR PLLPEN LL_RCC_PLL_DisableDomain_ADC
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_DisableDomain_ADC(void)
{
CLEAR_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPEN);
}
/**
* @brief Check if PLL output mapped on ADC domain clock is enabled
* @rmtoll PLLCFGR PLLPEN LL_RCC_PLL_IsEnabledDomain_ADC
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_IsEnabledDomain_ADC(void)
{
return ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLPEN) == (RCC_PLLCFGR_PLLPEN)) ? 1UL : 0UL);
}
/**
* @brief Enable PLL output mapped on 48MHz domain clock
* @rmtoll PLLCFGR PLLQEN LL_RCC_PLL_EnableDomain_48M
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_EnableDomain_48M(void)
{
SET_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQEN);
}
/**
* @brief Disable PLL output mapped on 48MHz domain clock
* @note Cannot be disabled if the PLL clock is used as the system
* clock
* @note In order to save power, when the PLLCLK of the PLL is
* not used, should be 0
* @rmtoll PLLCFGR PLLQEN LL_RCC_PLL_DisableDomain_48M
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_DisableDomain_48M(void)
{
CLEAR_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQEN);
}
/**
* @brief Check if PLL output mapped on 48MHz domain clock is enabled
* @rmtoll PLLCFGR PLLQEN LL_RCC_PLL_IsEnabledDomain_48M
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_IsEnabledDomain_48M(void)
{
return ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLQEN) == (RCC_PLLCFGR_PLLQEN)) ? 1UL : 0UL);
}
/**
* @brief Enable PLL output mapped on SYSCLK domain
* @rmtoll PLLCFGR PLLREN LL_RCC_PLL_EnableDomain_SYS
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_EnableDomain_SYS(void)
{
SET_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLREN);
}
/**
* @brief Disable PLL output mapped on SYSCLK domain
* @note Cannot be disabled if the PLL clock is used as the system
* clock
* @note In order to save power, when the PLLCLK of the PLL is
* not used, Main PLL should be 0
* @rmtoll PLLCFGR PLLREN LL_RCC_PLL_DisableDomain_SYS
* @retval None
*/
__STATIC_INLINE void LL_RCC_PLL_DisableDomain_SYS(void)
{
CLEAR_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLREN);
}
/**
* @brief Check if PLL output mapped on SYSCLK domain clock is enabled
* @rmtoll PLLCFGR PLLREN LL_RCC_PLL_IsEnabledDomain_SYS
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_PLL_IsEnabledDomain_SYS(void)
{
return ((READ_BIT(RCC->PLLCFGR, RCC_PLLCFGR_PLLREN) == (RCC_PLLCFGR_PLLREN)) ? 1UL : 0UL);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_FLAG_Management FLAG Management
* @{
*/
/**
* @brief Clear LSI ready interrupt flag
* @rmtoll CICR LSIRDYC LL_RCC_ClearFlag_LSIRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_LSIRDY(void)
{
SET_BIT(RCC->CICR, RCC_CICR_LSIRDYC);
}
/**
* @brief Clear LSE ready interrupt flag
* @rmtoll CICR LSERDYC LL_RCC_ClearFlag_LSERDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_LSERDY(void)
{
SET_BIT(RCC->CICR, RCC_CICR_LSERDYC);
}
/**
* @brief Clear HSI ready interrupt flag
* @rmtoll CICR HSIRDYC LL_RCC_ClearFlag_HSIRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_HSIRDY(void)
{
SET_BIT(RCC->CICR, RCC_CICR_HSIRDYC);
}
/**
* @brief Clear HSE ready interrupt flag
* @rmtoll CICR HSERDYC LL_RCC_ClearFlag_HSERDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_HSERDY(void)
{
SET_BIT(RCC->CICR, RCC_CICR_HSERDYC);
}
/**
* @brief Clear PLL ready interrupt flag
* @rmtoll CICR PLLRDYC LL_RCC_ClearFlag_PLLRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_PLLRDY(void)
{
SET_BIT(RCC->CICR, RCC_CICR_PLLRDYC);
}
/**
* @brief Clear HSI48 ready interrupt flag
* @rmtoll CICR HSI48RDYC LL_RCC_ClearFlag_HSI48RDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_HSI48RDY(void)
{
SET_BIT(RCC->CICR, RCC_CICR_HSI48RDYC);
}
/**
* @brief Clear Clock security system interrupt flag
* @rmtoll CICR CSSC LL_RCC_ClearFlag_HSECSS
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_HSECSS(void)
{
SET_BIT(RCC->CICR, RCC_CICR_CSSC);
}
/**
* @brief Clear LSE Clock security system interrupt flag
* @rmtoll CICR LSECSSC LL_RCC_ClearFlag_LSECSS
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearFlag_LSECSS(void)
{
SET_BIT(RCC->CICR, RCC_CICR_LSECSSC);
}
/**
* @brief Check if LSI ready interrupt occurred or not
* @rmtoll CIFR LSIRDYF LL_RCC_IsActiveFlag_LSIRDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_LSIRDY(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_LSIRDYF) == (RCC_CIFR_LSIRDYF)) ? 1UL : 0UL);
}
/**
* @brief Check if LSE ready interrupt occurred or not
* @rmtoll CIFR LSERDYF LL_RCC_IsActiveFlag_LSERDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_LSERDY(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_LSERDYF) == (RCC_CIFR_LSERDYF)) ? 1UL : 0UL);
}
/**
* @brief Check if HSI ready interrupt occurred or not
* @rmtoll CIFR HSIRDYF LL_RCC_IsActiveFlag_HSIRDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_HSIRDY(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_HSIRDYF) == (RCC_CIFR_HSIRDYF)) ? 1UL : 0UL);
}
/**
* @brief Check if HSE ready interrupt occurred or not
* @rmtoll CIFR HSERDYF LL_RCC_IsActiveFlag_HSERDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_HSERDY(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_HSERDYF) == (RCC_CIFR_HSERDYF)) ? 1UL : 0UL);
}
/**
* @brief Check if PLL ready interrupt occurred or not
* @rmtoll CIFR PLLRDYF LL_RCC_IsActiveFlag_PLLRDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_PLLRDY(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_PLLRDYF) == (RCC_CIFR_PLLRDYF)) ? 1UL : 0UL);
}
/**
* @brief Check if HSI48 ready interrupt occurred or not
* @rmtoll CIR HSI48RDYF LL_RCC_IsActiveFlag_HSI48RDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_HSI48RDY(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_HSI48RDYF) == (RCC_CIFR_HSI48RDYF)) ? 1UL : 0UL);
}
/**
* @brief Check if Clock security system interrupt occurred or not
* @rmtoll CIFR CSSF LL_RCC_IsActiveFlag_HSECSS
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_HSECSS(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_CSSF) == (RCC_CIFR_CSSF)) ? 1UL : 0UL);
}
/**
* @brief Check if LSE Clock security system interrupt occurred or not
* @rmtoll CIFR LSECSSF LL_RCC_IsActiveFlag_LSECSS
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_LSECSS(void)
{
return ((READ_BIT(RCC->CIFR, RCC_CIFR_LSECSSF) == (RCC_CIFR_LSECSSF)) ? 1UL : 0UL);
}
/**
* @brief Check if RCC flag Independent Watchdog reset is set or not.
* @rmtoll CSR IWDGRSTF LL_RCC_IsActiveFlag_IWDGRST
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_IWDGRST(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_IWDGRSTF) == (RCC_CSR_IWDGRSTF)) ? 1UL : 0UL);
}
/**
* @brief Check if RCC flag Low Power reset is set or not.
* @rmtoll CSR LPWRRSTF LL_RCC_IsActiveFlag_LPWRRST
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_LPWRRST(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_LPWRRSTF) == (RCC_CSR_LPWRRSTF)) ? 1UL : 0UL);
}
/**
* @brief Check if RCC flag Option byte reset is set or not.
* @rmtoll CSR OBLRSTF LL_RCC_IsActiveFlag_OBLRST
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_OBLRST(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_OBLRSTF) == (RCC_CSR_OBLRSTF)) ? 1UL : 0UL);
}
/**
* @brief Check if RCC flag Pin reset is set or not.
* @rmtoll CSR PINRSTF LL_RCC_IsActiveFlag_PINRST
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_PINRST(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_PINRSTF) == (RCC_CSR_PINRSTF)) ? 1UL : 0UL);
}
/**
* @brief Check if RCC flag Software reset is set or not.
* @rmtoll CSR SFTRSTF LL_RCC_IsActiveFlag_SFTRST
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_SFTRST(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_SFTRSTF) == (RCC_CSR_SFTRSTF)) ? 1UL : 0UL);
}
/**
* @brief Check if RCC flag Window Watchdog reset is set or not.
* @rmtoll CSR WWDGRSTF LL_RCC_IsActiveFlag_WWDGRST
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_WWDGRST(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_WWDGRSTF) == (RCC_CSR_WWDGRSTF)) ? 1UL : 0UL);
}
/**
* @brief Check if RCC flag BOR reset is set or not.
* @rmtoll CSR BORRSTF LL_RCC_IsActiveFlag_BORRST
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsActiveFlag_BORRST(void)
{
return ((READ_BIT(RCC->CSR, RCC_CSR_BORRSTF) == (RCC_CSR_BORRSTF)) ? 1UL : 0UL);
}
/**
* @brief Set RMVF bit to clear the reset flags.
* @rmtoll CSR RMVF LL_RCC_ClearResetFlags
* @retval None
*/
__STATIC_INLINE void LL_RCC_ClearResetFlags(void)
{
SET_BIT(RCC->CSR, RCC_CSR_RMVF);
}
/**
* @}
*/
/** @defgroup RCC_LL_EF_IT_Management IT Management
* @{
*/
/**
* @brief Enable LSI ready interrupt
* @rmtoll CIER LSIRDYIE LL_RCC_EnableIT_LSIRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableIT_LSIRDY(void)
{
SET_BIT(RCC->CIER, RCC_CIER_LSIRDYIE);
}
/**
* @brief Enable LSE ready interrupt
* @rmtoll CIER LSERDYIE LL_RCC_EnableIT_LSERDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableIT_LSERDY(void)
{
SET_BIT(RCC->CIER, RCC_CIER_LSERDYIE);
}
/**
* @brief Enable HSI ready interrupt
* @rmtoll CIER HSIRDYIE LL_RCC_EnableIT_HSIRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableIT_HSIRDY(void)
{
SET_BIT(RCC->CIER, RCC_CIER_HSIRDYIE);
}
/**
* @brief Enable HSE ready interrupt
* @rmtoll CIER HSERDYIE LL_RCC_EnableIT_HSERDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableIT_HSERDY(void)
{
SET_BIT(RCC->CIER, RCC_CIER_HSERDYIE);
}
/**
* @brief Enable PLL ready interrupt
* @rmtoll CIER PLLRDYIE LL_RCC_EnableIT_PLLRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableIT_PLLRDY(void)
{
SET_BIT(RCC->CIER, RCC_CIER_PLLRDYIE);
}
/**
* @brief Enable HSI48 ready interrupt
* @rmtoll CIER HSI48RDYIE LL_RCC_EnableIT_HSI48RDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableIT_HSI48RDY(void)
{
SET_BIT(RCC->CIER, RCC_CIER_HSI48RDYIE);
}
/**
* @brief Enable LSE clock security system interrupt
* @rmtoll CIER LSECSSIE LL_RCC_EnableIT_LSECSS
* @retval None
*/
__STATIC_INLINE void LL_RCC_EnableIT_LSECSS(void)
{
SET_BIT(RCC->CIER, RCC_CIER_LSECSSIE);
}
/**
* @brief Disable LSI ready interrupt
* @rmtoll CIER LSIRDYIE LL_RCC_DisableIT_LSIRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableIT_LSIRDY(void)
{
CLEAR_BIT(RCC->CIER, RCC_CIER_LSIRDYIE);
}
/**
* @brief Disable LSE ready interrupt
* @rmtoll CIER LSERDYIE LL_RCC_DisableIT_LSERDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableIT_LSERDY(void)
{
CLEAR_BIT(RCC->CIER, RCC_CIER_LSERDYIE);
}
/**
* @brief Disable HSI ready interrupt
* @rmtoll CIER HSIRDYIE LL_RCC_DisableIT_HSIRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableIT_HSIRDY(void)
{
CLEAR_BIT(RCC->CIER, RCC_CIER_HSIRDYIE);
}
/**
* @brief Disable HSE ready interrupt
* @rmtoll CIER HSERDYIE LL_RCC_DisableIT_HSERDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableIT_HSERDY(void)
{
CLEAR_BIT(RCC->CIER, RCC_CIER_HSERDYIE);
}
/**
* @brief Disable PLL ready interrupt
* @rmtoll CIER PLLRDYIE LL_RCC_DisableIT_PLLRDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableIT_PLLRDY(void)
{
CLEAR_BIT(RCC->CIER, RCC_CIER_PLLRDYIE);
}
/**
* @brief Disable HSI48 ready interrupt
* @rmtoll CIER HSI48RDYIE LL_RCC_DisableIT_HSI48RDY
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableIT_HSI48RDY(void)
{
CLEAR_BIT(RCC->CIER, RCC_CIER_HSI48RDYIE);
}
/**
* @brief Disable LSE clock security system interrupt
* @rmtoll CIER LSECSSIE LL_RCC_DisableIT_LSECSS
* @retval None
*/
__STATIC_INLINE void LL_RCC_DisableIT_LSECSS(void)
{
CLEAR_BIT(RCC->CIER, RCC_CIER_LSECSSIE);
}
/**
* @brief Checks if LSI ready interrupt source is enabled or disabled.
* @rmtoll CIER LSIRDYIE LL_RCC_IsEnabledIT_LSIRDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledIT_LSIRDY(void)
{
return ((READ_BIT(RCC->CIER, RCC_CIER_LSIRDYIE) == (RCC_CIER_LSIRDYIE)) ? 1UL : 0UL);
}
/**
* @brief Checks if LSE ready interrupt source is enabled or disabled.
* @rmtoll CIER LSERDYIE LL_RCC_IsEnabledIT_LSERDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledIT_LSERDY(void)
{
return ((READ_BIT(RCC->CIER, RCC_CIER_LSERDYIE) == (RCC_CIER_LSERDYIE)) ? 1UL : 0UL);
}
/**
* @brief Checks if HSI ready interrupt source is enabled or disabled.
* @rmtoll CIER HSIRDYIE LL_RCC_IsEnabledIT_HSIRDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledIT_HSIRDY(void)
{
return ((READ_BIT(RCC->CIER, RCC_CIER_HSIRDYIE) == (RCC_CIER_HSIRDYIE)) ? 1UL : 0UL);
}
/**
* @brief Checks if HSE ready interrupt source is enabled or disabled.
* @rmtoll CIER HSERDYIE LL_RCC_IsEnabledIT_HSERDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledIT_HSERDY(void)
{
return ((READ_BIT(RCC->CIER, RCC_CIER_HSERDYIE) == (RCC_CIER_HSERDYIE)) ? 1UL : 0UL);
}
/**
* @brief Checks if PLL ready interrupt source is enabled or disabled.
* @rmtoll CIER PLLRDYIE LL_RCC_IsEnabledIT_PLLRDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledIT_PLLRDY(void)
{
return ((READ_BIT(RCC->CIER, RCC_CIER_PLLRDYIE) == (RCC_CIER_PLLRDYIE)) ? 1UL : 0UL);
}
/**
* @brief Checks if HSI48 ready interrupt source is enabled or disabled.
* @rmtoll CIER HSI48RDYIE LL_RCC_IsEnabledIT_HSI48RDY
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledIT_HSI48RDY(void)
{
return ((READ_BIT(RCC->CIER, RCC_CIER_HSI48RDYIE) == (RCC_CIER_HSI48RDYIE)) ? 1UL : 0UL);
}
/**
* @brief Checks if LSECSS interrupt source is enabled or disabled.
* @rmtoll CIER LSECSSIE LL_RCC_IsEnabledIT_LSECSS
* @retval State of bit (1 or 0).
*/
__STATIC_INLINE uint32_t LL_RCC_IsEnabledIT_LSECSS(void)
{
return ((READ_BIT(RCC->CIER, RCC_CIER_LSECSSIE) == (RCC_CIER_LSECSSIE)) ? 1UL : 0UL);
}
/**
* @}
*/
#if defined(USE_FULL_LL_DRIVER)
/** @defgroup RCC_LL_EF_Init De-initialization function
* @{
*/
ErrorStatus LL_RCC_DeInit(void);
/**
* @}
*/
/** @defgroup RCC_LL_EF_Get_Freq Get system and peripherals clocks frequency functions
* @{
*/
void LL_RCC_GetSystemClocksFreq(LL_RCC_ClocksTypeDef *RCC_Clocks);
uint32_t LL_RCC_GetUSARTClockFreq(uint32_t USARTxSource);
#if defined(UART4)
uint32_t LL_RCC_GetUARTClockFreq(uint32_t UARTxSource);
#endif /* UART4 */
uint32_t LL_RCC_GetI2CClockFreq(uint32_t I2CxSource);
uint32_t LL_RCC_GetLPUARTClockFreq(uint32_t LPUARTxSource);
uint32_t LL_RCC_GetLPTIMClockFreq(uint32_t LPTIMxSource);
uint32_t LL_RCC_GetSAIClockFreq(uint32_t SAIxSource);
uint32_t LL_RCC_GetI2SClockFreq(uint32_t I2SxSource);
#if defined(FDCAN1)
uint32_t LL_RCC_GetFDCANClockFreq(uint32_t FDCANxSource);
#endif /* FDCAN1 */
uint32_t LL_RCC_GetRNGClockFreq(uint32_t RNGxSource);
uint32_t LL_RCC_GetUSBClockFreq(uint32_t USBxSource);
uint32_t LL_RCC_GetADCClockFreq(uint32_t ADCxSource);
#if defined(QUADSPI)
uint32_t LL_RCC_GetQUADSPIClockFreq(uint32_t QUADSPIxSource);
#endif /* QUADSPI */
/**
* @}
*/
#endif /* USE_FULL_LL_DRIVER */
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_LL_RCC_H */
| 113,243 | C | 36.760587 | 229 | 0.599534 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal.h | /**
******************************************************************************
* @file stm32g4xx_hal.h
* @author MCD Application Team
* @brief This file contains all the functions prototypes for the HAL
* module driver.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_H
#define STM32G4xx_HAL_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_conf.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup HAL HAL
* @{
*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup HAL_Exported_Constants HAL Exported Constants
* @{
*/
/** @defgroup HAL_TICK_FREQ Tick Frequency
* @{
*/
#define HAL_TICK_FREQ_10HZ 100U
#define HAL_TICK_FREQ_100HZ 10U
#define HAL_TICK_FREQ_1KHZ 1U
#define HAL_TICK_FREQ_DEFAULT HAL_TICK_FREQ_1KHZ
/**
* @}
*/
/** @defgroup SYSCFG_Exported_Constants SYSCFG Exported Constants
* @{
*/
/** @defgroup SYSCFG_BootMode Boot Mode
* @{
*/
#define SYSCFG_BOOT_MAINFLASH 0x00000000U
#define SYSCFG_BOOT_SYSTEMFLASH SYSCFG_MEMMEMRMP_MODE_0
#if defined (FMC_BANK1)
#define SYSCFG_BOOT_FMC SYSCFG_MEMMEMRMP_MODE_1
#endif /* FMC_BANK1 */
#define SYSCFG_BOOT_SRAM (SYSCFG_MEMMEMRMP_MODE_1 | SYSCFG_MEMMEMRMP_MODE_0)
#if defined (QUADSPI)
#define SYSCFG_BOOT_QUADSPI (SYSCFG_MEMMEMRMP_MODE_2 | SYSCFG_MEMMEMRMP_MODE_1)
#endif /* QUADSPI */
/**
* @}
*/
/** @defgroup SYSCFG_FPU_Interrupts FPU Interrupts
* @{
*/
#define SYSCFG_IT_FPU_IOC SYSCFG_CFGR1_FPU_IE_0 /*!< Floating Point Unit Invalid operation Interrupt */
#define SYSCFG_IT_FPU_DZC SYSCFG_CFGR1_FPU_IE_1 /*!< Floating Point Unit Divide-by-zero Interrupt */
#define SYSCFG_IT_FPU_UFC SYSCFG_CFGR1_FPU_IE_2 /*!< Floating Point Unit Underflow Interrupt */
#define SYSCFG_IT_FPU_OFC SYSCFG_CFGR1_FPU_IE_3 /*!< Floating Point Unit Overflow Interrupt */
#define SYSCFG_IT_FPU_IDC SYSCFG_CFGR1_FPU_IE_4 /*!< Floating Point Unit Input denormal Interrupt */
#define SYSCFG_IT_FPU_IXC SYSCFG_CFGR1_FPU_IE_5 /*!< Floating Point Unit Inexact Interrupt */
/**
* @}
*/
/** @defgroup SYSCFG_CCMSRAMWRP CCM Write protection
* @{
*/
#define SYSCFG_CCMSRAMWRP_PAGE0 SYSCFG_SWPR_PAGE0 /*!< CCMSRAM Write protection page 0 */
#define SYSCFG_CCMSRAMWRP_PAGE1 SYSCFG_SWPR_PAGE1 /*!< CCMSRAM Write protection page 1 */
#define SYSCFG_CCMSRAMWRP_PAGE2 SYSCFG_SWPR_PAGE2 /*!< CCMSRAM Write protection page 2 */
#define SYSCFG_CCMSRAMWRP_PAGE3 SYSCFG_SWPR_PAGE3 /*!< CCMSRAM Write protection page 3 */
#define SYSCFG_CCMSRAMWRP_PAGE4 SYSCFG_SWPR_PAGE4 /*!< CCMSRAM Write protection page 4 */
#define SYSCFG_CCMSRAMWRP_PAGE5 SYSCFG_SWPR_PAGE5 /*!< CCMSRAM Write protection page 5 */
#define SYSCFG_CCMSRAMWRP_PAGE6 SYSCFG_SWPR_PAGE6 /*!< CCMSRAM Write protection page 6 */
#define SYSCFG_CCMSRAMWRP_PAGE7 SYSCFG_SWPR_PAGE7 /*!< CCMSRAM Write protection page 7 */
#define SYSCFG_CCMSRAMWRP_PAGE8 SYSCFG_SWPR_PAGE8 /*!< CCMSRAM Write protection page 8 */
#define SYSCFG_CCMSRAMWRP_PAGE9 SYSCFG_SWPR_PAGE9 /*!< CCMSRAM Write protection page 9 */
#define SYSCFG_CCMSRAMWRP_PAGE10 SYSCFG_SWPR_PAGE10 /*!< CCMSRAM Write protection page 10 */
#define SYSCFG_CCMSRAMWRP_PAGE11 SYSCFG_SWPR_PAGE11 /*!< CCMSRAM Write protection page 11 */
#define SYSCFG_CCMSRAMWRP_PAGE12 SYSCFG_SWPR_PAGE12 /*!< CCMSRAM Write protection page 12 */
#define SYSCFG_CCMSRAMWRP_PAGE13 SYSCFG_SWPR_PAGE13 /*!< CCMSRAM Write protection page 13 */
#define SYSCFG_CCMSRAMWRP_PAGE14 SYSCFG_SWPR_PAGE14 /*!< CCMSRAM Write protection page 14 */
#define SYSCFG_CCMSRAMWRP_PAGE15 SYSCFG_SWPR_PAGE15 /*!< CCMSRAM Write protection page 15 */
#define SYSCFG_CCMSRAMWRP_PAGE16 SYSCFG_SWPR_PAGE16 /*!< CCMSRAM Write protection page 16 */
#define SYSCFG_CCMSRAMWRP_PAGE17 SYSCFG_SWPR_PAGE17 /*!< CCMSRAM Write protection page 17 */
#define SYSCFG_CCMSRAMWRP_PAGE18 SYSCFG_SWPR_PAGE18 /*!< CCMSRAM Write protection page 18 */
#define SYSCFG_CCMSRAMWRP_PAGE19 SYSCFG_SWPR_PAGE19 /*!< CCMSRAM Write protection page 19 */
#define SYSCFG_CCMSRAMWRP_PAGE20 SYSCFG_SWPR_PAGE20 /*!< CCMSRAM Write protection page 20 */
#define SYSCFG_CCMSRAMWRP_PAGE21 SYSCFG_SWPR_PAGE21 /*!< CCMSRAM Write protection page 21 */
#define SYSCFG_CCMSRAMWRP_PAGE22 SYSCFG_SWPR_PAGE22 /*!< CCMSRAM Write protection page 22 */
#define SYSCFG_CCMSRAMWRP_PAGE23 SYSCFG_SWPR_PAGE23 /*!< CCMSRAM Write protection page 23 */
#define SYSCFG_CCMSRAMWRP_PAGE24 SYSCFG_SWPR_PAGE24 /*!< CCMSRAM Write protection page 24 */
#define SYSCFG_CCMSRAMWRP_PAGE25 SYSCFG_SWPR_PAGE25 /*!< CCMSRAM Write protection page 25 */
#define SYSCFG_CCMSRAMWRP_PAGE26 SYSCFG_SWPR_PAGE26 /*!< CCMSRAM Write protection page 26 */
#define SYSCFG_CCMSRAMWRP_PAGE27 SYSCFG_SWPR_PAGE27 /*!< CCMSRAM Write protection page 27 */
#define SYSCFG_CCMSRAMWRP_PAGE28 SYSCFG_SWPR_PAGE28 /*!< CCMSRAM Write protection page 28 */
#define SYSCFG_CCMSRAMWRP_PAGE29 SYSCFG_SWPR_PAGE29 /*!< CCMSRAM Write protection page 29 */
#define SYSCFG_CCMSRAMWRP_PAGE30 SYSCFG_SWPR_PAGE30 /*!< CCMSRAM Write protection page 30 */
#define SYSCFG_CCMSRAMWRP_PAGE31 SYSCFG_SWPR_PAGE31 /*!< CCMSRAM Write protection page 31 */
/**
* @}
*/
#if defined(VREFBUF)
/** @defgroup SYSCFG_VREFBUF_VoltageScale VREFBUF Voltage Scale
* @{
*/
#define SYSCFG_VREFBUF_VOLTAGE_SCALE0 0x00000000U /*!< Voltage reference scale 0 (VREFBUF_OUT = 2.048V) */
#define SYSCFG_VREFBUF_VOLTAGE_SCALE1 VREFBUF_CSR_VRS_0 /*!< Voltage reference scale 1 (VREFBUF_OUT = 2.5V) */
#define SYSCFG_VREFBUF_VOLTAGE_SCALE2 VREFBUF_CSR_VRS_1 /*!< Voltage reference scale 2 (VREFBUF_OUT = 2.9V) */
/**
* @}
*/
/** @defgroup SYSCFG_VREFBUF_HighImpedance VREFBUF High Impedance
* @{
*/
#define SYSCFG_VREFBUF_HIGH_IMPEDANCE_DISABLE 0x00000000U /*!< VREF_plus pin is internally connected to Voltage reference buffer output */
#define SYSCFG_VREFBUF_HIGH_IMPEDANCE_ENABLE VREFBUF_CSR_HIZ /*!< VREF_plus pin is high impedance */
/**
* @}
*/
#endif /* VREFBUF */
/** @defgroup SYSCFG_flags_definition Flags
* @{
*/
#define SYSCFG_FLAG_SRAM_PE SYSCFG_CFGR2_SPF /*!< SRAM parity error (first 32kB of SRAM1 + CCM SRAM) */
#define SYSCFG_FLAG_CCMSRAM_BUSY SYSCFG_SCSR_CCMBSY /*!< CCMSRAM busy by erase operation */
/**
* @}
*/
/** @defgroup SYSCFG_FastModePlus_GPIO Fast-mode Plus on GPIO
* @{
*/
/** @brief Fast-mode Plus driving capability on a specific GPIO
*/
#define SYSCFG_FASTMODEPLUS_PB6 SYSCFG_CFGR1_I2C_PB6_FMP /*!< Enable Fast-mode Plus on PB6 */
#define SYSCFG_FASTMODEPLUS_PB7 SYSCFG_CFGR1_I2C_PB7_FMP /*!< Enable Fast-mode Plus on PB7 */
#if defined(SYSCFG_CFGR1_I2C_PB8_FMP)
#define SYSCFG_FASTMODEPLUS_PB8 SYSCFG_CFGR1_I2C_PB8_FMP /*!< Enable Fast-mode Plus on PB8 */
#endif /* SYSCFG_CFGR1_I2C_PB8_FMP */
#if defined(SYSCFG_CFGR1_I2C_PB9_FMP)
#define SYSCFG_FASTMODEPLUS_PB9 SYSCFG_CFGR1_I2C_PB9_FMP /*!< Enable Fast-mode Plus on PB9 */
#endif /* SYSCFG_CFGR1_I2C_PB9_FMP */
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup DBGMCU_Exported_Macros DBGMCU Exported Macros
* @{
*/
/** @brief Freeze/Unfreeze Peripherals in Debug mode
*/
#if defined(DBGMCU_APB1FZR1_DBG_TIM2_STOP)
#define __HAL_DBGMCU_FREEZE_TIM2() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM2_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM2() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM2_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_TIM2_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_TIM3_STOP)
#define __HAL_DBGMCU_FREEZE_TIM3() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM3_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM3() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM3_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_TIM3_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_TIM4_STOP)
#define __HAL_DBGMCU_FREEZE_TIM4() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM4_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM4() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM4_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_TIM4_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_TIM5_STOP)
#define __HAL_DBGMCU_FREEZE_TIM5() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM5_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM5() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM5_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_TIM5_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_TIM6_STOP)
#define __HAL_DBGMCU_FREEZE_TIM6() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM6_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM6() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM6_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_TIM6_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_TIM7_STOP)
#define __HAL_DBGMCU_FREEZE_TIM7() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM7_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM7() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_TIM7_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_TIM7_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_RTC_STOP)
#define __HAL_DBGMCU_FREEZE_RTC() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_RTC_STOP)
#define __HAL_DBGMCU_UNFREEZE_RTC() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_RTC_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_RTC_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_WWDG_STOP)
#define __HAL_DBGMCU_FREEZE_WWDG() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_WWDG_STOP)
#define __HAL_DBGMCU_UNFREEZE_WWDG() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_WWDG_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_WWDG_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_IWDG_STOP)
#define __HAL_DBGMCU_FREEZE_IWDG() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_IWDG_STOP)
#define __HAL_DBGMCU_UNFREEZE_IWDG() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_IWDG_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_IWDG_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_I2C1_STOP)
#define __HAL_DBGMCU_FREEZE_I2C1_TIMEOUT() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_I2C1_STOP)
#define __HAL_DBGMCU_UNFREEZE_I2C1_TIMEOUT() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_I2C1_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_I2C1_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_I2C2_STOP)
#define __HAL_DBGMCU_FREEZE_I2C2_TIMEOUT() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_I2C2_STOP)
#define __HAL_DBGMCU_UNFREEZE_I2C2_TIMEOUT() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_I2C2_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_I2C2_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_I2C3_STOP)
#define __HAL_DBGMCU_FREEZE_I2C3_TIMEOUT() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_I2C3_STOP)
#define __HAL_DBGMCU_UNFREEZE_I2C3_TIMEOUT() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_I2C3_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_I2C3_STOP */
#if defined(DBGMCU_APB1FZR1_DBG_LPTIM1_STOP)
#define __HAL_DBGMCU_FREEZE_LPTIM1() SET_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_LPTIM1_STOP)
#define __HAL_DBGMCU_UNFREEZE_LPTIM1() CLEAR_BIT(DBGMCU->APB1FZR1, DBGMCU_APB1FZR1_DBG_LPTIM1_STOP)
#endif /* DBGMCU_APB1FZR1_DBG_LPTIM1_STOP */
#if defined(DBGMCU_APB1FZR2_DBG_I2C4_STOP)
#define __HAL_DBGMCU_FREEZE_I2C4_TIMEOUT() SET_BIT(DBGMCU->APB1FZR2, DBGMCU_APB1FZR2_DBG_I2C4_STOP)
#define __HAL_DBGMCU_UNFREEZE_I2C4_TIMEOUT() CLEAR_BIT(DBGMCU->APB1FZR2, DBGMCU_APB1FZR2_DBG_I2C4_STOP)
#endif /* DBGMCU_APB1FZR2_DBG_I2C4_STOP */
#if defined(DBGMCU_APB2FZ_DBG_TIM1_STOP)
#define __HAL_DBGMCU_FREEZE_TIM1() SET_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM1_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM1() CLEAR_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM1_STOP)
#endif /* DBGMCU_APB2FZ_DBG_TIM1_STOP */
#if defined(DBGMCU_APB2FZ_DBG_TIM8_STOP)
#define __HAL_DBGMCU_FREEZE_TIM8() SET_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM8_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM8() CLEAR_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM8_STOP)
#endif /* DBGMCU_APB2FZ_DBG_TIM8_STOP */
#if defined(DBGMCU_APB2FZ_DBG_TIM15_STOP)
#define __HAL_DBGMCU_FREEZE_TIM15() SET_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM15_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM15() CLEAR_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM15_STOP)
#endif /* DBGMCU_APB2FZ_DBG_TIM15_STOP */
#if defined(DBGMCU_APB2FZ_DBG_TIM16_STOP)
#define __HAL_DBGMCU_FREEZE_TIM16() SET_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM16_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM16() CLEAR_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM16_STOP)
#endif /* DBGMCU_APB2FZ_DBG_TIM16_STOP */
#if defined(DBGMCU_APB2FZ_DBG_TIM17_STOP)
#define __HAL_DBGMCU_FREEZE_TIM17() SET_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM17_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM17() CLEAR_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM17_STOP)
#endif /* DBGMCU_APB2FZ_DBG_TIM17_STOP */
#if defined(DBGMCU_APB2FZ_DBG_TIM20_STOP)
#define __HAL_DBGMCU_FREEZE_TIM20() SET_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM20_STOP)
#define __HAL_DBGMCU_UNFREEZE_TIM20() CLEAR_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_TIM20_STOP)
#endif /* DBGMCU_APB2FZ_DBG_TIM20_STOP */
#if defined(DBGMCU_APB2FZ_DBG_HRTIM1_STOP)
#define __HAL_DBGMCU_FREEZE_HRTIM1() SET_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_HRTIM1_STOP)
#define __HAL_DBGMCU_UNFREEZE_HRTIM1() CLEAR_BIT(DBGMCU->APB2FZ, DBGMCU_APB2FZ_DBG_HRTIM1_STOP)
#endif /* DBGMCU_APB2FZ_DBG_HRTIM1_STOP */
/**
* @}
*/
/** @defgroup SYSCFG_Exported_Macros SYSCFG Exported Macros
* @{
*/
/** @brief Main Flash memory mapped at 0x00000000.
*/
#define __HAL_SYSCFG_REMAPMEMORY_FLASH() CLEAR_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE)
/** @brief System Flash memory mapped at 0x00000000.
*/
#define __HAL_SYSCFG_REMAPMEMORY_SYSTEMFLASH() MODIFY_REG(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE, SYSCFG_MEMRMP_MEM_MODE_0)
/** @brief Embedded SRAM mapped at 0x00000000.
*/
#define __HAL_SYSCFG_REMAPMEMORY_SRAM() MODIFY_REG(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE, (SYSCFG_MEMRMP_MEM_MODE_1|SYSCFG_MEMRMP_MEM_MODE_0))
#if defined (FMC_BANK1)
/** @brief FMC Bank1 (NOR/PSRAM 1 and 2) mapped at 0x00000000.
*/
#define __HAL_SYSCFG_REMAPMEMORY_FMC() MODIFY_REG(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE, SYSCFG_MEMRMP_MEM_MODE_1)
#endif /* FMC_BANK1 */
#if defined (QUADSPI)
/** @brief QUADSPI mapped at 0x00000000.
*/
#define __HAL_SYSCFG_REMAPMEMORY_QUADSPI() MODIFY_REG(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE, (SYSCFG_MEMRMP_MEM_MODE_2|SYSCFG_MEMRMP_MEM_MODE_1))
#endif /* QUADSPI */
/**
* @brief Return the boot mode as configured by user.
* @retval The boot mode as configured by user. The returned value can be one
* of the following values:
* @arg @ref SYSCFG_BOOT_MAINFLASH
* @arg @ref SYSCFG_BOOT_SYSTEMFLASH
* @arg @ref SYSCFG_BOOT_FMC (*)
* @arg @ref SYSCFG_BOOT_QUADSPI (*)
* @arg @ref SYSCFG_BOOT_SRAM
* @note (*) availability depends on devices
*/
#define __HAL_SYSCFG_GET_BOOT_MODE() READ_BIT(SYSCFG->MEMRMP, SYSCFG_MEMRMP_MEM_MODE)
/** @brief CCMSRAM page write protection enable macro
* @param __CCMSRAMWRP__: This parameter can be a value of @ref SYSCFG_CCMSRAMWRP
* @note write protection can only be disabled by a system reset
* @retval None
*/
/* Legacy define */
#define __HAL_SYSCFG_CCMSRAM_WRP_1_31_ENABLE __HAL_SYSCFG_CCMSRAM_WRP_0_31_ENABLE
#define __HAL_SYSCFG_CCMSRAM_WRP_0_31_ENABLE(__CCMSRAMWRP__) do {assert_param(IS_SYSCFG_CCMSRAMWRP_PAGE((__CCMSRAMWRP__)));\
SET_BIT(SYSCFG->SWPR,(__CCMSRAMWRP__));\
}while(0)
/** @brief CCMSRAM page write protection unlock prior to erase
* @note Writing a wrong key reactivates the write protection
*/
#define __HAL_SYSCFG_CCMSRAM_WRP_UNLOCK() do {SYSCFG->SKR = 0xCA;\
SYSCFG->SKR = 0x53;\
}while(0)
/** @brief CCMSRAM erase
* @note __SYSCFG_GET_FLAG(SYSCFG_FLAG_CCMSRAM_BUSY) may be used to check end of erase
*/
#define __HAL_SYSCFG_CCMSRAM_ERASE() SET_BIT(SYSCFG->SCSR, SYSCFG_SCSR_CCMER)
/** @brief Floating Point Unit interrupt enable/disable macros
* @param __INTERRUPT__: This parameter can be a value of @ref SYSCFG_FPU_Interrupts
*/
#define __HAL_SYSCFG_FPU_INTERRUPT_ENABLE(__INTERRUPT__) do {assert_param(IS_SYSCFG_FPU_INTERRUPT((__INTERRUPT__)));\
SET_BIT(SYSCFG->CFGR1, (__INTERRUPT__));\
}while(0)
#define __HAL_SYSCFG_FPU_INTERRUPT_DISABLE(__INTERRUPT__) do {assert_param(IS_SYSCFG_FPU_INTERRUPT((__INTERRUPT__)));\
CLEAR_BIT(SYSCFG->CFGR1, (__INTERRUPT__));\
}while(0)
/** @brief SYSCFG Break ECC lock.
* Enable and lock the connection of Flash ECC error connection to TIM1/8/15/16/17 Break input.
* @note The selected configuration is locked and can be unlocked only by system reset.
*/
#define __HAL_SYSCFG_BREAK_ECC_LOCK() SET_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_ECCL)
/** @brief SYSCFG Break Cortex-M4 Lockup lock.
* Enable and lock the connection of Cortex-M4 LOCKUP (Hardfault) output to TIM1/8/15/16/17 Break input.
* @note The selected configuration is locked and can be unlocked only by system reset.
*/
#define __HAL_SYSCFG_BREAK_LOCKUP_LOCK() SET_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_CLL)
/** @brief SYSCFG Break PVD lock.
* Enable and lock the PVD connection to Timer1/8/15/16/17 Break input, as well as the PVDE and PLS[2:0] in the PWR_CR2 register.
* @note The selected configuration is locked and can be unlocked only by system reset.
*/
#define __HAL_SYSCFG_BREAK_PVD_LOCK() SET_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_PVDL)
/** @brief SYSCFG Break SRAM parity lock.
* Enable and lock the SRAM parity error (first 32kB of SRAM1 + CCM SRAM) signal connection to TIM1/8/15/16/17 Break input.
* @note The selected configuration is locked and can be unlocked by system reset.
*/
#define __HAL_SYSCFG_BREAK_SRAMPARITY_LOCK() SET_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_SPL)
/** @brief Check SYSCFG flag is set or not.
* @param __FLAG__: specifies the flag to check.
* This parameter can be one of the following values:
* @arg @ref SYSCFG_FLAG_SRAM_PE SRAM Parity Error Flag
* @arg @ref SYSCFG_FLAG_CCMSRAM_BUSY CCMSRAM Erase Ongoing
* @retval The new state of __FLAG__ (TRUE or FALSE).
*/
#define __HAL_SYSCFG_GET_FLAG(__FLAG__) ((((((__FLAG__) == SYSCFG_SCSR_CCMBSY)? SYSCFG->SCSR : SYSCFG->CFGR2)\
& (__FLAG__))!= 0U) ? 1U : 0U)
/** @brief Set the SPF bit to clear the SRAM Parity Error Flag.
*/
#define __HAL_SYSCFG_CLEAR_FLAG() SET_BIT(SYSCFG->CFGR2, SYSCFG_CFGR2_SPF)
/** @brief Fast-mode Plus driving capability enable/disable macros
* @param __FASTMODEPLUS__: This parameter can be a value of :
* @arg @ref SYSCFG_FASTMODEPLUS_PB6 Fast-mode Plus driving capability activation on PB6
* @arg @ref SYSCFG_FASTMODEPLUS_PB7 Fast-mode Plus driving capability activation on PB7
* @arg @ref SYSCFG_FASTMODEPLUS_PB8 Fast-mode Plus driving capability activation on PB8
* @arg @ref SYSCFG_FASTMODEPLUS_PB9 Fast-mode Plus driving capability activation on PB9
*/
#define __HAL_SYSCFG_FASTMODEPLUS_ENABLE(__FASTMODEPLUS__) do {assert_param(IS_SYSCFG_FASTMODEPLUS((__FASTMODEPLUS__)));\
SET_BIT(SYSCFG->CFGR1, (__FASTMODEPLUS__));\
}while(0)
#define __HAL_SYSCFG_FASTMODEPLUS_DISABLE(__FASTMODEPLUS__) do {assert_param(IS_SYSCFG_FASTMODEPLUS((__FASTMODEPLUS__)));\
CLEAR_BIT(SYSCFG->CFGR1, (__FASTMODEPLUS__));\
}while(0)
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup SYSCFG_Private_Macros SYSCFG Private Macros
* @{
*/
#define IS_SYSCFG_FPU_INTERRUPT(__INTERRUPT__) ((((__INTERRUPT__) & SYSCFG_IT_FPU_IOC) == SYSCFG_IT_FPU_IOC) || \
(((__INTERRUPT__) & SYSCFG_IT_FPU_DZC) == SYSCFG_IT_FPU_DZC) || \
(((__INTERRUPT__) & SYSCFG_IT_FPU_UFC) == SYSCFG_IT_FPU_UFC) || \
(((__INTERRUPT__) & SYSCFG_IT_FPU_OFC) == SYSCFG_IT_FPU_OFC) || \
(((__INTERRUPT__) & SYSCFG_IT_FPU_IDC) == SYSCFG_IT_FPU_IDC) || \
(((__INTERRUPT__) & SYSCFG_IT_FPU_IXC) == SYSCFG_IT_FPU_IXC))
#define IS_SYSCFG_BREAK_CONFIG(__CONFIG__) (((__CONFIG__) == SYSCFG_BREAK_ECC) || \
((__CONFIG__) == SYSCFG_BREAK_PVD) || \
((__CONFIG__) == SYSCFG_BREAK_SRAMPARITY) || \
((__CONFIG__) == SYSCFG_BREAK_LOCKUP))
#if (CCMSRAM_SIZE == 0x00008000UL) || (CCMSRAM_SIZE == 0x00004000UL)
#define IS_SYSCFG_CCMSRAMWRP_PAGE(__PAGE__) ((__PAGE__) > 0U)
#elif (CCMSRAM_SIZE == 0x00002800UL)
#define IS_SYSCFG_CCMSRAMWRP_PAGE(__PAGE__) (((__PAGE__) > 0U) && ((__PAGE__) <= 0x000003FFU))
#endif /* CCMSRAM_SIZE */
#if defined(VREFBUF)
#define IS_SYSCFG_VREFBUF_VOLTAGE_SCALE(__SCALE__) (((__SCALE__) == SYSCFG_VREFBUF_VOLTAGE_SCALE0) || \
((__SCALE__) == SYSCFG_VREFBUF_VOLTAGE_SCALE1) || \
((__SCALE__) == SYSCFG_VREFBUF_VOLTAGE_SCALE2))
#define IS_SYSCFG_VREFBUF_HIGH_IMPEDANCE(__VALUE__) (((__VALUE__) == SYSCFG_VREFBUF_HIGH_IMPEDANCE_DISABLE) || \
((__VALUE__) == SYSCFG_VREFBUF_HIGH_IMPEDANCE_ENABLE))
#define IS_SYSCFG_VREFBUF_TRIMMING(__VALUE__) (((__VALUE__) > 0U) && ((__VALUE__) <= VREFBUF_CCR_TRIM))
#endif /* VREFBUF */
#if defined(SYSCFG_FASTMODEPLUS_PB8) && defined(SYSCFG_FASTMODEPLUS_PB9)
#define IS_SYSCFG_FASTMODEPLUS(__PIN__) ((((__PIN__) & SYSCFG_FASTMODEPLUS_PB6) == SYSCFG_FASTMODEPLUS_PB6) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB7) == SYSCFG_FASTMODEPLUS_PB7) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB8) == SYSCFG_FASTMODEPLUS_PB8) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB9) == SYSCFG_FASTMODEPLUS_PB9))
#elif defined(SYSCFG_FASTMODEPLUS_PB8)
#define IS_SYSCFG_FASTMODEPLUS(__PIN__) ((((__PIN__) & SYSCFG_FASTMODEPLUS_PB6) == SYSCFG_FASTMODEPLUS_PB6) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB7) == SYSCFG_FASTMODEPLUS_PB7) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB8) == SYSCFG_FASTMODEPLUS_PB8))
#elif defined(SYSCFG_FASTMODEPLUS_PB9)
#define IS_SYSCFG_FASTMODEPLUS(__PIN__) ((((__PIN__) & SYSCFG_FASTMODEPLUS_PB6) == SYSCFG_FASTMODEPLUS_PB6) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB7) == SYSCFG_FASTMODEPLUS_PB7) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB9) == SYSCFG_FASTMODEPLUS_PB9))
#else
#define IS_SYSCFG_FASTMODEPLUS(__PIN__) ((((__PIN__) & SYSCFG_FASTMODEPLUS_PB6) == SYSCFG_FASTMODEPLUS_PB6) || \
(((__PIN__) & SYSCFG_FASTMODEPLUS_PB7) == SYSCFG_FASTMODEPLUS_PB7))
#endif /* SYSCFG_FASTMODEPLUS_PB */
/**
* @}
*/
/** @defgroup HAL_Private_Macros HAL Private Macros
* @{
*/
#define IS_TICKFREQ(FREQ) (((FREQ) == HAL_TICK_FREQ_10HZ) || \
((FREQ) == HAL_TICK_FREQ_100HZ) || \
((FREQ) == HAL_TICK_FREQ_1KHZ))
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup HAL_Exported_Functions
* @{
*/
/** @addtogroup HAL_Exported_Functions_Group1
* @{
*/
/* Initialization and Configuration functions ******************************/
HAL_StatusTypeDef HAL_Init(void);
HAL_StatusTypeDef HAL_DeInit(void);
void HAL_MspInit(void);
void HAL_MspDeInit(void);
HAL_StatusTypeDef HAL_InitTick(uint32_t TickPriority);
/**
* @}
*/
/** @addtogroup HAL_Exported_Functions_Group2 HAL Control functions
* @{
*/
/* Peripheral Control functions ************************************************/
void HAL_IncTick(void);
void HAL_Delay(uint32_t Delay);
uint32_t HAL_GetTick(void);
uint32_t HAL_GetTickPrio(void);
HAL_StatusTypeDef HAL_SetTickFreq(uint32_t Freq);
uint32_t HAL_GetTickFreq(void);
void HAL_SuspendTick(void);
void HAL_ResumeTick(void);
uint32_t HAL_GetHalVersion(void);
uint32_t HAL_GetREVID(void);
uint32_t HAL_GetDEVID(void);
uint32_t HAL_GetUIDw0(void);
uint32_t HAL_GetUIDw1(void);
uint32_t HAL_GetUIDw2(void);
/**
* @}
*/
/** @addtogroup HAL_Exported_Functions_Group3
* @{
*/
/* DBGMCU Peripheral Control functions *****************************************/
void HAL_DBGMCU_EnableDBGSleepMode(void);
void HAL_DBGMCU_DisableDBGSleepMode(void);
void HAL_DBGMCU_EnableDBGStopMode(void);
void HAL_DBGMCU_DisableDBGStopMode(void);
void HAL_DBGMCU_EnableDBGStandbyMode(void);
void HAL_DBGMCU_DisableDBGStandbyMode(void);
/**
* @}
*/
/* Exported variables ---------------------------------------------------------*/
/** @addtogroup HAL_Exported_Variables
* @{
*/
extern __IO uint32_t uwTick;
extern uint32_t uwTickPrio;
extern uint32_t uwTickFreq;
/**
* @}
*/
/** @addtogroup HAL_Exported_Functions_Group4
* @{
*/
/* SYSCFG Control functions ****************************************************/
void HAL_SYSCFG_CCMSRAMErase(void);
void HAL_SYSCFG_EnableMemorySwappingBank(void);
void HAL_SYSCFG_DisableMemorySwappingBank(void);
#if defined(VREFBUF)
void HAL_SYSCFG_VREFBUF_VoltageScalingConfig(uint32_t VoltageScaling);
void HAL_SYSCFG_VREFBUF_HighImpedanceConfig(uint32_t Mode);
void HAL_SYSCFG_VREFBUF_TrimmingConfig(uint32_t TrimmingValue);
HAL_StatusTypeDef HAL_SYSCFG_EnableVREFBUF(void);
void HAL_SYSCFG_DisableVREFBUF(void);
#endif /* VREFBUF */
void HAL_SYSCFG_EnableIOSwitchBooster(void);
void HAL_SYSCFG_DisableIOSwitchBooster(void);
void HAL_SYSCFG_EnableIOSwitchVDD(void);
void HAL_SYSCFG_DisableIOSwitchVDD(void);
void HAL_SYSCFG_CCMSRAM_WriteProtectionEnable(uint32_t Page);
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_H */
| 27,983 | C | 43.560509 | 150 | 0.619948 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/stm32g4xx_hal_dma_ex.h | /**
******************************************************************************
* @file stm32g4xx_hal_dma_ex.h
* @author MCD Application Team
* @brief Header file of DMA HAL extension module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM32G4xx_HAL_DMA_EX_H
#define __STM32G4xx_HAL_DMA_EX_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup DMAEx
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @defgroup DMAEx_Exported_Types DMAEx Exported Types
* @{
*/
/**
* @brief HAL DMA Synchro definition
*/
/**
* @brief HAL DMAMUX Synchronization configuration structure definition
*/
typedef struct
{
uint32_t SyncSignalID; /*!< Specifies the synchronization signal gating the DMA request in periodic mode.
This parameter can be a value of @ref DMAEx_DMAMUX_SyncSignalID_selection */
uint32_t SyncPolarity; /*!< Specifies the polarity of the signal on which the DMA request is synchronized.
This parameter can be a value of @ref DMAEx_DMAMUX_SyncPolarity_selection */
FunctionalState SyncEnable; /*!< Specifies if the synchronization shall be enabled or disabled
This parameter can take the value ENABLE or DISABLE*/
FunctionalState EventEnable; /*!< Specifies if an event shall be generated once the RequestNumber is reached.
This parameter can take the value ENABLE or DISABLE */
uint32_t RequestNumber; /*!< Specifies the number of DMA request that will be authorized after a sync event
This parameter must be a number between Min_Data = 1 and Max_Data = 32 */
} HAL_DMA_MuxSyncConfigTypeDef;
/**
* @brief HAL DMAMUX request generator parameters structure definition
*/
typedef struct
{
uint32_t SignalID; /*!< Specifies the ID of the signal used for DMAMUX request generator
This parameter can be a value of @ref DMAEx_DMAMUX_SignalGeneratorID_selection */
uint32_t Polarity; /*!< Specifies the polarity of the signal on which the request is generated.
This parameter can be a value of @ref DMAEx_DMAMUX_RequestGeneneratorPolarity_selection */
uint32_t RequestNumber; /*!< Specifies the number of DMA request that will be generated after a signal event
This parameter must be a number between Min_Data = 1 and Max_Data = 32 */
} HAL_DMA_MuxRequestGeneratorConfigTypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup DMAEx_Exported_Constants DMAEx Exported Constants
* @{
*/
/** @defgroup DMAEx_DMAMUX_SyncSignalID_selection DMAMUX SyncSignalID selection
* @{
*/
#define HAL_DMAMUX1_SYNC_EXTI0 0U /*!< Synchronization Signal is EXTI0 IT */
#define HAL_DMAMUX1_SYNC_EXTI1 1U /*!< Synchronization Signal is EXTI1 IT */
#define HAL_DMAMUX1_SYNC_EXTI2 2U /*!< Synchronization Signal is EXTI2 IT */
#define HAL_DMAMUX1_SYNC_EXTI3 3U /*!< Synchronization Signal is EXTI3 IT */
#define HAL_DMAMUX1_SYNC_EXTI4 4U /*!< Synchronization Signal is EXTI4 IT */
#define HAL_DMAMUX1_SYNC_EXTI5 5U /*!< Synchronization Signal is EXTI5 IT */
#define HAL_DMAMUX1_SYNC_EXTI6 6U /*!< Synchronization Signal is EXTI6 IT */
#define HAL_DMAMUX1_SYNC_EXTI7 7U /*!< Synchronization Signal is EXTI7 IT */
#define HAL_DMAMUX1_SYNC_EXTI8 8U /*!< Synchronization Signal is EXTI8 IT */
#define HAL_DMAMUX1_SYNC_EXTI9 9U /*!< Synchronization Signal is EXTI9 IT */
#define HAL_DMAMUX1_SYNC_EXTI10 10U /*!< Synchronization Signal is EXTI10 IT */
#define HAL_DMAMUX1_SYNC_EXTI11 11U /*!< Synchronization Signal is EXTI11 IT */
#define HAL_DMAMUX1_SYNC_EXTI12 12U /*!< Synchronization Signal is EXTI12 IT */
#define HAL_DMAMUX1_SYNC_EXTI13 13U /*!< Synchronization Signal is EXTI13 IT */
#define HAL_DMAMUX1_SYNC_EXTI14 14U /*!< Synchronization Signal is EXTI14 IT */
#define HAL_DMAMUX1_SYNC_EXTI15 15U /*!< Synchronization Signal is EXTI15 IT */
#define HAL_DMAMUX1_SYNC_DMAMUX1_CH0_EVT 16U /*!< Synchronization Signal is DMAMUX1 Channel0 Event */
#define HAL_DMAMUX1_SYNC_DMAMUX1_CH1_EVT 17U /*!< Synchronization Signal is DMAMUX1 Channel1 Event */
#define HAL_DMAMUX1_SYNC_DMAMUX1_CH2_EVT 18U /*!< Synchronization Signal is DMAMUX1 Channel2 Event */
#define HAL_DMAMUX1_SYNC_DMAMUX1_CH3_EVT 19U /*!< Synchronization Signal is DMAMUX1 Channel3 Event */
#define HAL_DMAMUX1_SYNC_LPTIM1_OUT 20U /*!< Synchronization Signal is LPTIM1 OUT */
/**
* @}
*/
/** @defgroup DMAEx_DMAMUX_SyncPolarity_selection DMAMUX SyncPolarity selection
* @{
*/
#define HAL_DMAMUX_SYNC_NO_EVENT 0U /*!< block synchronization events */
#define HAL_DMAMUX_SYNC_RISING ((uint32_t)DMAMUX_CxCR_SPOL_0) /*!< synchronize with rising edge events */
#define HAL_DMAMUX_SYNC_FALLING ((uint32_t)DMAMUX_CxCR_SPOL_1) /*!< synchronize with falling edge events */
#define HAL_DMAMUX_SYNC_RISING_FALLING ((uint32_t)DMAMUX_CxCR_SPOL) /*!< synchronize with rising and falling edge events */
/**
* @}
*/
/** @defgroup DMAEx_DMAMUX_SignalGeneratorID_selection DMAMUX SignalGeneratorID selection
* @{
*/
#define HAL_DMAMUX1_REQ_GEN_EXTI0 0U /*!< Request generator Signal is EXTI0 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI1 1U /*!< Request generator Signal is EXTI1 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI2 2U /*!< Request generator Signal is EXTI2 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI3 3U /*!< Request generator Signal is EXTI3 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI4 4U /*!< Request generator Signal is EXTI4 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI5 5U /*!< Request generator Signal is EXTI5 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI6 6U /*!< Request generator Signal is EXTI6 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI7 7U /*!< Request generator Signal is EXTI7 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI8 8U /*!< Request generator Signal is EXTI8 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI9 9U /*!< Request generator Signal is EXTI9 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI10 10U /*!< Request generator Signal is EXTI10 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI11 11U /*!< Request generator Signal is EXTI11 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI12 12U /*!< Request generator Signal is EXTI12 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI13 13U /*!< Request generator Signal is EXTI13 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI14 14U /*!< Request generator Signal is EXTI14 IT */
#define HAL_DMAMUX1_REQ_GEN_EXTI15 15U /*!< Request generator Signal is EXTI15 IT */
#define HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH0_EVT 16U /*!< Request generator Signal is DMAMUX1 Channel0 Event */
#define HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH1_EVT 17U /*!< Request generator Signal is DMAMUX1 Channel1 Event */
#define HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH2_EVT 18U /*!< Request generator Signal is DMAMUX1 Channel2 Event */
#define HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH3_EVT 19U /*!< Request generator Signal is DMAMUX1 Channel3 Event */
#define HAL_DMAMUX1_REQ_GEN_LPTIM1_OUT 20U /*!< Request generator Signal is LPTIM1 OUT */
/**
* @}
*/
/** @defgroup DMAEx_DMAMUX_RequestGeneneratorPolarity_selection DMAMUX RequestGeneneratorPolarity selection
* @{
*/
#define HAL_DMAMUX_REQ_GEN_NO_EVENT 0x00000000U /*!< block request generator events */
#define HAL_DMAMUX_REQ_GEN_RISING DMAMUX_RGxCR_GPOL_0 /*!< generate request on rising edge events */
#define HAL_DMAMUX_REQ_GEN_FALLING DMAMUX_RGxCR_GPOL_1 /*!< generate request on falling edge events */
#define HAL_DMAMUX_REQ_GEN_RISING_FALLING DMAMUX_RGxCR_GPOL /*!< generate request on rising and falling edge events */
/**
* @}
*/
/**
* @}
*/
/* Exported macro ------------------------------------------------------------*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup DMAEx_Exported_Functions
* @{
*/
/* IO operation functions *****************************************************/
/** @addtogroup DMAEx_Exported_Functions_Group1
* @{
*/
/* ------------------------- REQUEST -----------------------------------------*/
HAL_StatusTypeDef HAL_DMAEx_ConfigMuxRequestGenerator(DMA_HandleTypeDef *hdma,
HAL_DMA_MuxRequestGeneratorConfigTypeDef *pRequestGeneratorConfig);
HAL_StatusTypeDef HAL_DMAEx_EnableMuxRequestGenerator(DMA_HandleTypeDef *hdma);
HAL_StatusTypeDef HAL_DMAEx_DisableMuxRequestGenerator(DMA_HandleTypeDef *hdma);
/* -------------------------------------------------------------------------- */
/* ------------------------- SYNCHRO -----------------------------------------*/
HAL_StatusTypeDef HAL_DMAEx_ConfigMuxSync(DMA_HandleTypeDef *hdma, HAL_DMA_MuxSyncConfigTypeDef *pSyncConfig);
/* -------------------------------------------------------------------------- */
void HAL_DMAEx_MUX_IRQHandler(DMA_HandleTypeDef *hdma);
/**
* @}
*/
/**
* @}
*/
/* Private macros ------------------------------------------------------------*/
/** @defgroup DMAEx_Private_Macros DMAEx Private Macros
* @brief DMAEx private macros
* @{
*/
#define IS_DMAMUX_SYNC_SIGNAL_ID(SIGNAL_ID) ((SIGNAL_ID) <= HAL_DMAMUX1_SYNC_LPTIM1_OUT)
#define IS_DMAMUX_SYNC_REQUEST_NUMBER(REQUEST_NUMBER) (((REQUEST_NUMBER) > 0U) && ((REQUEST_NUMBER) <= 32U))
#define IS_DMAMUX_SYNC_POLARITY(POLARITY) (((POLARITY) == HAL_DMAMUX_SYNC_NO_EVENT) || \
((POLARITY) == HAL_DMAMUX_SYNC_RISING) || \
((POLARITY) == HAL_DMAMUX_SYNC_FALLING) || \
((POLARITY) == HAL_DMAMUX_SYNC_RISING_FALLING))
#define IS_DMAMUX_SYNC_STATE(SYNC) (((SYNC) == DISABLE) || ((SYNC) == ENABLE))
#define IS_DMAMUX_SYNC_EVENT(EVENT) (((EVENT) == DISABLE) || \
((EVENT) == ENABLE))
#define IS_DMAMUX_REQUEST_GEN_SIGNAL_ID(SIGNAL_ID) ((SIGNAL_ID) <= HAL_DMAMUX1_REQ_GEN_LPTIM1_OUT)
#define IS_DMAMUX_REQUEST_GEN_REQUEST_NUMBER(REQUEST_NUMBER) (((REQUEST_NUMBER) > 0U) && ((REQUEST_NUMBER) <= 32U))
#define IS_DMAMUX_REQUEST_GEN_POLARITY(POLARITY) (((POLARITY) == HAL_DMAMUX_REQ_GEN_NO_EVENT) || \
((POLARITY) == HAL_DMAMUX_REQ_GEN_RISING) || \
((POLARITY) == HAL_DMAMUX_REQ_GEN_FALLING) || \
((POLARITY) == HAL_DMAMUX_REQ_GEN_RISING_FALLING))
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* __STM32G4xx_HAL_DMA_EX_H */
| 12,347 | C | 45.596226 | 124 | 0.561027 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/STM32G4xx_HAL_Driver/Inc/Legacy/stm32_hal_legacy.h | /**
******************************************************************************
* @file stm32_hal_legacy.h
* @author MCD Application Team
* @brief This file contains aliases definition for the STM32Cube HAL constants
* macros and functions maintained for legacy purpose.
******************************************************************************
* @attention
*
* Copyright (c) 2021 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32_HAL_LEGACY
#define STM32_HAL_LEGACY
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
/* Exported types ------------------------------------------------------------*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup HAL_AES_Aliased_Defines HAL CRYP Aliased Defines maintained for legacy purpose
* @{
*/
#define AES_FLAG_RDERR CRYP_FLAG_RDERR
#define AES_FLAG_WRERR CRYP_FLAG_WRERR
#define AES_CLEARFLAG_CCF CRYP_CLEARFLAG_CCF
#define AES_CLEARFLAG_RDERR CRYP_CLEARFLAG_RDERR
#define AES_CLEARFLAG_WRERR CRYP_CLEARFLAG_WRERR
#if defined(STM32H7) || defined(STM32MP1)
#define CRYP_DATATYPE_32B CRYP_NO_SWAP
#define CRYP_DATATYPE_16B CRYP_HALFWORD_SWAP
#define CRYP_DATATYPE_8B CRYP_BYTE_SWAP
#define CRYP_DATATYPE_1B CRYP_BIT_SWAP
#endif /* STM32H7 || STM32MP1 */
/**
* @}
*/
/** @defgroup HAL_ADC_Aliased_Defines HAL ADC Aliased Defines maintained for legacy purpose
* @{
*/
#define ADC_RESOLUTION12b ADC_RESOLUTION_12B
#define ADC_RESOLUTION10b ADC_RESOLUTION_10B
#define ADC_RESOLUTION8b ADC_RESOLUTION_8B
#define ADC_RESOLUTION6b ADC_RESOLUTION_6B
#define OVR_DATA_OVERWRITTEN ADC_OVR_DATA_OVERWRITTEN
#define OVR_DATA_PRESERVED ADC_OVR_DATA_PRESERVED
#define EOC_SINGLE_CONV ADC_EOC_SINGLE_CONV
#define EOC_SEQ_CONV ADC_EOC_SEQ_CONV
#define EOC_SINGLE_SEQ_CONV ADC_EOC_SINGLE_SEQ_CONV
#define REGULAR_GROUP ADC_REGULAR_GROUP
#define INJECTED_GROUP ADC_INJECTED_GROUP
#define REGULAR_INJECTED_GROUP ADC_REGULAR_INJECTED_GROUP
#define AWD_EVENT ADC_AWD_EVENT
#define AWD1_EVENT ADC_AWD1_EVENT
#define AWD2_EVENT ADC_AWD2_EVENT
#define AWD3_EVENT ADC_AWD3_EVENT
#define OVR_EVENT ADC_OVR_EVENT
#define JQOVF_EVENT ADC_JQOVF_EVENT
#define ALL_CHANNELS ADC_ALL_CHANNELS
#define REGULAR_CHANNELS ADC_REGULAR_CHANNELS
#define INJECTED_CHANNELS ADC_INJECTED_CHANNELS
#define SYSCFG_FLAG_SENSOR_ADC ADC_FLAG_SENSOR
#define SYSCFG_FLAG_VREF_ADC ADC_FLAG_VREFINT
#define ADC_CLOCKPRESCALER_PCLK_DIV1 ADC_CLOCK_SYNC_PCLK_DIV1
#define ADC_CLOCKPRESCALER_PCLK_DIV2 ADC_CLOCK_SYNC_PCLK_DIV2
#define ADC_CLOCKPRESCALER_PCLK_DIV4 ADC_CLOCK_SYNC_PCLK_DIV4
#define ADC_CLOCKPRESCALER_PCLK_DIV6 ADC_CLOCK_SYNC_PCLK_DIV6
#define ADC_CLOCKPRESCALER_PCLK_DIV8 ADC_CLOCK_SYNC_PCLK_DIV8
#define ADC_EXTERNALTRIG0_T6_TRGO ADC_EXTERNALTRIGCONV_T6_TRGO
#define ADC_EXTERNALTRIG1_T21_CC2 ADC_EXTERNALTRIGCONV_T21_CC2
#define ADC_EXTERNALTRIG2_T2_TRGO ADC_EXTERNALTRIGCONV_T2_TRGO
#define ADC_EXTERNALTRIG3_T2_CC4 ADC_EXTERNALTRIGCONV_T2_CC4
#define ADC_EXTERNALTRIG4_T22_TRGO ADC_EXTERNALTRIGCONV_T22_TRGO
#define ADC_EXTERNALTRIG7_EXT_IT11 ADC_EXTERNALTRIGCONV_EXT_IT11
#define ADC_CLOCK_ASYNC ADC_CLOCK_ASYNC_DIV1
#define ADC_EXTERNALTRIG_EDGE_NONE ADC_EXTERNALTRIGCONVEDGE_NONE
#define ADC_EXTERNALTRIG_EDGE_RISING ADC_EXTERNALTRIGCONVEDGE_RISING
#define ADC_EXTERNALTRIG_EDGE_FALLING ADC_EXTERNALTRIGCONVEDGE_FALLING
#define ADC_EXTERNALTRIG_EDGE_RISINGFALLING ADC_EXTERNALTRIGCONVEDGE_RISINGFALLING
#define ADC_SAMPLETIME_2CYCLE_5 ADC_SAMPLETIME_2CYCLES_5
#define HAL_ADC_STATE_BUSY_REG HAL_ADC_STATE_REG_BUSY
#define HAL_ADC_STATE_BUSY_INJ HAL_ADC_STATE_INJ_BUSY
#define HAL_ADC_STATE_EOC_REG HAL_ADC_STATE_REG_EOC
#define HAL_ADC_STATE_EOC_INJ HAL_ADC_STATE_INJ_EOC
#define HAL_ADC_STATE_ERROR HAL_ADC_STATE_ERROR_INTERNAL
#define HAL_ADC_STATE_BUSY HAL_ADC_STATE_BUSY_INTERNAL
#define HAL_ADC_STATE_AWD HAL_ADC_STATE_AWD1
#if defined(STM32H7)
#define ADC_CHANNEL_VBAT_DIV4 ADC_CHANNEL_VBAT
#endif /* STM32H7 */
/**
* @}
*/
/** @defgroup HAL_CEC_Aliased_Defines HAL CEC Aliased Defines maintained for legacy purpose
* @{
*/
#define __HAL_CEC_GET_IT __HAL_CEC_GET_FLAG
/**
* @}
*/
/** @defgroup HAL_COMP_Aliased_Defines HAL COMP Aliased Defines maintained for legacy purpose
* @{
*/
#define COMP_WINDOWMODE_DISABLED COMP_WINDOWMODE_DISABLE
#define COMP_WINDOWMODE_ENABLED COMP_WINDOWMODE_ENABLE
#define COMP_EXTI_LINE_COMP1_EVENT COMP_EXTI_LINE_COMP1
#define COMP_EXTI_LINE_COMP2_EVENT COMP_EXTI_LINE_COMP2
#define COMP_EXTI_LINE_COMP3_EVENT COMP_EXTI_LINE_COMP3
#define COMP_EXTI_LINE_COMP4_EVENT COMP_EXTI_LINE_COMP4
#define COMP_EXTI_LINE_COMP5_EVENT COMP_EXTI_LINE_COMP5
#define COMP_EXTI_LINE_COMP6_EVENT COMP_EXTI_LINE_COMP6
#define COMP_EXTI_LINE_COMP7_EVENT COMP_EXTI_LINE_COMP7
#if defined(STM32L0)
#define COMP_LPTIMCONNECTION_ENABLED ((uint32_t)0x00000003U) /*!< COMPX output generic naming: connected to LPTIM
input 1 for COMP1, LPTIM input 2 for COMP2 */
#endif
#define COMP_OUTPUT_COMP6TIM2OCREFCLR COMP_OUTPUT_COMP6_TIM2OCREFCLR
#if defined(STM32F373xC) || defined(STM32F378xx)
#define COMP_OUTPUT_TIM3IC1 COMP_OUTPUT_COMP1_TIM3IC1
#define COMP_OUTPUT_TIM3OCREFCLR COMP_OUTPUT_COMP1_TIM3OCREFCLR
#endif /* STM32F373xC || STM32F378xx */
#if defined(STM32L0) || defined(STM32L4)
#define COMP_WINDOWMODE_ENABLE COMP_WINDOWMODE_COMP1_INPUT_PLUS_COMMON
#define COMP_NONINVERTINGINPUT_IO1 COMP_INPUT_PLUS_IO1
#define COMP_NONINVERTINGINPUT_IO2 COMP_INPUT_PLUS_IO2
#define COMP_NONINVERTINGINPUT_IO3 COMP_INPUT_PLUS_IO3
#define COMP_NONINVERTINGINPUT_IO4 COMP_INPUT_PLUS_IO4
#define COMP_NONINVERTINGINPUT_IO5 COMP_INPUT_PLUS_IO5
#define COMP_NONINVERTINGINPUT_IO6 COMP_INPUT_PLUS_IO6
#define COMP_INVERTINGINPUT_1_4VREFINT COMP_INPUT_MINUS_1_4VREFINT
#define COMP_INVERTINGINPUT_1_2VREFINT COMP_INPUT_MINUS_1_2VREFINT
#define COMP_INVERTINGINPUT_3_4VREFINT COMP_INPUT_MINUS_3_4VREFINT
#define COMP_INVERTINGINPUT_VREFINT COMP_INPUT_MINUS_VREFINT
#define COMP_INVERTINGINPUT_DAC1_CH1 COMP_INPUT_MINUS_DAC1_CH1
#define COMP_INVERTINGINPUT_DAC1_CH2 COMP_INPUT_MINUS_DAC1_CH2
#define COMP_INVERTINGINPUT_DAC1 COMP_INPUT_MINUS_DAC1_CH1
#define COMP_INVERTINGINPUT_DAC2 COMP_INPUT_MINUS_DAC1_CH2
#define COMP_INVERTINGINPUT_IO1 COMP_INPUT_MINUS_IO1
#if defined(STM32L0)
/* Issue fixed on STM32L0 COMP driver: only 2 dedicated IO (IO1 and IO2), */
/* IO2 was wrongly assigned to IO shared with DAC and IO3 was corresponding */
/* to the second dedicated IO (only for COMP2). */
#define COMP_INVERTINGINPUT_IO2 COMP_INPUT_MINUS_DAC1_CH2
#define COMP_INVERTINGINPUT_IO3 COMP_INPUT_MINUS_IO2
#else
#define COMP_INVERTINGINPUT_IO2 COMP_INPUT_MINUS_IO2
#define COMP_INVERTINGINPUT_IO3 COMP_INPUT_MINUS_IO3
#endif
#define COMP_INVERTINGINPUT_IO4 COMP_INPUT_MINUS_IO4
#define COMP_INVERTINGINPUT_IO5 COMP_INPUT_MINUS_IO5
#define COMP_OUTPUTLEVEL_LOW COMP_OUTPUT_LEVEL_LOW
#define COMP_OUTPUTLEVEL_HIGH COMP_OUTPUT_LEVEL_HIGH
/* Note: Literal "COMP_FLAG_LOCK" kept for legacy purpose. */
/* To check COMP lock state, use macro "__HAL_COMP_IS_LOCKED()". */
#if defined(COMP_CSR_LOCK)
#define COMP_FLAG_LOCK COMP_CSR_LOCK
#elif defined(COMP_CSR_COMP1LOCK)
#define COMP_FLAG_LOCK COMP_CSR_COMP1LOCK
#elif defined(COMP_CSR_COMPxLOCK)
#define COMP_FLAG_LOCK COMP_CSR_COMPxLOCK
#endif
#if defined(STM32L4)
#define COMP_BLANKINGSRCE_TIM1OC5 COMP_BLANKINGSRC_TIM1_OC5_COMP1
#define COMP_BLANKINGSRCE_TIM2OC3 COMP_BLANKINGSRC_TIM2_OC3_COMP1
#define COMP_BLANKINGSRCE_TIM3OC3 COMP_BLANKINGSRC_TIM3_OC3_COMP1
#define COMP_BLANKINGSRCE_TIM3OC4 COMP_BLANKINGSRC_TIM3_OC4_COMP2
#define COMP_BLANKINGSRCE_TIM8OC5 COMP_BLANKINGSRC_TIM8_OC5_COMP2
#define COMP_BLANKINGSRCE_TIM15OC1 COMP_BLANKINGSRC_TIM15_OC1_COMP2
#define COMP_BLANKINGSRCE_NONE COMP_BLANKINGSRC_NONE
#endif
#if defined(STM32L0)
#define COMP_MODE_HIGHSPEED COMP_POWERMODE_MEDIUMSPEED
#define COMP_MODE_LOWSPEED COMP_POWERMODE_ULTRALOWPOWER
#else
#define COMP_MODE_HIGHSPEED COMP_POWERMODE_HIGHSPEED
#define COMP_MODE_MEDIUMSPEED COMP_POWERMODE_MEDIUMSPEED
#define COMP_MODE_LOWPOWER COMP_POWERMODE_LOWPOWER
#define COMP_MODE_ULTRALOWPOWER COMP_POWERMODE_ULTRALOWPOWER
#endif
#endif
/**
* @}
*/
/** @defgroup HAL_CORTEX_Aliased_Defines HAL CORTEX Aliased Defines maintained for legacy purpose
* @{
*/
#define __HAL_CORTEX_SYSTICKCLK_CONFIG HAL_SYSTICK_CLKSourceConfig
/**
* @}
*/
/** @defgroup CRC_Aliases CRC API aliases
* @{
*/
#define HAL_CRC_Input_Data_Reverse HAL_CRCEx_Input_Data_Reverse /*!< Aliased to HAL_CRCEx_Input_Data_Reverse for
inter STM32 series compatibility */
#define HAL_CRC_Output_Data_Reverse HAL_CRCEx_Output_Data_Reverse /*!< Aliased to HAL_CRCEx_Output_Data_Reverse for
inter STM32 series compatibility */
/**
* @}
*/
/** @defgroup HAL_CRC_Aliased_Defines HAL CRC Aliased Defines maintained for legacy purpose
* @{
*/
#define CRC_OUTPUTDATA_INVERSION_DISABLED CRC_OUTPUTDATA_INVERSION_DISABLE
#define CRC_OUTPUTDATA_INVERSION_ENABLED CRC_OUTPUTDATA_INVERSION_ENABLE
/**
* @}
*/
/** @defgroup HAL_DAC_Aliased_Defines HAL DAC Aliased Defines maintained for legacy purpose
* @{
*/
#define DAC1_CHANNEL_1 DAC_CHANNEL_1
#define DAC1_CHANNEL_2 DAC_CHANNEL_2
#define DAC2_CHANNEL_1 DAC_CHANNEL_1
#define DAC_WAVE_NONE 0x00000000U
#define DAC_WAVE_NOISE DAC_CR_WAVE1_0
#define DAC_WAVE_TRIANGLE DAC_CR_WAVE1_1
#define DAC_WAVEGENERATION_NONE DAC_WAVE_NONE
#define DAC_WAVEGENERATION_NOISE DAC_WAVE_NOISE
#define DAC_WAVEGENERATION_TRIANGLE DAC_WAVE_TRIANGLE
#if defined(STM32G4) || defined(STM32H7)
#define DAC_CHIPCONNECT_DISABLE DAC_CHIPCONNECT_EXTERNAL
#define DAC_CHIPCONNECT_ENABLE DAC_CHIPCONNECT_INTERNAL
#endif
#if defined(STM32L1) || defined(STM32L4) || defined(STM32G0) || defined(STM32L5) || defined(STM32H7) || \
defined(STM32F4) || defined(STM32G4)
#define HAL_DAC_MSP_INIT_CB_ID HAL_DAC_MSPINIT_CB_ID
#define HAL_DAC_MSP_DEINIT_CB_ID HAL_DAC_MSPDEINIT_CB_ID
#endif
/**
* @}
*/
/** @defgroup HAL_DMA_Aliased_Defines HAL DMA Aliased Defines maintained for legacy purpose
* @{
*/
#define HAL_REMAPDMA_ADC_DMA_CH2 DMA_REMAP_ADC_DMA_CH2
#define HAL_REMAPDMA_USART1_TX_DMA_CH4 DMA_REMAP_USART1_TX_DMA_CH4
#define HAL_REMAPDMA_USART1_RX_DMA_CH5 DMA_REMAP_USART1_RX_DMA_CH5
#define HAL_REMAPDMA_TIM16_DMA_CH4 DMA_REMAP_TIM16_DMA_CH4
#define HAL_REMAPDMA_TIM17_DMA_CH2 DMA_REMAP_TIM17_DMA_CH2
#define HAL_REMAPDMA_USART3_DMA_CH32 DMA_REMAP_USART3_DMA_CH32
#define HAL_REMAPDMA_TIM16_DMA_CH6 DMA_REMAP_TIM16_DMA_CH6
#define HAL_REMAPDMA_TIM17_DMA_CH7 DMA_REMAP_TIM17_DMA_CH7
#define HAL_REMAPDMA_SPI2_DMA_CH67 DMA_REMAP_SPI2_DMA_CH67
#define HAL_REMAPDMA_USART2_DMA_CH67 DMA_REMAP_USART2_DMA_CH67
#define HAL_REMAPDMA_I2C1_DMA_CH76 DMA_REMAP_I2C1_DMA_CH76
#define HAL_REMAPDMA_TIM1_DMA_CH6 DMA_REMAP_TIM1_DMA_CH6
#define HAL_REMAPDMA_TIM2_DMA_CH7 DMA_REMAP_TIM2_DMA_CH7
#define HAL_REMAPDMA_TIM3_DMA_CH6 DMA_REMAP_TIM3_DMA_CH6
#define IS_HAL_REMAPDMA IS_DMA_REMAP
#define __HAL_REMAPDMA_CHANNEL_ENABLE __HAL_DMA_REMAP_CHANNEL_ENABLE
#define __HAL_REMAPDMA_CHANNEL_DISABLE __HAL_DMA_REMAP_CHANNEL_DISABLE
#if defined(STM32L4)
#define HAL_DMAMUX1_REQUEST_GEN_EXTI0 HAL_DMAMUX1_REQ_GEN_EXTI0
#define HAL_DMAMUX1_REQUEST_GEN_EXTI1 HAL_DMAMUX1_REQ_GEN_EXTI1
#define HAL_DMAMUX1_REQUEST_GEN_EXTI2 HAL_DMAMUX1_REQ_GEN_EXTI2
#define HAL_DMAMUX1_REQUEST_GEN_EXTI3 HAL_DMAMUX1_REQ_GEN_EXTI3
#define HAL_DMAMUX1_REQUEST_GEN_EXTI4 HAL_DMAMUX1_REQ_GEN_EXTI4
#define HAL_DMAMUX1_REQUEST_GEN_EXTI5 HAL_DMAMUX1_REQ_GEN_EXTI5
#define HAL_DMAMUX1_REQUEST_GEN_EXTI6 HAL_DMAMUX1_REQ_GEN_EXTI6
#define HAL_DMAMUX1_REQUEST_GEN_EXTI7 HAL_DMAMUX1_REQ_GEN_EXTI7
#define HAL_DMAMUX1_REQUEST_GEN_EXTI8 HAL_DMAMUX1_REQ_GEN_EXTI8
#define HAL_DMAMUX1_REQUEST_GEN_EXTI9 HAL_DMAMUX1_REQ_GEN_EXTI9
#define HAL_DMAMUX1_REQUEST_GEN_EXTI10 HAL_DMAMUX1_REQ_GEN_EXTI10
#define HAL_DMAMUX1_REQUEST_GEN_EXTI11 HAL_DMAMUX1_REQ_GEN_EXTI11
#define HAL_DMAMUX1_REQUEST_GEN_EXTI12 HAL_DMAMUX1_REQ_GEN_EXTI12
#define HAL_DMAMUX1_REQUEST_GEN_EXTI13 HAL_DMAMUX1_REQ_GEN_EXTI13
#define HAL_DMAMUX1_REQUEST_GEN_EXTI14 HAL_DMAMUX1_REQ_GEN_EXTI14
#define HAL_DMAMUX1_REQUEST_GEN_EXTI15 HAL_DMAMUX1_REQ_GEN_EXTI15
#define HAL_DMAMUX1_REQUEST_GEN_DMAMUX1_CH0_EVT HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH0_EVT
#define HAL_DMAMUX1_REQUEST_GEN_DMAMUX1_CH1_EVT HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH1_EVT
#define HAL_DMAMUX1_REQUEST_GEN_DMAMUX1_CH2_EVT HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH2_EVT
#define HAL_DMAMUX1_REQUEST_GEN_DMAMUX1_CH3_EVT HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH3_EVT
#define HAL_DMAMUX1_REQUEST_GEN_LPTIM1_OUT HAL_DMAMUX1_REQ_GEN_LPTIM1_OUT
#define HAL_DMAMUX1_REQUEST_GEN_LPTIM2_OUT HAL_DMAMUX1_REQ_GEN_LPTIM2_OUT
#define HAL_DMAMUX1_REQUEST_GEN_DSI_TE HAL_DMAMUX1_REQ_GEN_DSI_TE
#define HAL_DMAMUX1_REQUEST_GEN_DSI_EOT HAL_DMAMUX1_REQ_GEN_DSI_EOT
#define HAL_DMAMUX1_REQUEST_GEN_DMA2D_EOT HAL_DMAMUX1_REQ_GEN_DMA2D_EOT
#define HAL_DMAMUX1_REQUEST_GEN_LTDC_IT HAL_DMAMUX1_REQ_GEN_LTDC_IT
#define HAL_DMAMUX_REQUEST_GEN_NO_EVENT HAL_DMAMUX_REQ_GEN_NO_EVENT
#define HAL_DMAMUX_REQUEST_GEN_RISING HAL_DMAMUX_REQ_GEN_RISING
#define HAL_DMAMUX_REQUEST_GEN_FALLING HAL_DMAMUX_REQ_GEN_FALLING
#define HAL_DMAMUX_REQUEST_GEN_RISING_FALLING HAL_DMAMUX_REQ_GEN_RISING_FALLING
#if defined(STM32L4R5xx) || defined(STM32L4R9xx) || defined(STM32L4R9xx) || defined(STM32L4S5xx) || \
defined(STM32L4S7xx) || defined(STM32L4S9xx)
#define DMA_REQUEST_DCMI_PSSI DMA_REQUEST_DCMI
#endif
#endif /* STM32L4 */
#if defined(STM32G0)
#define DMA_REQUEST_DAC1_CHANNEL1 DMA_REQUEST_DAC1_CH1
#define DMA_REQUEST_DAC1_CHANNEL2 DMA_REQUEST_DAC1_CH2
#define DMA_REQUEST_TIM16_TRIG_COM DMA_REQUEST_TIM16_COM
#define DMA_REQUEST_TIM17_TRIG_COM DMA_REQUEST_TIM17_COM
#define LL_DMAMUX_REQ_TIM16_TRIG_COM LL_DMAMUX_REQ_TIM16_COM
#define LL_DMAMUX_REQ_TIM17_TRIG_COM LL_DMAMUX_REQ_TIM17_COM
#endif
#if defined(STM32H7)
#define DMA_REQUEST_DAC1 DMA_REQUEST_DAC1_CH1
#define DMA_REQUEST_DAC2 DMA_REQUEST_DAC1_CH2
#define BDMA_REQUEST_LP_UART1_RX BDMA_REQUEST_LPUART1_RX
#define BDMA_REQUEST_LP_UART1_TX BDMA_REQUEST_LPUART1_TX
#define HAL_DMAMUX1_REQUEST_GEN_DMAMUX1_CH0_EVT HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH0_EVT
#define HAL_DMAMUX1_REQUEST_GEN_DMAMUX1_CH1_EVT HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH1_EVT
#define HAL_DMAMUX1_REQUEST_GEN_DMAMUX1_CH2_EVT HAL_DMAMUX1_REQ_GEN_DMAMUX1_CH2_EVT
#define HAL_DMAMUX1_REQUEST_GEN_LPTIM1_OUT HAL_DMAMUX1_REQ_GEN_LPTIM1_OUT
#define HAL_DMAMUX1_REQUEST_GEN_LPTIM2_OUT HAL_DMAMUX1_REQ_GEN_LPTIM2_OUT
#define HAL_DMAMUX1_REQUEST_GEN_LPTIM3_OUT HAL_DMAMUX1_REQ_GEN_LPTIM3_OUT
#define HAL_DMAMUX1_REQUEST_GEN_EXTI0 HAL_DMAMUX1_REQ_GEN_EXTI0
#define HAL_DMAMUX1_REQUEST_GEN_TIM12_TRGO HAL_DMAMUX1_REQ_GEN_TIM12_TRGO
#define HAL_DMAMUX2_REQUEST_GEN_DMAMUX2_CH0_EVT HAL_DMAMUX2_REQ_GEN_DMAMUX2_CH0_EVT
#define HAL_DMAMUX2_REQUEST_GEN_DMAMUX2_CH1_EVT HAL_DMAMUX2_REQ_GEN_DMAMUX2_CH1_EVT
#define HAL_DMAMUX2_REQUEST_GEN_DMAMUX2_CH2_EVT HAL_DMAMUX2_REQ_GEN_DMAMUX2_CH2_EVT
#define HAL_DMAMUX2_REQUEST_GEN_DMAMUX2_CH3_EVT HAL_DMAMUX2_REQ_GEN_DMAMUX2_CH3_EVT
#define HAL_DMAMUX2_REQUEST_GEN_DMAMUX2_CH4_EVT HAL_DMAMUX2_REQ_GEN_DMAMUX2_CH4_EVT
#define HAL_DMAMUX2_REQUEST_GEN_DMAMUX2_CH5_EVT HAL_DMAMUX2_REQ_GEN_DMAMUX2_CH5_EVT
#define HAL_DMAMUX2_REQUEST_GEN_DMAMUX2_CH6_EVT HAL_DMAMUX2_REQ_GEN_DMAMUX2_CH6_EVT
#define HAL_DMAMUX2_REQUEST_GEN_LPUART1_RX_WKUP HAL_DMAMUX2_REQ_GEN_LPUART1_RX_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_LPUART1_TX_WKUP HAL_DMAMUX2_REQ_GEN_LPUART1_TX_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_LPTIM2_WKUP HAL_DMAMUX2_REQ_GEN_LPTIM2_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_LPTIM2_OUT HAL_DMAMUX2_REQ_GEN_LPTIM2_OUT
#define HAL_DMAMUX2_REQUEST_GEN_LPTIM3_WKUP HAL_DMAMUX2_REQ_GEN_LPTIM3_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_LPTIM3_OUT HAL_DMAMUX2_REQ_GEN_LPTIM3_OUT
#define HAL_DMAMUX2_REQUEST_GEN_LPTIM4_WKUP HAL_DMAMUX2_REQ_GEN_LPTIM4_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_LPTIM5_WKUP HAL_DMAMUX2_REQ_GEN_LPTIM5_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_I2C4_WKUP HAL_DMAMUX2_REQ_GEN_I2C4_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_SPI6_WKUP HAL_DMAMUX2_REQ_GEN_SPI6_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_COMP1_OUT HAL_DMAMUX2_REQ_GEN_COMP1_OUT
#define HAL_DMAMUX2_REQUEST_GEN_COMP2_OUT HAL_DMAMUX2_REQ_GEN_COMP2_OUT
#define HAL_DMAMUX2_REQUEST_GEN_RTC_WKUP HAL_DMAMUX2_REQ_GEN_RTC_WKUP
#define HAL_DMAMUX2_REQUEST_GEN_EXTI0 HAL_DMAMUX2_REQ_GEN_EXTI0
#define HAL_DMAMUX2_REQUEST_GEN_EXTI2 HAL_DMAMUX2_REQ_GEN_EXTI2
#define HAL_DMAMUX2_REQUEST_GEN_I2C4_IT_EVT HAL_DMAMUX2_REQ_GEN_I2C4_IT_EVT
#define HAL_DMAMUX2_REQUEST_GEN_SPI6_IT HAL_DMAMUX2_REQ_GEN_SPI6_IT
#define HAL_DMAMUX2_REQUEST_GEN_LPUART1_TX_IT HAL_DMAMUX2_REQ_GEN_LPUART1_TX_IT
#define HAL_DMAMUX2_REQUEST_GEN_LPUART1_RX_IT HAL_DMAMUX2_REQ_GEN_LPUART1_RX_IT
#define HAL_DMAMUX2_REQUEST_GEN_ADC3_IT HAL_DMAMUX2_REQ_GEN_ADC3_IT
#define HAL_DMAMUX2_REQUEST_GEN_ADC3_AWD1_OUT HAL_DMAMUX2_REQ_GEN_ADC3_AWD1_OUT
#define HAL_DMAMUX2_REQUEST_GEN_BDMA_CH0_IT HAL_DMAMUX2_REQ_GEN_BDMA_CH0_IT
#define HAL_DMAMUX2_REQUEST_GEN_BDMA_CH1_IT HAL_DMAMUX2_REQ_GEN_BDMA_CH1_IT
#define HAL_DMAMUX_REQUEST_GEN_NO_EVENT HAL_DMAMUX_REQ_GEN_NO_EVENT
#define HAL_DMAMUX_REQUEST_GEN_RISING HAL_DMAMUX_REQ_GEN_RISING
#define HAL_DMAMUX_REQUEST_GEN_FALLING HAL_DMAMUX_REQ_GEN_FALLING
#define HAL_DMAMUX_REQUEST_GEN_RISING_FALLING HAL_DMAMUX_REQ_GEN_RISING_FALLING
#define DFSDM_FILTER_EXT_TRIG_LPTIM1 DFSDM_FILTER_EXT_TRIG_LPTIM1_OUT
#define DFSDM_FILTER_EXT_TRIG_LPTIM2 DFSDM_FILTER_EXT_TRIG_LPTIM2_OUT
#define DFSDM_FILTER_EXT_TRIG_LPTIM3 DFSDM_FILTER_EXT_TRIG_LPTIM3_OUT
#define DAC_TRIGGER_LP1_OUT DAC_TRIGGER_LPTIM1_OUT
#define DAC_TRIGGER_LP2_OUT DAC_TRIGGER_LPTIM2_OUT
#endif /* STM32H7 */
/**
* @}
*/
/** @defgroup HAL_FLASH_Aliased_Defines HAL FLASH Aliased Defines maintained for legacy purpose
* @{
*/
#define TYPEPROGRAM_BYTE FLASH_TYPEPROGRAM_BYTE
#define TYPEPROGRAM_HALFWORD FLASH_TYPEPROGRAM_HALFWORD
#define TYPEPROGRAM_WORD FLASH_TYPEPROGRAM_WORD
#define TYPEPROGRAM_DOUBLEWORD FLASH_TYPEPROGRAM_DOUBLEWORD
#define TYPEERASE_SECTORS FLASH_TYPEERASE_SECTORS
#define TYPEERASE_PAGES FLASH_TYPEERASE_PAGES
#define TYPEERASE_PAGEERASE FLASH_TYPEERASE_PAGES
#define TYPEERASE_MASSERASE FLASH_TYPEERASE_MASSERASE
#define WRPSTATE_DISABLE OB_WRPSTATE_DISABLE
#define WRPSTATE_ENABLE OB_WRPSTATE_ENABLE
#define HAL_FLASH_TIMEOUT_VALUE FLASH_TIMEOUT_VALUE
#define OBEX_PCROP OPTIONBYTE_PCROP
#define OBEX_BOOTCONFIG OPTIONBYTE_BOOTCONFIG
#define PCROPSTATE_DISABLE OB_PCROP_STATE_DISABLE
#define PCROPSTATE_ENABLE OB_PCROP_STATE_ENABLE
#define TYPEERASEDATA_BYTE FLASH_TYPEERASEDATA_BYTE
#define TYPEERASEDATA_HALFWORD FLASH_TYPEERASEDATA_HALFWORD
#define TYPEERASEDATA_WORD FLASH_TYPEERASEDATA_WORD
#define TYPEPROGRAMDATA_BYTE FLASH_TYPEPROGRAMDATA_BYTE
#define TYPEPROGRAMDATA_HALFWORD FLASH_TYPEPROGRAMDATA_HALFWORD
#define TYPEPROGRAMDATA_WORD FLASH_TYPEPROGRAMDATA_WORD
#define TYPEPROGRAMDATA_FASTBYTE FLASH_TYPEPROGRAMDATA_FASTBYTE
#define TYPEPROGRAMDATA_FASTHALFWORD FLASH_TYPEPROGRAMDATA_FASTHALFWORD
#define TYPEPROGRAMDATA_FASTWORD FLASH_TYPEPROGRAMDATA_FASTWORD
#define PAGESIZE FLASH_PAGE_SIZE
#define TYPEPROGRAM_FASTBYTE FLASH_TYPEPROGRAM_BYTE
#define TYPEPROGRAM_FASTHALFWORD FLASH_TYPEPROGRAM_HALFWORD
#define TYPEPROGRAM_FASTWORD FLASH_TYPEPROGRAM_WORD
#define VOLTAGE_RANGE_1 FLASH_VOLTAGE_RANGE_1
#define VOLTAGE_RANGE_2 FLASH_VOLTAGE_RANGE_2
#define VOLTAGE_RANGE_3 FLASH_VOLTAGE_RANGE_3
#define VOLTAGE_RANGE_4 FLASH_VOLTAGE_RANGE_4
#define TYPEPROGRAM_FAST FLASH_TYPEPROGRAM_FAST
#define TYPEPROGRAM_FAST_AND_LAST FLASH_TYPEPROGRAM_FAST_AND_LAST
#define WRPAREA_BANK1_AREAA OB_WRPAREA_BANK1_AREAA
#define WRPAREA_BANK1_AREAB OB_WRPAREA_BANK1_AREAB
#define WRPAREA_BANK2_AREAA OB_WRPAREA_BANK2_AREAA
#define WRPAREA_BANK2_AREAB OB_WRPAREA_BANK2_AREAB
#define IWDG_STDBY_FREEZE OB_IWDG_STDBY_FREEZE
#define IWDG_STDBY_ACTIVE OB_IWDG_STDBY_RUN
#define IWDG_STOP_FREEZE OB_IWDG_STOP_FREEZE
#define IWDG_STOP_ACTIVE OB_IWDG_STOP_RUN
#define FLASH_ERROR_NONE HAL_FLASH_ERROR_NONE
#define FLASH_ERROR_RD HAL_FLASH_ERROR_RD
#define FLASH_ERROR_PG HAL_FLASH_ERROR_PROG
#define FLASH_ERROR_PGP HAL_FLASH_ERROR_PGS
#define FLASH_ERROR_WRP HAL_FLASH_ERROR_WRP
#define FLASH_ERROR_OPTV HAL_FLASH_ERROR_OPTV
#define FLASH_ERROR_OPTVUSR HAL_FLASH_ERROR_OPTVUSR
#define FLASH_ERROR_PROG HAL_FLASH_ERROR_PROG
#define FLASH_ERROR_OP HAL_FLASH_ERROR_OPERATION
#define FLASH_ERROR_PGA HAL_FLASH_ERROR_PGA
#define FLASH_ERROR_SIZE HAL_FLASH_ERROR_SIZE
#define FLASH_ERROR_SIZ HAL_FLASH_ERROR_SIZE
#define FLASH_ERROR_PGS HAL_FLASH_ERROR_PGS
#define FLASH_ERROR_MIS HAL_FLASH_ERROR_MIS
#define FLASH_ERROR_FAST HAL_FLASH_ERROR_FAST
#define FLASH_ERROR_FWWERR HAL_FLASH_ERROR_FWWERR
#define FLASH_ERROR_NOTZERO HAL_FLASH_ERROR_NOTZERO
#define FLASH_ERROR_OPERATION HAL_FLASH_ERROR_OPERATION
#define FLASH_ERROR_ERS HAL_FLASH_ERROR_ERS
#define OB_WDG_SW OB_IWDG_SW
#define OB_WDG_HW OB_IWDG_HW
#define OB_SDADC12_VDD_MONITOR_SET OB_SDACD_VDD_MONITOR_SET
#define OB_SDADC12_VDD_MONITOR_RESET OB_SDACD_VDD_MONITOR_RESET
#define OB_RAM_PARITY_CHECK_SET OB_SRAM_PARITY_SET
#define OB_RAM_PARITY_CHECK_RESET OB_SRAM_PARITY_RESET
#define IS_OB_SDADC12_VDD_MONITOR IS_OB_SDACD_VDD_MONITOR
#define OB_RDP_LEVEL0 OB_RDP_LEVEL_0
#define OB_RDP_LEVEL1 OB_RDP_LEVEL_1
#define OB_RDP_LEVEL2 OB_RDP_LEVEL_2
#if defined(STM32G0)
#define OB_BOOT_LOCK_DISABLE OB_BOOT_ENTRY_FORCED_NONE
#define OB_BOOT_LOCK_ENABLE OB_BOOT_ENTRY_FORCED_FLASH
#else
#define OB_BOOT_ENTRY_FORCED_NONE OB_BOOT_LOCK_DISABLE
#define OB_BOOT_ENTRY_FORCED_FLASH OB_BOOT_LOCK_ENABLE
#endif
#if defined(STM32H7)
#define FLASH_FLAG_SNECCE_BANK1RR FLASH_FLAG_SNECCERR_BANK1
#define FLASH_FLAG_DBECCE_BANK1RR FLASH_FLAG_DBECCERR_BANK1
#define FLASH_FLAG_STRBER_BANK1R FLASH_FLAG_STRBERR_BANK1
#define FLASH_FLAG_SNECCE_BANK2RR FLASH_FLAG_SNECCERR_BANK2
#define FLASH_FLAG_DBECCE_BANK2RR FLASH_FLAG_DBECCERR_BANK2
#define FLASH_FLAG_STRBER_BANK2R FLASH_FLAG_STRBERR_BANK2
#define FLASH_FLAG_WDW FLASH_FLAG_WBNE
#define OB_WRP_SECTOR_All OB_WRP_SECTOR_ALL
#endif /* STM32H7 */
/**
* @}
*/
/** @defgroup HAL_JPEG_Aliased_Macros HAL JPEG Aliased Macros maintained for legacy purpose
* @{
*/
#if defined(STM32H7)
#define __HAL_RCC_JPEG_CLK_ENABLE __HAL_RCC_JPGDECEN_CLK_ENABLE
#define __HAL_RCC_JPEG_CLK_DISABLE __HAL_RCC_JPGDECEN_CLK_DISABLE
#define __HAL_RCC_JPEG_FORCE_RESET __HAL_RCC_JPGDECRST_FORCE_RESET
#define __HAL_RCC_JPEG_RELEASE_RESET __HAL_RCC_JPGDECRST_RELEASE_RESET
#define __HAL_RCC_JPEG_CLK_SLEEP_ENABLE __HAL_RCC_JPGDEC_CLK_SLEEP_ENABLE
#define __HAL_RCC_JPEG_CLK_SLEEP_DISABLE __HAL_RCC_JPGDEC_CLK_SLEEP_DISABLE
#endif /* STM32H7 */
/**
* @}
*/
/** @defgroup HAL_SYSCFG_Aliased_Defines HAL SYSCFG Aliased Defines maintained for legacy purpose
* @{
*/
#define HAL_SYSCFG_FASTMODEPLUS_I2C_PA9 I2C_FASTMODEPLUS_PA9
#define HAL_SYSCFG_FASTMODEPLUS_I2C_PA10 I2C_FASTMODEPLUS_PA10
#define HAL_SYSCFG_FASTMODEPLUS_I2C_PB6 I2C_FASTMODEPLUS_PB6
#define HAL_SYSCFG_FASTMODEPLUS_I2C_PB7 I2C_FASTMODEPLUS_PB7
#define HAL_SYSCFG_FASTMODEPLUS_I2C_PB8 I2C_FASTMODEPLUS_PB8
#define HAL_SYSCFG_FASTMODEPLUS_I2C_PB9 I2C_FASTMODEPLUS_PB9
#define HAL_SYSCFG_FASTMODEPLUS_I2C1 I2C_FASTMODEPLUS_I2C1
#define HAL_SYSCFG_FASTMODEPLUS_I2C2 I2C_FASTMODEPLUS_I2C2
#define HAL_SYSCFG_FASTMODEPLUS_I2C3 I2C_FASTMODEPLUS_I2C3
#if defined(STM32G4)
#define HAL_SYSCFG_EnableIOAnalogSwitchBooster HAL_SYSCFG_EnableIOSwitchBooster
#define HAL_SYSCFG_DisableIOAnalogSwitchBooster HAL_SYSCFG_DisableIOSwitchBooster
#define HAL_SYSCFG_EnableIOAnalogSwitchVDD HAL_SYSCFG_EnableIOSwitchVDD
#define HAL_SYSCFG_DisableIOAnalogSwitchVDD HAL_SYSCFG_DisableIOSwitchVDD
#endif /* STM32G4 */
/**
* @}
*/
/** @defgroup LL_FMC_Aliased_Defines LL FMC Aliased Defines maintained for compatibility purpose
* @{
*/
#if defined(STM32L4) || defined(STM32F7) || defined(STM32H7) || defined(STM32G4)
#define FMC_NAND_PCC_WAIT_FEATURE_DISABLE FMC_NAND_WAIT_FEATURE_DISABLE
#define FMC_NAND_PCC_WAIT_FEATURE_ENABLE FMC_NAND_WAIT_FEATURE_ENABLE
#define FMC_NAND_PCC_MEM_BUS_WIDTH_8 FMC_NAND_MEM_BUS_WIDTH_8
#define FMC_NAND_PCC_MEM_BUS_WIDTH_16 FMC_NAND_MEM_BUS_WIDTH_16
#elif defined(STM32F1) || defined(STM32F2) || defined(STM32F3) || defined(STM32F4)
#define FMC_NAND_WAIT_FEATURE_DISABLE FMC_NAND_PCC_WAIT_FEATURE_DISABLE
#define FMC_NAND_WAIT_FEATURE_ENABLE FMC_NAND_PCC_WAIT_FEATURE_ENABLE
#define FMC_NAND_MEM_BUS_WIDTH_8 FMC_NAND_PCC_MEM_BUS_WIDTH_8
#define FMC_NAND_MEM_BUS_WIDTH_16 FMC_NAND_PCC_MEM_BUS_WIDTH_16
#endif
/**
* @}
*/
/** @defgroup LL_FSMC_Aliased_Defines LL FSMC Aliased Defines maintained for legacy purpose
* @{
*/
#define FSMC_NORSRAM_TYPEDEF FSMC_NORSRAM_TypeDef
#define FSMC_NORSRAM_EXTENDED_TYPEDEF FSMC_NORSRAM_EXTENDED_TypeDef
/**
* @}
*/
/** @defgroup HAL_GPIO_Aliased_Macros HAL GPIO Aliased Macros maintained for legacy purpose
* @{
*/
#define GET_GPIO_SOURCE GPIO_GET_INDEX
#define GET_GPIO_INDEX GPIO_GET_INDEX
#if defined(STM32F4)
#define GPIO_AF12_SDMMC GPIO_AF12_SDIO
#define GPIO_AF12_SDMMC1 GPIO_AF12_SDIO
#endif
#if defined(STM32F7)
#define GPIO_AF12_SDIO GPIO_AF12_SDMMC1
#define GPIO_AF12_SDMMC GPIO_AF12_SDMMC1
#endif
#if defined(STM32L4)
#define GPIO_AF12_SDIO GPIO_AF12_SDMMC1
#define GPIO_AF12_SDMMC GPIO_AF12_SDMMC1
#endif
#if defined(STM32H7)
#define GPIO_AF7_SDIO1 GPIO_AF7_SDMMC1
#define GPIO_AF8_SDIO1 GPIO_AF8_SDMMC1
#define GPIO_AF12_SDIO1 GPIO_AF12_SDMMC1
#define GPIO_AF9_SDIO2 GPIO_AF9_SDMMC2
#define GPIO_AF10_SDIO2 GPIO_AF10_SDMMC2
#define GPIO_AF11_SDIO2 GPIO_AF11_SDMMC2
#if defined (STM32H743xx) || defined (STM32H753xx) || defined (STM32H750xx) || defined (STM32H742xx) || \
defined (STM32H745xx) || defined (STM32H755xx) || defined (STM32H747xx) || defined (STM32H757xx)
#define GPIO_AF10_OTG2_HS GPIO_AF10_OTG2_FS
#define GPIO_AF10_OTG1_FS GPIO_AF10_OTG1_HS
#define GPIO_AF12_OTG2_FS GPIO_AF12_OTG1_FS
#endif /*STM32H743xx || STM32H753xx || STM32H750xx || STM32H742xx || STM32H745xx || STM32H755xx || STM32H747xx || \
STM32H757xx */
#endif /* STM32H7 */
#define GPIO_AF0_LPTIM GPIO_AF0_LPTIM1
#define GPIO_AF1_LPTIM GPIO_AF1_LPTIM1
#define GPIO_AF2_LPTIM GPIO_AF2_LPTIM1
#if defined(STM32L0) || defined(STM32L4) || defined(STM32F4) || defined(STM32F2) || defined(STM32F7) || defined(STM32G4) || defined(STM32H7) || defined(STM32WB)
#define GPIO_SPEED_LOW GPIO_SPEED_FREQ_LOW
#define GPIO_SPEED_MEDIUM GPIO_SPEED_FREQ_MEDIUM
#define GPIO_SPEED_FAST GPIO_SPEED_FREQ_HIGH
#define GPIO_SPEED_HIGH GPIO_SPEED_FREQ_VERY_HIGH
#endif /* STM32L0 || STM32L4 || STM32F4 || STM32F2 || STM32F7 || STM32G4 || STM32H7 || STM32WB */
#if defined(STM32L1)
#define GPIO_SPEED_VERY_LOW GPIO_SPEED_FREQ_LOW
#define GPIO_SPEED_LOW GPIO_SPEED_FREQ_MEDIUM
#define GPIO_SPEED_MEDIUM GPIO_SPEED_FREQ_HIGH
#define GPIO_SPEED_HIGH GPIO_SPEED_FREQ_VERY_HIGH
#endif /* STM32L1 */
#if defined(STM32F0) || defined(STM32F3) || defined(STM32F1)
#define GPIO_SPEED_LOW GPIO_SPEED_FREQ_LOW
#define GPIO_SPEED_MEDIUM GPIO_SPEED_FREQ_MEDIUM
#define GPIO_SPEED_HIGH GPIO_SPEED_FREQ_HIGH
#endif /* STM32F0 || STM32F3 || STM32F1 */
#define GPIO_AF6_DFSDM GPIO_AF6_DFSDM1
/**
* @}
*/
/** @defgroup HAL_GTZC_Aliased_Defines HAL GTZC Aliased Defines maintained for legacy purpose
* @{
*/
/**
* @}
*/
/** @defgroup HAL_HRTIM_Aliased_Macros HAL HRTIM Aliased Macros maintained for legacy purpose
* @{
*/
#define HRTIM_TIMDELAYEDPROTECTION_DISABLED HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DISABLED
#define HRTIM_TIMDELAYEDPROTECTION_DELAYEDOUT1_EEV68 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT1_EEV6
#define HRTIM_TIMDELAYEDPROTECTION_DELAYEDOUT2_EEV68 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT2_EEV6
#define HRTIM_TIMDELAYEDPROTECTION_DELAYEDBOTH_EEV68 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDBOTH_EEV6
#define HRTIM_TIMDELAYEDPROTECTION_BALANCED_EEV68 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_BALANCED_EEV6
#define HRTIM_TIMDELAYEDPROTECTION_DELAYEDOUT1_DEEV79 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT1_DEEV7
#define HRTIM_TIMDELAYEDPROTECTION_DELAYEDOUT2_DEEV79 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT2_DEEV7
#define HRTIM_TIMDELAYEDPROTECTION_DELAYEDBOTH_EEV79 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDBOTH_EEV7
#define HRTIM_TIMDELAYEDPROTECTION_BALANCED_EEV79 HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_BALANCED_EEV7
#define __HAL_HRTIM_SetCounter __HAL_HRTIM_SETCOUNTER
#define __HAL_HRTIM_GetCounter __HAL_HRTIM_GETCOUNTER
#define __HAL_HRTIM_SetPeriod __HAL_HRTIM_SETPERIOD
#define __HAL_HRTIM_GetPeriod __HAL_HRTIM_GETPERIOD
#define __HAL_HRTIM_SetClockPrescaler __HAL_HRTIM_SETCLOCKPRESCALER
#define __HAL_HRTIM_GetClockPrescaler __HAL_HRTIM_GETCLOCKPRESCALER
#define __HAL_HRTIM_SetCompare __HAL_HRTIM_SETCOMPARE
#define __HAL_HRTIM_GetCompare __HAL_HRTIM_GETCOMPARE
#if defined(STM32G4)
#define HAL_HRTIM_ExternalEventCounterConfig HAL_HRTIM_ExtEventCounterConfig
#define HAL_HRTIM_ExternalEventCounterEnable HAL_HRTIM_ExtEventCounterEnable
#define HAL_HRTIM_ExternalEventCounterDisable HAL_HRTIM_ExtEventCounterDisable
#define HAL_HRTIM_ExternalEventCounterReset HAL_HRTIM_ExtEventCounterReset
#define HRTIM_TIMEEVENT_A HRTIM_EVENTCOUNTER_A
#define HRTIM_TIMEEVENT_B HRTIM_EVENTCOUNTER_B
#define HRTIM_TIMEEVENTRESETMODE_UNCONDITIONAL HRTIM_EVENTCOUNTER_RSTMODE_UNCONDITIONAL
#define HRTIM_TIMEEVENTRESETMODE_CONDITIONAL HRTIM_EVENTCOUNTER_RSTMODE_CONDITIONAL
#endif /* STM32G4 */
#if defined(STM32H7)
#define HRTIM_OUTPUTSET_TIMAEV1_TIMBCMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTSET_TIMAEV2_TIMBCMP2 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTSET_TIMAEV3_TIMCCMP2 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTSET_TIMAEV4_TIMCCMP3 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTSET_TIMAEV5_TIMDCMP1 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTSET_TIMAEV6_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTSET_TIMAEV7_TIMECMP3 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTSET_TIMAEV8_TIMECMP4 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTSET_TIMAEV9_TIMFCMP4 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTSET_TIMBEV1_TIMACMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTSET_TIMBEV2_TIMACMP2 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTSET_TIMBEV3_TIMCCMP3 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTSET_TIMBEV4_TIMCCMP4 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTSET_TIMBEV5_TIMDCMP3 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTSET_TIMBEV6_TIMDCMP4 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTSET_TIMBEV7_TIMECMP1 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTSET_TIMBEV8_TIMECMP2 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTSET_TIMBEV9_TIMFCMP3 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTSET_TIMCEV1_TIMACMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTSET_TIMCEV2_TIMACMP2 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTSET_TIMCEV3_TIMBCMP2 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTSET_TIMCEV4_TIMBCMP3 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTSET_TIMCEV5_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTSET_TIMCEV6_TIMDCMP4 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTSET_TIMCEV7_TIMECMP3 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTSET_TIMCEV8_TIMECMP4 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTSET_TIMCEV9_TIMFCMP2 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTSET_TIMDEV1_TIMACMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTSET_TIMDEV2_TIMACMP4 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTSET_TIMDEV3_TIMBCMP2 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTSET_TIMDEV4_TIMBCMP4 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTSET_TIMDEV5_TIMCCMP4 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTSET_TIMDEV6_TIMECMP1 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTSET_TIMDEV7_TIMECMP4 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTSET_TIMDEV8_TIMFCMP1 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTSET_TIMDEV9_TIMFCMP3 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTSET_TIMEEV1_TIMACMP4 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTSET_TIMEEV2_TIMBCMP3 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTSET_TIMEEV3_TIMBCMP4 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTSET_TIMEEV4_TIMCCMP1 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTSET_TIMEEV5_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTSET_TIMEEV6_TIMDCMP1 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTSET_TIMEEV7_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTSET_TIMEEV8_TIMFCMP3 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTSET_TIMEEV9_TIMFCMP4 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTSET_TIMFEV1_TIMACMP3 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTSET_TIMFEV2_TIMBCMP1 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTSET_TIMFEV3_TIMBCMP4 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTSET_TIMFEV4_TIMCCMP1 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTSET_TIMFEV5_TIMCCMP4 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTSET_TIMFEV6_TIMDCMP3 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTSET_TIMFEV7_TIMDCMP4 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTSET_TIMFEV8_TIMECMP2 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTSET_TIMFEV9_TIMECMP3 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTRESET_TIMAEV1_TIMBCMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTRESET_TIMAEV2_TIMBCMP2 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTRESET_TIMAEV3_TIMCCMP2 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTRESET_TIMAEV4_TIMCCMP3 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTRESET_TIMAEV5_TIMDCMP1 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTRESET_TIMAEV6_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTRESET_TIMAEV7_TIMECMP3 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTRESET_TIMAEV8_TIMECMP4 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTRESET_TIMAEV9_TIMFCMP4 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTRESET_TIMBEV1_TIMACMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTRESET_TIMBEV2_TIMACMP2 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTRESET_TIMBEV3_TIMCCMP3 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTRESET_TIMBEV4_TIMCCMP4 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTRESET_TIMBEV5_TIMDCMP3 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTRESET_TIMBEV6_TIMDCMP4 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTRESET_TIMBEV7_TIMECMP1 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTRESET_TIMBEV8_TIMECMP2 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTRESET_TIMBEV9_TIMFCMP3 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTRESET_TIMCEV1_TIMACMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTRESET_TIMCEV2_TIMACMP2 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTRESET_TIMCEV3_TIMBCMP2 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTRESET_TIMCEV4_TIMBCMP3 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTRESET_TIMCEV5_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTRESET_TIMCEV6_TIMDCMP4 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTRESET_TIMCEV7_TIMECMP3 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTRESET_TIMCEV8_TIMECMP4 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTRESET_TIMCEV9_TIMFCMP2 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTRESET_TIMDEV1_TIMACMP1 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTRESET_TIMDEV2_TIMACMP4 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTRESET_TIMDEV3_TIMBCMP2 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTRESET_TIMDEV4_TIMBCMP4 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTRESET_TIMDEV5_TIMCCMP4 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTRESET_TIMDEV6_TIMECMP1 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTRESET_TIMDEV7_TIMECMP4 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTRESET_TIMDEV8_TIMFCMP1 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTRESET_TIMDEV9_TIMFCMP3 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTRESET_TIMEEV1_TIMACMP4 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTRESET_TIMEEV2_TIMBCMP3 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTRESET_TIMEEV3_TIMBCMP4 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTRESET_TIMEEV4_TIMCCMP1 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTRESET_TIMEEV5_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTRESET_TIMEEV6_TIMDCMP1 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTRESET_TIMEEV7_TIMDCMP2 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTRESET_TIMEEV8_TIMFCMP3 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTRESET_TIMEEV9_TIMFCMP4 HRTIM_OUTPUTSET_TIMEV_9
#define HRTIM_OUTPUTRESET_TIMFEV1_TIMACMP3 HRTIM_OUTPUTSET_TIMEV_1
#define HRTIM_OUTPUTRESET_TIMFEV2_TIMBCMP1 HRTIM_OUTPUTSET_TIMEV_2
#define HRTIM_OUTPUTRESET_TIMFEV3_TIMBCMP4 HRTIM_OUTPUTSET_TIMEV_3
#define HRTIM_OUTPUTRESET_TIMFEV4_TIMCCMP1 HRTIM_OUTPUTSET_TIMEV_4
#define HRTIM_OUTPUTRESET_TIMFEV5_TIMCCMP4 HRTIM_OUTPUTSET_TIMEV_5
#define HRTIM_OUTPUTRESET_TIMFEV6_TIMDCMP3 HRTIM_OUTPUTSET_TIMEV_6
#define HRTIM_OUTPUTRESET_TIMFEV7_TIMDCMP4 HRTIM_OUTPUTSET_TIMEV_7
#define HRTIM_OUTPUTRESET_TIMFEV8_TIMECMP2 HRTIM_OUTPUTSET_TIMEV_8
#define HRTIM_OUTPUTRESET_TIMFEV9_TIMECMP3 HRTIM_OUTPUTSET_TIMEV_9
#endif /* STM32H7 */
#if defined(STM32F3)
/** @brief Constants defining available sources associated to external events.
*/
#define HRTIM_EVENTSRC_1 (0x00000000U)
#define HRTIM_EVENTSRC_2 (HRTIM_EECR1_EE1SRC_0)
#define HRTIM_EVENTSRC_3 (HRTIM_EECR1_EE1SRC_1)
#define HRTIM_EVENTSRC_4 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0)
/** @brief Constants defining the DLL calibration periods (in micro seconds)
*/
#define HRTIM_CALIBRATIONRATE_7300 0x00000000U
#define HRTIM_CALIBRATIONRATE_910 (HRTIM_DLLCR_CALRTE_0)
#define HRTIM_CALIBRATIONRATE_114 (HRTIM_DLLCR_CALRTE_1)
#define HRTIM_CALIBRATIONRATE_14 (HRTIM_DLLCR_CALRTE_1 | HRTIM_DLLCR_CALRTE_0)
#endif /* STM32F3 */
/**
* @}
*/
/** @defgroup HAL_I2C_Aliased_Defines HAL I2C Aliased Defines maintained for legacy purpose
* @{
*/
#define I2C_DUALADDRESS_DISABLED I2C_DUALADDRESS_DISABLE
#define I2C_DUALADDRESS_ENABLED I2C_DUALADDRESS_ENABLE
#define I2C_GENERALCALL_DISABLED I2C_GENERALCALL_DISABLE
#define I2C_GENERALCALL_ENABLED I2C_GENERALCALL_ENABLE
#define I2C_NOSTRETCH_DISABLED I2C_NOSTRETCH_DISABLE
#define I2C_NOSTRETCH_ENABLED I2C_NOSTRETCH_ENABLE
#define I2C_ANALOGFILTER_ENABLED I2C_ANALOGFILTER_ENABLE
#define I2C_ANALOGFILTER_DISABLED I2C_ANALOGFILTER_DISABLE
#if defined(STM32F0) || defined(STM32F1) || defined(STM32F3) || defined(STM32G0) || defined(STM32L4) || \
defined(STM32L1) || defined(STM32F7)
#define HAL_I2C_STATE_MEM_BUSY_TX HAL_I2C_STATE_BUSY_TX
#define HAL_I2C_STATE_MEM_BUSY_RX HAL_I2C_STATE_BUSY_RX
#define HAL_I2C_STATE_MASTER_BUSY_TX HAL_I2C_STATE_BUSY_TX
#define HAL_I2C_STATE_MASTER_BUSY_RX HAL_I2C_STATE_BUSY_RX
#define HAL_I2C_STATE_SLAVE_BUSY_TX HAL_I2C_STATE_BUSY_TX
#define HAL_I2C_STATE_SLAVE_BUSY_RX HAL_I2C_STATE_BUSY_RX
#endif
/**
* @}
*/
/** @defgroup HAL_IRDA_Aliased_Defines HAL IRDA Aliased Defines maintained for legacy purpose
* @{
*/
#define IRDA_ONE_BIT_SAMPLE_DISABLED IRDA_ONE_BIT_SAMPLE_DISABLE
#define IRDA_ONE_BIT_SAMPLE_ENABLED IRDA_ONE_BIT_SAMPLE_ENABLE
/**
* @}
*/
/** @defgroup HAL_IWDG_Aliased_Defines HAL IWDG Aliased Defines maintained for legacy purpose
* @{
*/
#define KR_KEY_RELOAD IWDG_KEY_RELOAD
#define KR_KEY_ENABLE IWDG_KEY_ENABLE
#define KR_KEY_EWA IWDG_KEY_WRITE_ACCESS_ENABLE
#define KR_KEY_DWA IWDG_KEY_WRITE_ACCESS_DISABLE
/**
* @}
*/
/** @defgroup HAL_LPTIM_Aliased_Defines HAL LPTIM Aliased Defines maintained for legacy purpose
* @{
*/
#define LPTIM_CLOCKSAMPLETIME_DIRECTTRANSISTION LPTIM_CLOCKSAMPLETIME_DIRECTTRANSITION
#define LPTIM_CLOCKSAMPLETIME_2TRANSISTIONS LPTIM_CLOCKSAMPLETIME_2TRANSITIONS
#define LPTIM_CLOCKSAMPLETIME_4TRANSISTIONS LPTIM_CLOCKSAMPLETIME_4TRANSITIONS
#define LPTIM_CLOCKSAMPLETIME_8TRANSISTIONS LPTIM_CLOCKSAMPLETIME_8TRANSITIONS
#define LPTIM_CLOCKPOLARITY_RISINGEDGE LPTIM_CLOCKPOLARITY_RISING
#define LPTIM_CLOCKPOLARITY_FALLINGEDGE LPTIM_CLOCKPOLARITY_FALLING
#define LPTIM_CLOCKPOLARITY_BOTHEDGES LPTIM_CLOCKPOLARITY_RISING_FALLING
#define LPTIM_TRIGSAMPLETIME_DIRECTTRANSISTION LPTIM_TRIGSAMPLETIME_DIRECTTRANSITION
#define LPTIM_TRIGSAMPLETIME_2TRANSISTIONS LPTIM_TRIGSAMPLETIME_2TRANSITIONS
#define LPTIM_TRIGSAMPLETIME_4TRANSISTIONS LPTIM_TRIGSAMPLETIME_4TRANSITIONS
#define LPTIM_TRIGSAMPLETIME_8TRANSISTIONS LPTIM_TRIGSAMPLETIME_8TRANSITIONS
/* The following 3 definition have also been present in a temporary version of lptim.h */
/* They need to be renamed also to the right name, just in case */
#define LPTIM_TRIGSAMPLETIME_2TRANSITION LPTIM_TRIGSAMPLETIME_2TRANSITIONS
#define LPTIM_TRIGSAMPLETIME_4TRANSITION LPTIM_TRIGSAMPLETIME_4TRANSITIONS
#define LPTIM_TRIGSAMPLETIME_8TRANSITION LPTIM_TRIGSAMPLETIME_8TRANSITIONS
/** @defgroup HAL_LPTIM_Aliased_Defines HAL LPTIM Aliased Defines maintained for legacy purpose
* @{
*/
#define HAL_LPTIM_ReadCompare HAL_LPTIM_ReadCapturedValue
/**
* @}
*/
/**
* @}
*/
/** @defgroup HAL_NAND_Aliased_Defines HAL NAND Aliased Defines maintained for legacy purpose
* @{
*/
#define HAL_NAND_Read_Page HAL_NAND_Read_Page_8b
#define HAL_NAND_Write_Page HAL_NAND_Write_Page_8b
#define HAL_NAND_Read_SpareArea HAL_NAND_Read_SpareArea_8b
#define HAL_NAND_Write_SpareArea HAL_NAND_Write_SpareArea_8b
#define NAND_AddressTypedef NAND_AddressTypeDef
#define __ARRAY_ADDRESS ARRAY_ADDRESS
#define __ADDR_1st_CYCLE ADDR_1ST_CYCLE
#define __ADDR_2nd_CYCLE ADDR_2ND_CYCLE
#define __ADDR_3rd_CYCLE ADDR_3RD_CYCLE
#define __ADDR_4th_CYCLE ADDR_4TH_CYCLE
/**
* @}
*/
/** @defgroup HAL_NOR_Aliased_Defines HAL NOR Aliased Defines maintained for legacy purpose
* @{
*/
#define NOR_StatusTypedef HAL_NOR_StatusTypeDef
#define NOR_SUCCESS HAL_NOR_STATUS_SUCCESS
#define NOR_ONGOING HAL_NOR_STATUS_ONGOING
#define NOR_ERROR HAL_NOR_STATUS_ERROR
#define NOR_TIMEOUT HAL_NOR_STATUS_TIMEOUT
#define __NOR_WRITE NOR_WRITE
#define __NOR_ADDR_SHIFT NOR_ADDR_SHIFT
/**
* @}
*/
/** @defgroup HAL_OPAMP_Aliased_Defines HAL OPAMP Aliased Defines maintained for legacy purpose
* @{
*/
#define OPAMP_NONINVERTINGINPUT_VP0 OPAMP_NONINVERTINGINPUT_IO0
#define OPAMP_NONINVERTINGINPUT_VP1 OPAMP_NONINVERTINGINPUT_IO1
#define OPAMP_NONINVERTINGINPUT_VP2 OPAMP_NONINVERTINGINPUT_IO2
#define OPAMP_NONINVERTINGINPUT_VP3 OPAMP_NONINVERTINGINPUT_IO3
#define OPAMP_SEC_NONINVERTINGINPUT_VP0 OPAMP_SEC_NONINVERTINGINPUT_IO0
#define OPAMP_SEC_NONINVERTINGINPUT_VP1 OPAMP_SEC_NONINVERTINGINPUT_IO1
#define OPAMP_SEC_NONINVERTINGINPUT_VP2 OPAMP_SEC_NONINVERTINGINPUT_IO2
#define OPAMP_SEC_NONINVERTINGINPUT_VP3 OPAMP_SEC_NONINVERTINGINPUT_IO3
#define OPAMP_INVERTINGINPUT_VM0 OPAMP_INVERTINGINPUT_IO0
#define OPAMP_INVERTINGINPUT_VM1 OPAMP_INVERTINGINPUT_IO1
#define IOPAMP_INVERTINGINPUT_VM0 OPAMP_INVERTINGINPUT_IO0
#define IOPAMP_INVERTINGINPUT_VM1 OPAMP_INVERTINGINPUT_IO1
#define OPAMP_SEC_INVERTINGINPUT_VM0 OPAMP_SEC_INVERTINGINPUT_IO0
#define OPAMP_SEC_INVERTINGINPUT_VM1 OPAMP_SEC_INVERTINGINPUT_IO1
#define OPAMP_INVERTINGINPUT_VINM OPAMP_SEC_INVERTINGINPUT_IO1
#define OPAMP_PGACONNECT_NO OPAMP_PGA_CONNECT_INVERTINGINPUT_NO
#define OPAMP_PGACONNECT_VM0 OPAMP_PGA_CONNECT_INVERTINGINPUT_IO0
#define OPAMP_PGACONNECT_VM1 OPAMP_PGA_CONNECT_INVERTINGINPUT_IO1
#if defined(STM32L1) || defined(STM32L4) || defined(STM32L5) || defined(STM32H7) || defined(STM32G4)
#define HAL_OPAMP_MSP_INIT_CB_ID HAL_OPAMP_MSPINIT_CB_ID
#define HAL_OPAMP_MSP_DEINIT_CB_ID HAL_OPAMP_MSPDEINIT_CB_ID
#endif
#if defined(STM32L4) || defined(STM32L5)
#define OPAMP_POWERMODE_NORMAL OPAMP_POWERMODE_NORMALPOWER
#elif defined(STM32G4)
#define OPAMP_POWERMODE_NORMAL OPAMP_POWERMODE_NORMALSPEED
#endif
/**
* @}
*/
/** @defgroup HAL_I2S_Aliased_Defines HAL I2S Aliased Defines maintained for legacy purpose
* @{
*/
#define I2S_STANDARD_PHILLIPS I2S_STANDARD_PHILIPS
#if defined(STM32H7)
#define I2S_IT_TXE I2S_IT_TXP
#define I2S_IT_RXNE I2S_IT_RXP
#define I2S_FLAG_TXE I2S_FLAG_TXP
#define I2S_FLAG_RXNE I2S_FLAG_RXP
#endif
#if defined(STM32F7)
#define I2S_CLOCK_SYSCLK I2S_CLOCK_PLL
#endif
/**
* @}
*/
/** @defgroup HAL_PCCARD_Aliased_Defines HAL PCCARD Aliased Defines maintained for legacy purpose
* @{
*/
/* Compact Flash-ATA registers description */
#define CF_DATA ATA_DATA
#define CF_SECTOR_COUNT ATA_SECTOR_COUNT
#define CF_SECTOR_NUMBER ATA_SECTOR_NUMBER
#define CF_CYLINDER_LOW ATA_CYLINDER_LOW
#define CF_CYLINDER_HIGH ATA_CYLINDER_HIGH
#define CF_CARD_HEAD ATA_CARD_HEAD
#define CF_STATUS_CMD ATA_STATUS_CMD
#define CF_STATUS_CMD_ALTERNATE ATA_STATUS_CMD_ALTERNATE
#define CF_COMMON_DATA_AREA ATA_COMMON_DATA_AREA
/* Compact Flash-ATA commands */
#define CF_READ_SECTOR_CMD ATA_READ_SECTOR_CMD
#define CF_WRITE_SECTOR_CMD ATA_WRITE_SECTOR_CMD
#define CF_ERASE_SECTOR_CMD ATA_ERASE_SECTOR_CMD
#define CF_IDENTIFY_CMD ATA_IDENTIFY_CMD
#define PCCARD_StatusTypedef HAL_PCCARD_StatusTypeDef
#define PCCARD_SUCCESS HAL_PCCARD_STATUS_SUCCESS
#define PCCARD_ONGOING HAL_PCCARD_STATUS_ONGOING
#define PCCARD_ERROR HAL_PCCARD_STATUS_ERROR
#define PCCARD_TIMEOUT HAL_PCCARD_STATUS_TIMEOUT
/**
* @}
*/
/** @defgroup HAL_RTC_Aliased_Defines HAL RTC Aliased Defines maintained for legacy purpose
* @{
*/
#define FORMAT_BIN RTC_FORMAT_BIN
#define FORMAT_BCD RTC_FORMAT_BCD
#define RTC_ALARMSUBSECONDMASK_None RTC_ALARMSUBSECONDMASK_NONE
#define RTC_TAMPERERASEBACKUP_DISABLED RTC_TAMPER_ERASE_BACKUP_DISABLE
#define RTC_TAMPERMASK_FLAG_DISABLED RTC_TAMPERMASK_FLAG_DISABLE
#define RTC_TAMPERMASK_FLAG_ENABLED RTC_TAMPERMASK_FLAG_ENABLE
#define RTC_MASKTAMPERFLAG_DISABLED RTC_TAMPERMASK_FLAG_DISABLE
#define RTC_MASKTAMPERFLAG_ENABLED RTC_TAMPERMASK_FLAG_ENABLE
#define RTC_TAMPERERASEBACKUP_ENABLED RTC_TAMPER_ERASE_BACKUP_ENABLE
#define RTC_TAMPER1_2_INTERRUPT RTC_ALL_TAMPER_INTERRUPT
#define RTC_TAMPER1_2_3_INTERRUPT RTC_ALL_TAMPER_INTERRUPT
#define RTC_TIMESTAMPPIN_PC13 RTC_TIMESTAMPPIN_DEFAULT
#define RTC_TIMESTAMPPIN_PA0 RTC_TIMESTAMPPIN_POS1
#define RTC_TIMESTAMPPIN_PI8 RTC_TIMESTAMPPIN_POS1
#define RTC_TIMESTAMPPIN_PC1 RTC_TIMESTAMPPIN_POS2
#define RTC_OUTPUT_REMAP_PC13 RTC_OUTPUT_REMAP_NONE
#define RTC_OUTPUT_REMAP_PB14 RTC_OUTPUT_REMAP_POS1
#define RTC_OUTPUT_REMAP_PB2 RTC_OUTPUT_REMAP_POS1
#define RTC_TAMPERPIN_PC13 RTC_TAMPERPIN_DEFAULT
#define RTC_TAMPERPIN_PA0 RTC_TAMPERPIN_POS1
#define RTC_TAMPERPIN_PI8 RTC_TAMPERPIN_POS1
#if defined(STM32F7)
#define RTC_TAMPCR_TAMPXE RTC_TAMPER_ENABLE_BITS_MASK
#define RTC_TAMPCR_TAMPXIE RTC_TAMPER_IT_ENABLE_BITS_MASK
#endif /* STM32F7 */
#if defined(STM32H7)
#define RTC_TAMPCR_TAMPXE RTC_TAMPER_X
#define RTC_TAMPCR_TAMPXIE RTC_TAMPER_X_INTERRUPT
#endif /* STM32H7 */
#if defined(STM32F7) || defined(STM32H7) || defined(STM32L0)
#define RTC_TAMPER1_INTERRUPT RTC_IT_TAMP1
#define RTC_TAMPER2_INTERRUPT RTC_IT_TAMP2
#define RTC_TAMPER3_INTERRUPT RTC_IT_TAMP3
#define RTC_ALL_TAMPER_INTERRUPT RTC_IT_TAMP
#endif /* STM32F7 || STM32H7 || STM32L0 */
/**
* @}
*/
/** @defgroup HAL_SMARTCARD_Aliased_Defines HAL SMARTCARD Aliased Defines maintained for legacy purpose
* @{
*/
#define SMARTCARD_NACK_ENABLED SMARTCARD_NACK_ENABLE
#define SMARTCARD_NACK_DISABLED SMARTCARD_NACK_DISABLE
#define SMARTCARD_ONEBIT_SAMPLING_DISABLED SMARTCARD_ONE_BIT_SAMPLE_DISABLE
#define SMARTCARD_ONEBIT_SAMPLING_ENABLED SMARTCARD_ONE_BIT_SAMPLE_ENABLE
#define SMARTCARD_ONEBIT_SAMPLING_DISABLE SMARTCARD_ONE_BIT_SAMPLE_DISABLE
#define SMARTCARD_ONEBIT_SAMPLING_ENABLE SMARTCARD_ONE_BIT_SAMPLE_ENABLE
#define SMARTCARD_TIMEOUT_DISABLED SMARTCARD_TIMEOUT_DISABLE
#define SMARTCARD_TIMEOUT_ENABLED SMARTCARD_TIMEOUT_ENABLE
#define SMARTCARD_LASTBIT_DISABLED SMARTCARD_LASTBIT_DISABLE
#define SMARTCARD_LASTBIT_ENABLED SMARTCARD_LASTBIT_ENABLE
/**
* @}
*/
/** @defgroup HAL_SMBUS_Aliased_Defines HAL SMBUS Aliased Defines maintained for legacy purpose
* @{
*/
#define SMBUS_DUALADDRESS_DISABLED SMBUS_DUALADDRESS_DISABLE
#define SMBUS_DUALADDRESS_ENABLED SMBUS_DUALADDRESS_ENABLE
#define SMBUS_GENERALCALL_DISABLED SMBUS_GENERALCALL_DISABLE
#define SMBUS_GENERALCALL_ENABLED SMBUS_GENERALCALL_ENABLE
#define SMBUS_NOSTRETCH_DISABLED SMBUS_NOSTRETCH_DISABLE
#define SMBUS_NOSTRETCH_ENABLED SMBUS_NOSTRETCH_ENABLE
#define SMBUS_ANALOGFILTER_ENABLED SMBUS_ANALOGFILTER_ENABLE
#define SMBUS_ANALOGFILTER_DISABLED SMBUS_ANALOGFILTER_DISABLE
#define SMBUS_PEC_DISABLED SMBUS_PEC_DISABLE
#define SMBUS_PEC_ENABLED SMBUS_PEC_ENABLE
#define HAL_SMBUS_STATE_SLAVE_LISTEN HAL_SMBUS_STATE_LISTEN
/**
* @}
*/
/** @defgroup HAL_SPI_Aliased_Defines HAL SPI Aliased Defines maintained for legacy purpose
* @{
*/
#define SPI_TIMODE_DISABLED SPI_TIMODE_DISABLE
#define SPI_TIMODE_ENABLED SPI_TIMODE_ENABLE
#define SPI_CRCCALCULATION_DISABLED SPI_CRCCALCULATION_DISABLE
#define SPI_CRCCALCULATION_ENABLED SPI_CRCCALCULATION_ENABLE
#define SPI_NSS_PULSE_DISABLED SPI_NSS_PULSE_DISABLE
#define SPI_NSS_PULSE_ENABLED SPI_NSS_PULSE_ENABLE
#if defined(STM32H7)
#define SPI_FLAG_TXE SPI_FLAG_TXP
#define SPI_FLAG_RXNE SPI_FLAG_RXP
#define SPI_IT_TXE SPI_IT_TXP
#define SPI_IT_RXNE SPI_IT_RXP
#define SPI_FRLVL_EMPTY SPI_RX_FIFO_0PACKET
#define SPI_FRLVL_QUARTER_FULL SPI_RX_FIFO_1PACKET
#define SPI_FRLVL_HALF_FULL SPI_RX_FIFO_2PACKET
#define SPI_FRLVL_FULL SPI_RX_FIFO_3PACKET
#endif /* STM32H7 */
/**
* @}
*/
/** @defgroup HAL_TIM_Aliased_Defines HAL TIM Aliased Defines maintained for legacy purpose
* @{
*/
#define CCER_CCxE_MASK TIM_CCER_CCxE_MASK
#define CCER_CCxNE_MASK TIM_CCER_CCxNE_MASK
#define TIM_DMABase_CR1 TIM_DMABASE_CR1
#define TIM_DMABase_CR2 TIM_DMABASE_CR2
#define TIM_DMABase_SMCR TIM_DMABASE_SMCR
#define TIM_DMABase_DIER TIM_DMABASE_DIER
#define TIM_DMABase_SR TIM_DMABASE_SR
#define TIM_DMABase_EGR TIM_DMABASE_EGR
#define TIM_DMABase_CCMR1 TIM_DMABASE_CCMR1
#define TIM_DMABase_CCMR2 TIM_DMABASE_CCMR2
#define TIM_DMABase_CCER TIM_DMABASE_CCER
#define TIM_DMABase_CNT TIM_DMABASE_CNT
#define TIM_DMABase_PSC TIM_DMABASE_PSC
#define TIM_DMABase_ARR TIM_DMABASE_ARR
#define TIM_DMABase_RCR TIM_DMABASE_RCR
#define TIM_DMABase_CCR1 TIM_DMABASE_CCR1
#define TIM_DMABase_CCR2 TIM_DMABASE_CCR2
#define TIM_DMABase_CCR3 TIM_DMABASE_CCR3
#define TIM_DMABase_CCR4 TIM_DMABASE_CCR4
#define TIM_DMABase_BDTR TIM_DMABASE_BDTR
#define TIM_DMABase_DCR TIM_DMABASE_DCR
#define TIM_DMABase_DMAR TIM_DMABASE_DMAR
#define TIM_DMABase_OR1 TIM_DMABASE_OR1
#define TIM_DMABase_CCMR3 TIM_DMABASE_CCMR3
#define TIM_DMABase_CCR5 TIM_DMABASE_CCR5
#define TIM_DMABase_CCR6 TIM_DMABASE_CCR6
#define TIM_DMABase_OR2 TIM_DMABASE_OR2
#define TIM_DMABase_OR3 TIM_DMABASE_OR3
#define TIM_DMABase_OR TIM_DMABASE_OR
#define TIM_EventSource_Update TIM_EVENTSOURCE_UPDATE
#define TIM_EventSource_CC1 TIM_EVENTSOURCE_CC1
#define TIM_EventSource_CC2 TIM_EVENTSOURCE_CC2
#define TIM_EventSource_CC3 TIM_EVENTSOURCE_CC3
#define TIM_EventSource_CC4 TIM_EVENTSOURCE_CC4
#define TIM_EventSource_COM TIM_EVENTSOURCE_COM
#define TIM_EventSource_Trigger TIM_EVENTSOURCE_TRIGGER
#define TIM_EventSource_Break TIM_EVENTSOURCE_BREAK
#define TIM_EventSource_Break2 TIM_EVENTSOURCE_BREAK2
#define TIM_DMABurstLength_1Transfer TIM_DMABURSTLENGTH_1TRANSFER
#define TIM_DMABurstLength_2Transfers TIM_DMABURSTLENGTH_2TRANSFERS
#define TIM_DMABurstLength_3Transfers TIM_DMABURSTLENGTH_3TRANSFERS
#define TIM_DMABurstLength_4Transfers TIM_DMABURSTLENGTH_4TRANSFERS
#define TIM_DMABurstLength_5Transfers TIM_DMABURSTLENGTH_5TRANSFERS
#define TIM_DMABurstLength_6Transfers TIM_DMABURSTLENGTH_6TRANSFERS
#define TIM_DMABurstLength_7Transfers TIM_DMABURSTLENGTH_7TRANSFERS
#define TIM_DMABurstLength_8Transfers TIM_DMABURSTLENGTH_8TRANSFERS
#define TIM_DMABurstLength_9Transfers TIM_DMABURSTLENGTH_9TRANSFERS
#define TIM_DMABurstLength_10Transfers TIM_DMABURSTLENGTH_10TRANSFERS
#define TIM_DMABurstLength_11Transfers TIM_DMABURSTLENGTH_11TRANSFERS
#define TIM_DMABurstLength_12Transfers TIM_DMABURSTLENGTH_12TRANSFERS
#define TIM_DMABurstLength_13Transfers TIM_DMABURSTLENGTH_13TRANSFERS
#define TIM_DMABurstLength_14Transfers TIM_DMABURSTLENGTH_14TRANSFERS
#define TIM_DMABurstLength_15Transfers TIM_DMABURSTLENGTH_15TRANSFERS
#define TIM_DMABurstLength_16Transfers TIM_DMABURSTLENGTH_16TRANSFERS
#define TIM_DMABurstLength_17Transfers TIM_DMABURSTLENGTH_17TRANSFERS
#define TIM_DMABurstLength_18Transfers TIM_DMABURSTLENGTH_18TRANSFERS
#if defined(STM32L0)
#define TIM22_TI1_GPIO1 TIM22_TI1_GPIO
#define TIM22_TI1_GPIO2 TIM22_TI1_GPIO
#endif
#if defined(STM32F3)
#define IS_TIM_HALL_INTERFACE_INSTANCE IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE
#endif
#if defined(STM32H7)
#define TIM_TIM1_ETR_COMP1_OUT TIM_TIM1_ETR_COMP1
#define TIM_TIM1_ETR_COMP2_OUT TIM_TIM1_ETR_COMP2
#define TIM_TIM8_ETR_COMP1_OUT TIM_TIM8_ETR_COMP1
#define TIM_TIM8_ETR_COMP2_OUT TIM_TIM8_ETR_COMP2
#define TIM_TIM2_ETR_COMP1_OUT TIM_TIM2_ETR_COMP1
#define TIM_TIM2_ETR_COMP2_OUT TIM_TIM2_ETR_COMP2
#define TIM_TIM3_ETR_COMP1_OUT TIM_TIM3_ETR_COMP1
#define TIM_TIM1_TI1_COMP1_OUT TIM_TIM1_TI1_COMP1
#define TIM_TIM8_TI1_COMP2_OUT TIM_TIM8_TI1_COMP2
#define TIM_TIM2_TI4_COMP1_OUT TIM_TIM2_TI4_COMP1
#define TIM_TIM2_TI4_COMP2_OUT TIM_TIM2_TI4_COMP2
#define TIM_TIM2_TI4_COMP1COMP2_OUT TIM_TIM2_TI4_COMP1_COMP2
#define TIM_TIM3_TI1_COMP1_OUT TIM_TIM3_TI1_COMP1
#define TIM_TIM3_TI1_COMP2_OUT TIM_TIM3_TI1_COMP2
#define TIM_TIM3_TI1_COMP1COMP2_OUT TIM_TIM3_TI1_COMP1_COMP2
#endif
/**
* @}
*/
/** @defgroup HAL_TSC_Aliased_Defines HAL TSC Aliased Defines maintained for legacy purpose
* @{
*/
#define TSC_SYNC_POL_FALL TSC_SYNC_POLARITY_FALLING
#define TSC_SYNC_POL_RISE_HIGH TSC_SYNC_POLARITY_RISING
/**
* @}
*/
/** @defgroup HAL_UART_Aliased_Defines HAL UART Aliased Defines maintained for legacy purpose
* @{
*/
#define UART_ONEBIT_SAMPLING_DISABLED UART_ONE_BIT_SAMPLE_DISABLE
#define UART_ONEBIT_SAMPLING_ENABLED UART_ONE_BIT_SAMPLE_ENABLE
#define UART_ONE_BIT_SAMPLE_DISABLED UART_ONE_BIT_SAMPLE_DISABLE
#define UART_ONE_BIT_SAMPLE_ENABLED UART_ONE_BIT_SAMPLE_ENABLE
#define __HAL_UART_ONEBIT_ENABLE __HAL_UART_ONE_BIT_SAMPLE_ENABLE
#define __HAL_UART_ONEBIT_DISABLE __HAL_UART_ONE_BIT_SAMPLE_DISABLE
#define __DIV_SAMPLING16 UART_DIV_SAMPLING16
#define __DIVMANT_SAMPLING16 UART_DIVMANT_SAMPLING16
#define __DIVFRAQ_SAMPLING16 UART_DIVFRAQ_SAMPLING16
#define __UART_BRR_SAMPLING16 UART_BRR_SAMPLING16
#define __DIV_SAMPLING8 UART_DIV_SAMPLING8
#define __DIVMANT_SAMPLING8 UART_DIVMANT_SAMPLING8
#define __DIVFRAQ_SAMPLING8 UART_DIVFRAQ_SAMPLING8
#define __UART_BRR_SAMPLING8 UART_BRR_SAMPLING8
#define __DIV_LPUART UART_DIV_LPUART
#define UART_WAKEUPMETHODE_IDLELINE UART_WAKEUPMETHOD_IDLELINE
#define UART_WAKEUPMETHODE_ADDRESSMARK UART_WAKEUPMETHOD_ADDRESSMARK
/**
* @}
*/
/** @defgroup HAL_USART_Aliased_Defines HAL USART Aliased Defines maintained for legacy purpose
* @{
*/
#define USART_CLOCK_DISABLED USART_CLOCK_DISABLE
#define USART_CLOCK_ENABLED USART_CLOCK_ENABLE
#define USARTNACK_ENABLED USART_NACK_ENABLE
#define USARTNACK_DISABLED USART_NACK_DISABLE
/**
* @}
*/
/** @defgroup HAL_WWDG_Aliased_Defines HAL WWDG Aliased Defines maintained for legacy purpose
* @{
*/
#define CFR_BASE WWDG_CFR_BASE
/**
* @}
*/
/** @defgroup HAL_CAN_Aliased_Defines HAL CAN Aliased Defines maintained for legacy purpose
* @{
*/
#define CAN_FilterFIFO0 CAN_FILTER_FIFO0
#define CAN_FilterFIFO1 CAN_FILTER_FIFO1
#define CAN_IT_RQCP0 CAN_IT_TME
#define CAN_IT_RQCP1 CAN_IT_TME
#define CAN_IT_RQCP2 CAN_IT_TME
#define INAK_TIMEOUT CAN_TIMEOUT_VALUE
#define SLAK_TIMEOUT CAN_TIMEOUT_VALUE
#define CAN_TXSTATUS_FAILED ((uint8_t)0x00U)
#define CAN_TXSTATUS_OK ((uint8_t)0x01U)
#define CAN_TXSTATUS_PENDING ((uint8_t)0x02U)
/**
* @}
*/
/** @defgroup HAL_ETH_Aliased_Defines HAL ETH Aliased Defines maintained for legacy purpose
* @{
*/
#define VLAN_TAG ETH_VLAN_TAG
#define MIN_ETH_PAYLOAD ETH_MIN_ETH_PAYLOAD
#define MAX_ETH_PAYLOAD ETH_MAX_ETH_PAYLOAD
#define JUMBO_FRAME_PAYLOAD ETH_JUMBO_FRAME_PAYLOAD
#define MACMIIAR_CR_MASK ETH_MACMIIAR_CR_MASK
#define MACCR_CLEAR_MASK ETH_MACCR_CLEAR_MASK
#define MACFCR_CLEAR_MASK ETH_MACFCR_CLEAR_MASK
#define DMAOMR_CLEAR_MASK ETH_DMAOMR_CLEAR_MASK
#define ETH_MMCCR 0x00000100U
#define ETH_MMCRIR 0x00000104U
#define ETH_MMCTIR 0x00000108U
#define ETH_MMCRIMR 0x0000010CU
#define ETH_MMCTIMR 0x00000110U
#define ETH_MMCTGFSCCR 0x0000014CU
#define ETH_MMCTGFMSCCR 0x00000150U
#define ETH_MMCTGFCR 0x00000168U
#define ETH_MMCRFCECR 0x00000194U
#define ETH_MMCRFAECR 0x00000198U
#define ETH_MMCRGUFCR 0x000001C4U
#define ETH_MAC_TXFIFO_FULL 0x02000000U /* Tx FIFO full */
#define ETH_MAC_TXFIFONOT_EMPTY 0x01000000U /* Tx FIFO not empty */
#define ETH_MAC_TXFIFO_WRITE_ACTIVE 0x00400000U /* Tx FIFO write active */
#define ETH_MAC_TXFIFO_IDLE 0x00000000U /* Tx FIFO read status: Idle */
#define ETH_MAC_TXFIFO_READ 0x00100000U /* Tx FIFO read status: Read (transferring data to
the MAC transmitter) */
#define ETH_MAC_TXFIFO_WAITING 0x00200000U /* Tx FIFO read status: Waiting for TxStatus from
MAC transmitter */
#define ETH_MAC_TXFIFO_WRITING 0x00300000U /* Tx FIFO read status: Writing the received TxStatus
or flushing the TxFIFO */
#define ETH_MAC_TRANSMISSION_PAUSE 0x00080000U /* MAC transmitter in pause */
#define ETH_MAC_TRANSMITFRAMECONTROLLER_IDLE 0x00000000U /* MAC transmit frame controller: Idle */
#define ETH_MAC_TRANSMITFRAMECONTROLLER_WAITING 0x00020000U /* MAC transmit frame controller: Waiting for Status
of previous frame or IFG/backoff period to be over */
#define ETH_MAC_TRANSMITFRAMECONTROLLER_GENRATING_PCF 0x00040000U /* MAC transmit frame controller: Generating and
transmitting a Pause control frame (in full duplex mode) */
#define ETH_MAC_TRANSMITFRAMECONTROLLER_TRANSFERRING 0x00060000U /* MAC transmit frame controller: Transferring input
frame for transmission */
#define ETH_MAC_MII_TRANSMIT_ACTIVE 0x00010000U /* MAC MII transmit engine active */
#define ETH_MAC_RXFIFO_EMPTY 0x00000000U /* Rx FIFO fill level: empty */
#define ETH_MAC_RXFIFO_BELOW_THRESHOLD 0x00000100U /* Rx FIFO fill level: fill-level below flow-control
de-activate threshold */
#define ETH_MAC_RXFIFO_ABOVE_THRESHOLD 0x00000200U /* Rx FIFO fill level: fill-level above flow-control
activate threshold */
#define ETH_MAC_RXFIFO_FULL 0x00000300U /* Rx FIFO fill level: full */
#if defined(STM32F1)
#else
#define ETH_MAC_READCONTROLLER_IDLE 0x00000000U /* Rx FIFO read controller IDLE state */
#define ETH_MAC_READCONTROLLER_READING_DATA 0x00000020U /* Rx FIFO read controller Reading frame data */
#define ETH_MAC_READCONTROLLER_READING_STATUS 0x00000040U /* Rx FIFO read controller Reading frame status
(or time-stamp) */
#endif
#define ETH_MAC_READCONTROLLER_FLUSHING 0x00000060U /* Rx FIFO read controller Flushing the frame data and
status */
#define ETH_MAC_RXFIFO_WRITE_ACTIVE 0x00000010U /* Rx FIFO write controller active */
#define ETH_MAC_SMALL_FIFO_NOTACTIVE 0x00000000U /* MAC small FIFO read / write controllers not active */
#define ETH_MAC_SMALL_FIFO_READ_ACTIVE 0x00000002U /* MAC small FIFO read controller active */
#define ETH_MAC_SMALL_FIFO_WRITE_ACTIVE 0x00000004U /* MAC small FIFO write controller active */
#define ETH_MAC_SMALL_FIFO_RW_ACTIVE 0x00000006U /* MAC small FIFO read / write controllers active */
#define ETH_MAC_MII_RECEIVE_PROTOCOL_ACTIVE 0x00000001U /* MAC MII receive protocol engine active */
#define ETH_TxPacketConfig ETH_TxPacketConfig_t /* Transmit Packet Configuration structure definition */
/**
* @}
*/
/** @defgroup HAL_DCMI_Aliased_Defines HAL DCMI Aliased Defines maintained for legacy purpose
* @{
*/
#define HAL_DCMI_ERROR_OVF HAL_DCMI_ERROR_OVR
#define DCMI_IT_OVF DCMI_IT_OVR
#define DCMI_FLAG_OVFRI DCMI_FLAG_OVRRI
#define DCMI_FLAG_OVFMI DCMI_FLAG_OVRMI
#define HAL_DCMI_ConfigCROP HAL_DCMI_ConfigCrop
#define HAL_DCMI_EnableCROP HAL_DCMI_EnableCrop
#define HAL_DCMI_DisableCROP HAL_DCMI_DisableCrop
/**
* @}
*/
#if defined(STM32L4) || defined(STM32F7) || defined(STM32F427xx) || defined(STM32F437xx) \
|| defined(STM32F429xx) || defined(STM32F439xx) || defined(STM32F469xx) || defined(STM32F479xx) \
|| defined(STM32H7)
/** @defgroup HAL_DMA2D_Aliased_Defines HAL DMA2D Aliased Defines maintained for legacy purpose
* @{
*/
#define DMA2D_ARGB8888 DMA2D_OUTPUT_ARGB8888
#define DMA2D_RGB888 DMA2D_OUTPUT_RGB888
#define DMA2D_RGB565 DMA2D_OUTPUT_RGB565
#define DMA2D_ARGB1555 DMA2D_OUTPUT_ARGB1555
#define DMA2D_ARGB4444 DMA2D_OUTPUT_ARGB4444
#define CM_ARGB8888 DMA2D_INPUT_ARGB8888
#define CM_RGB888 DMA2D_INPUT_RGB888
#define CM_RGB565 DMA2D_INPUT_RGB565
#define CM_ARGB1555 DMA2D_INPUT_ARGB1555
#define CM_ARGB4444 DMA2D_INPUT_ARGB4444
#define CM_L8 DMA2D_INPUT_L8
#define CM_AL44 DMA2D_INPUT_AL44
#define CM_AL88 DMA2D_INPUT_AL88
#define CM_L4 DMA2D_INPUT_L4
#define CM_A8 DMA2D_INPUT_A8
#define CM_A4 DMA2D_INPUT_A4
/**
* @}
*/
#endif /* STM32L4 || STM32F7 || STM32F4 || STM32H7 */
#if defined(STM32L4) || defined(STM32F7) || defined(STM32F427xx) || defined(STM32F437xx) || defined(STM32F429xx) || defined(STM32F439xx) || defined(STM32F469xx) || defined(STM32F479xx) || defined(STM32H7)
/** @defgroup DMA2D_Aliases DMA2D API Aliases
* @{
*/
#define HAL_DMA2D_DisableCLUT HAL_DMA2D_CLUTLoading_Abort /*!< Aliased to HAL_DMA2D_CLUTLoading_Abort
for compatibility with legacy code */
/**
* @}
*/
#endif /* STM32L4 || STM32F7 || STM32F4 || STM32H7 */
/** @defgroup HAL_PPP_Aliased_Defines HAL PPP Aliased Defines maintained for legacy purpose
* @{
*/
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @defgroup HAL_CRYP_Aliased_Functions HAL CRYP Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_CRYP_ComputationCpltCallback HAL_CRYPEx_ComputationCpltCallback
/**
* @}
*/
/** @defgroup HAL_DCACHE_Aliased_Functions HAL DCACHE Aliased Functions maintained for legacy purpose
* @{
*/
/**
* @}
*/
#if !defined(STM32F2)
/** @defgroup HASH_alias HASH API alias
* @{
*/
#define HAL_HASHEx_IRQHandler HAL_HASH_IRQHandler /*!< Redirection for compatibility with legacy code */
/**
*
* @}
*/
#endif /* STM32F2 */
/** @defgroup HAL_HASH_Aliased_Functions HAL HASH Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_HASH_STATETypeDef HAL_HASH_StateTypeDef
#define HAL_HASHPhaseTypeDef HAL_HASH_PhaseTypeDef
#define HAL_HMAC_MD5_Finish HAL_HASH_MD5_Finish
#define HAL_HMAC_SHA1_Finish HAL_HASH_SHA1_Finish
#define HAL_HMAC_SHA224_Finish HAL_HASH_SHA224_Finish
#define HAL_HMAC_SHA256_Finish HAL_HASH_SHA256_Finish
/*HASH Algorithm Selection*/
#define HASH_AlgoSelection_SHA1 HASH_ALGOSELECTION_SHA1
#define HASH_AlgoSelection_SHA224 HASH_ALGOSELECTION_SHA224
#define HASH_AlgoSelection_SHA256 HASH_ALGOSELECTION_SHA256
#define HASH_AlgoSelection_MD5 HASH_ALGOSELECTION_MD5
#define HASH_AlgoMode_HASH HASH_ALGOMODE_HASH
#define HASH_AlgoMode_HMAC HASH_ALGOMODE_HMAC
#define HASH_HMACKeyType_ShortKey HASH_HMAC_KEYTYPE_SHORTKEY
#define HASH_HMACKeyType_LongKey HASH_HMAC_KEYTYPE_LONGKEY
#if defined(STM32L4) || defined(STM32L5) || defined(STM32F2) || defined(STM32F4) || defined(STM32F7) || defined(STM32H7)
#define HAL_HASH_MD5_Accumulate HAL_HASH_MD5_Accmlt
#define HAL_HASH_MD5_Accumulate_End HAL_HASH_MD5_Accmlt_End
#define HAL_HASH_MD5_Accumulate_IT HAL_HASH_MD5_Accmlt_IT
#define HAL_HASH_MD5_Accumulate_End_IT HAL_HASH_MD5_Accmlt_End_IT
#define HAL_HASH_SHA1_Accumulate HAL_HASH_SHA1_Accmlt
#define HAL_HASH_SHA1_Accumulate_End HAL_HASH_SHA1_Accmlt_End
#define HAL_HASH_SHA1_Accumulate_IT HAL_HASH_SHA1_Accmlt_IT
#define HAL_HASH_SHA1_Accumulate_End_IT HAL_HASH_SHA1_Accmlt_End_IT
#define HAL_HASHEx_SHA224_Accumulate HAL_HASHEx_SHA224_Accmlt
#define HAL_HASHEx_SHA224_Accumulate_End HAL_HASHEx_SHA224_Accmlt_End
#define HAL_HASHEx_SHA224_Accumulate_IT HAL_HASHEx_SHA224_Accmlt_IT
#define HAL_HASHEx_SHA224_Accumulate_End_IT HAL_HASHEx_SHA224_Accmlt_End_IT
#define HAL_HASHEx_SHA256_Accumulate HAL_HASHEx_SHA256_Accmlt
#define HAL_HASHEx_SHA256_Accumulate_End HAL_HASHEx_SHA256_Accmlt_End
#define HAL_HASHEx_SHA256_Accumulate_IT HAL_HASHEx_SHA256_Accmlt_IT
#define HAL_HASHEx_SHA256_Accumulate_End_IT HAL_HASHEx_SHA256_Accmlt_End_IT
#endif /* STM32L4 || STM32L5 || STM32F2 || STM32F4 || STM32F7 || STM32H7 */
/**
* @}
*/
/** @defgroup HAL_Aliased_Functions HAL Generic Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_EnableDBGSleepMode HAL_DBGMCU_EnableDBGSleepMode
#define HAL_DisableDBGSleepMode HAL_DBGMCU_DisableDBGSleepMode
#define HAL_EnableDBGStopMode HAL_DBGMCU_EnableDBGStopMode
#define HAL_DisableDBGStopMode HAL_DBGMCU_DisableDBGStopMode
#define HAL_EnableDBGStandbyMode HAL_DBGMCU_EnableDBGStandbyMode
#define HAL_DisableDBGStandbyMode HAL_DBGMCU_DisableDBGStandbyMode
#define HAL_DBG_LowPowerConfig(Periph, cmd) (((cmd\
)==ENABLE)? HAL_DBGMCU_DBG_EnableLowPowerConfig(Periph) : \
HAL_DBGMCU_DBG_DisableLowPowerConfig(Periph))
#define HAL_VREFINT_OutputSelect HAL_SYSCFG_VREFINT_OutputSelect
#define HAL_Lock_Cmd(cmd) (((cmd)==ENABLE) ? HAL_SYSCFG_Enable_Lock_VREFINT() : HAL_SYSCFG_Disable_Lock_VREFINT())
#if defined(STM32L0)
#else
#define HAL_VREFINT_Cmd(cmd) (((cmd)==ENABLE)? HAL_SYSCFG_EnableVREFINT() : HAL_SYSCFG_DisableVREFINT())
#endif
#define HAL_ADC_EnableBuffer_Cmd(cmd) (((cmd)==ENABLE) ? HAL_ADCEx_EnableVREFINT() : HAL_ADCEx_DisableVREFINT())
#define HAL_ADC_EnableBufferSensor_Cmd(cmd) (((cmd\
)==ENABLE) ? HAL_ADCEx_EnableVREFINTTempSensor() : \
HAL_ADCEx_DisableVREFINTTempSensor())
#if defined(STM32H7A3xx) || defined(STM32H7B3xx) || defined(STM32H7B0xx) || defined(STM32H7A3xxQ) || \
defined(STM32H7B3xxQ) || defined(STM32H7B0xxQ)
#define HAL_EnableSRDomainDBGStopMode HAL_EnableDomain3DBGStopMode
#define HAL_DisableSRDomainDBGStopMode HAL_DisableDomain3DBGStopMode
#define HAL_EnableSRDomainDBGStandbyMode HAL_EnableDomain3DBGStandbyMode
#define HAL_DisableSRDomainDBGStandbyMode HAL_DisableDomain3DBGStandbyMode
#endif /* STM32H7A3xx || STM32H7B3xx || STM32H7B0xx || STM32H7A3xxQ || STM32H7B3xxQ || STM32H7B0xxQ */
/**
* @}
*/
/** @defgroup HAL_FLASH_Aliased_Functions HAL FLASH Aliased Functions maintained for legacy purpose
* @{
*/
#define FLASH_HalfPageProgram HAL_FLASHEx_HalfPageProgram
#define FLASH_EnableRunPowerDown HAL_FLASHEx_EnableRunPowerDown
#define FLASH_DisableRunPowerDown HAL_FLASHEx_DisableRunPowerDown
#define HAL_DATA_EEPROMEx_Unlock HAL_FLASHEx_DATAEEPROM_Unlock
#define HAL_DATA_EEPROMEx_Lock HAL_FLASHEx_DATAEEPROM_Lock
#define HAL_DATA_EEPROMEx_Erase HAL_FLASHEx_DATAEEPROM_Erase
#define HAL_DATA_EEPROMEx_Program HAL_FLASHEx_DATAEEPROM_Program
/**
* @}
*/
/** @defgroup HAL_I2C_Aliased_Functions HAL I2C Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_I2CEx_AnalogFilter_Config HAL_I2CEx_ConfigAnalogFilter
#define HAL_I2CEx_DigitalFilter_Config HAL_I2CEx_ConfigDigitalFilter
#define HAL_FMPI2CEx_AnalogFilter_Config HAL_FMPI2CEx_ConfigAnalogFilter
#define HAL_FMPI2CEx_DigitalFilter_Config HAL_FMPI2CEx_ConfigDigitalFilter
#define HAL_I2CFastModePlusConfig(SYSCFG_I2CFastModePlus, cmd) ((cmd == ENABLE)? \
HAL_I2CEx_EnableFastModePlus(SYSCFG_I2CFastModePlus): \
HAL_I2CEx_DisableFastModePlus(SYSCFG_I2CFastModePlus))
#if defined(STM32H7) || defined(STM32WB) || defined(STM32G0) || defined(STM32F0) || defined(STM32F1) || \
defined(STM32F2) || defined(STM32F3) || defined(STM32F4) || defined(STM32F7) || defined(STM32L0) || \
defined(STM32L4) || defined(STM32L5) || defined(STM32G4) || defined(STM32L1)
#define HAL_I2C_Master_Sequential_Transmit_IT HAL_I2C_Master_Seq_Transmit_IT
#define HAL_I2C_Master_Sequential_Receive_IT HAL_I2C_Master_Seq_Receive_IT
#define HAL_I2C_Slave_Sequential_Transmit_IT HAL_I2C_Slave_Seq_Transmit_IT
#define HAL_I2C_Slave_Sequential_Receive_IT HAL_I2C_Slave_Seq_Receive_IT
#endif /* STM32H7 || STM32WB || STM32G0 || STM32F0 || STM32F1 || STM32F2 || STM32F3 || STM32F4 || STM32F7 || STM32L0 ||
STM32L4 || STM32L5 || STM32G4 || STM32L1 */
#if defined(STM32H7) || defined(STM32WB) || defined(STM32G0) || defined(STM32F4) || defined(STM32F7) || \
defined(STM32L0) || defined(STM32L4) || defined(STM32L5) || defined(STM32G4)|| defined(STM32L1)
#define HAL_I2C_Master_Sequential_Transmit_DMA HAL_I2C_Master_Seq_Transmit_DMA
#define HAL_I2C_Master_Sequential_Receive_DMA HAL_I2C_Master_Seq_Receive_DMA
#define HAL_I2C_Slave_Sequential_Transmit_DMA HAL_I2C_Slave_Seq_Transmit_DMA
#define HAL_I2C_Slave_Sequential_Receive_DMA HAL_I2C_Slave_Seq_Receive_DMA
#endif /* STM32H7 || STM32WB || STM32G0 || STM32F4 || STM32F7 || STM32L0 || STM32L4 || STM32L5 || STM32G4 || STM32L1 */
#if defined(STM32F4)
#define HAL_FMPI2C_Master_Sequential_Transmit_IT HAL_FMPI2C_Master_Seq_Transmit_IT
#define HAL_FMPI2C_Master_Sequential_Receive_IT HAL_FMPI2C_Master_Seq_Receive_IT
#define HAL_FMPI2C_Slave_Sequential_Transmit_IT HAL_FMPI2C_Slave_Seq_Transmit_IT
#define HAL_FMPI2C_Slave_Sequential_Receive_IT HAL_FMPI2C_Slave_Seq_Receive_IT
#define HAL_FMPI2C_Master_Sequential_Transmit_DMA HAL_FMPI2C_Master_Seq_Transmit_DMA
#define HAL_FMPI2C_Master_Sequential_Receive_DMA HAL_FMPI2C_Master_Seq_Receive_DMA
#define HAL_FMPI2C_Slave_Sequential_Transmit_DMA HAL_FMPI2C_Slave_Seq_Transmit_DMA
#define HAL_FMPI2C_Slave_Sequential_Receive_DMA HAL_FMPI2C_Slave_Seq_Receive_DMA
#endif /* STM32F4 */
/**
* @}
*/
/** @defgroup HAL_PWR_Aliased HAL PWR Aliased maintained for legacy purpose
* @{
*/
#if defined(STM32G0)
#define HAL_PWR_ConfigPVD HAL_PWREx_ConfigPVD
#define HAL_PWR_EnablePVD HAL_PWREx_EnablePVD
#define HAL_PWR_DisablePVD HAL_PWREx_DisablePVD
#define HAL_PWR_PVD_IRQHandler HAL_PWREx_PVD_IRQHandler
#endif
#define HAL_PWR_PVDConfig HAL_PWR_ConfigPVD
#define HAL_PWR_DisableBkUpReg HAL_PWREx_DisableBkUpReg
#define HAL_PWR_DisableFlashPowerDown HAL_PWREx_DisableFlashPowerDown
#define HAL_PWR_DisableVddio2Monitor HAL_PWREx_DisableVddio2Monitor
#define HAL_PWR_EnableBkUpReg HAL_PWREx_EnableBkUpReg
#define HAL_PWR_EnableFlashPowerDown HAL_PWREx_EnableFlashPowerDown
#define HAL_PWR_EnableVddio2Monitor HAL_PWREx_EnableVddio2Monitor
#define HAL_PWR_PVD_PVM_IRQHandler HAL_PWREx_PVD_PVM_IRQHandler
#define HAL_PWR_PVDLevelConfig HAL_PWR_ConfigPVD
#define HAL_PWR_Vddio2Monitor_IRQHandler HAL_PWREx_Vddio2Monitor_IRQHandler
#define HAL_PWR_Vddio2MonitorCallback HAL_PWREx_Vddio2MonitorCallback
#define HAL_PWREx_ActivateOverDrive HAL_PWREx_EnableOverDrive
#define HAL_PWREx_DeactivateOverDrive HAL_PWREx_DisableOverDrive
#define HAL_PWREx_DisableSDADCAnalog HAL_PWREx_DisableSDADC
#define HAL_PWREx_EnableSDADCAnalog HAL_PWREx_EnableSDADC
#define HAL_PWREx_PVMConfig HAL_PWREx_ConfigPVM
#define PWR_MODE_NORMAL PWR_PVD_MODE_NORMAL
#define PWR_MODE_IT_RISING PWR_PVD_MODE_IT_RISING
#define PWR_MODE_IT_FALLING PWR_PVD_MODE_IT_FALLING
#define PWR_MODE_IT_RISING_FALLING PWR_PVD_MODE_IT_RISING_FALLING
#define PWR_MODE_EVENT_RISING PWR_PVD_MODE_EVENT_RISING
#define PWR_MODE_EVENT_FALLING PWR_PVD_MODE_EVENT_FALLING
#define PWR_MODE_EVENT_RISING_FALLING PWR_PVD_MODE_EVENT_RISING_FALLING
#define CR_OFFSET_BB PWR_CR_OFFSET_BB
#define CSR_OFFSET_BB PWR_CSR_OFFSET_BB
#define PMODE_BIT_NUMBER VOS_BIT_NUMBER
#define CR_PMODE_BB CR_VOS_BB
#define DBP_BitNumber DBP_BIT_NUMBER
#define PVDE_BitNumber PVDE_BIT_NUMBER
#define PMODE_BitNumber PMODE_BIT_NUMBER
#define EWUP_BitNumber EWUP_BIT_NUMBER
#define FPDS_BitNumber FPDS_BIT_NUMBER
#define ODEN_BitNumber ODEN_BIT_NUMBER
#define ODSWEN_BitNumber ODSWEN_BIT_NUMBER
#define MRLVDS_BitNumber MRLVDS_BIT_NUMBER
#define LPLVDS_BitNumber LPLVDS_BIT_NUMBER
#define BRE_BitNumber BRE_BIT_NUMBER
#define PWR_MODE_EVT PWR_PVD_MODE_NORMAL
/**
* @}
*/
/** @defgroup HAL_RTC_Aliased_Functions HAL RTC Aliased Functions maintained for legacy purpose
* @{
*/
/**
* @}
*/
/** @defgroup HAL_SMBUS_Aliased_Functions HAL SMBUS Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_SMBUS_Slave_Listen_IT HAL_SMBUS_EnableListen_IT
#define HAL_SMBUS_SlaveAddrCallback HAL_SMBUS_AddrCallback
#define HAL_SMBUS_SlaveListenCpltCallback HAL_SMBUS_ListenCpltCallback
/**
* @}
*/
/** @defgroup HAL_SPI_Aliased_Functions HAL SPI Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_SPI_FlushRxFifo HAL_SPIEx_FlushRxFifo
/**
* @}
*/
/** @defgroup HAL_TIM_Aliased_Functions HAL TIM Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_TIM_DMADelayPulseCplt TIM_DMADelayPulseCplt
#define HAL_TIM_DMAError TIM_DMAError
#define HAL_TIM_DMACaptureCplt TIM_DMACaptureCplt
#define HAL_TIMEx_DMACommutationCplt TIMEx_DMACommutationCplt
#if defined(STM32H7) || defined(STM32G0) || defined(STM32F0) || defined(STM32F1) || defined(STM32F2) || \
defined(STM32F3) || defined(STM32F4) || defined(STM32F7) || defined(STM32L0) || defined(STM32L4)
#define HAL_TIM_SlaveConfigSynchronization HAL_TIM_SlaveConfigSynchro
#define HAL_TIM_SlaveConfigSynchronization_IT HAL_TIM_SlaveConfigSynchro_IT
#define HAL_TIMEx_CommutationCallback HAL_TIMEx_CommutCallback
#define HAL_TIMEx_ConfigCommutationEvent HAL_TIMEx_ConfigCommutEvent
#define HAL_TIMEx_ConfigCommutationEvent_IT HAL_TIMEx_ConfigCommutEvent_IT
#define HAL_TIMEx_ConfigCommutationEvent_DMA HAL_TIMEx_ConfigCommutEvent_DMA
#endif /* STM32H7 || STM32G0 || STM32F0 || STM32F1 || STM32F2 || STM32F3 || STM32F4 || STM32F7 || STM32L0 */
/**
* @}
*/
/** @defgroup HAL_UART_Aliased_Functions HAL UART Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_UART_WakeupCallback HAL_UARTEx_WakeupCallback
/**
* @}
*/
/** @defgroup HAL_LTDC_Aliased_Functions HAL LTDC Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_LTDC_LineEvenCallback HAL_LTDC_LineEventCallback
#define HAL_LTDC_Relaod HAL_LTDC_Reload
#define HAL_LTDC_StructInitFromVideoConfig HAL_LTDCEx_StructInitFromVideoConfig
#define HAL_LTDC_StructInitFromAdaptedCommandConfig HAL_LTDCEx_StructInitFromAdaptedCommandConfig
/**
* @}
*/
/** @defgroup HAL_PPP_Aliased_Functions HAL PPP Aliased Functions maintained for legacy purpose
* @{
*/
/**
* @}
*/
/* Exported macros ------------------------------------------------------------*/
/** @defgroup HAL_AES_Aliased_Macros HAL CRYP Aliased Macros maintained for legacy purpose
* @{
*/
#define AES_IT_CC CRYP_IT_CC
#define AES_IT_ERR CRYP_IT_ERR
#define AES_FLAG_CCF CRYP_FLAG_CCF
/**
* @}
*/
/** @defgroup HAL_Aliased_Macros HAL Generic Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_GET_BOOT_MODE __HAL_SYSCFG_GET_BOOT_MODE
#define __HAL_REMAPMEMORY_FLASH __HAL_SYSCFG_REMAPMEMORY_FLASH
#define __HAL_REMAPMEMORY_SYSTEMFLASH __HAL_SYSCFG_REMAPMEMORY_SYSTEMFLASH
#define __HAL_REMAPMEMORY_SRAM __HAL_SYSCFG_REMAPMEMORY_SRAM
#define __HAL_REMAPMEMORY_FMC __HAL_SYSCFG_REMAPMEMORY_FMC
#define __HAL_REMAPMEMORY_FMC_SDRAM __HAL_SYSCFG_REMAPMEMORY_FMC_SDRAM
#define __HAL_REMAPMEMORY_FSMC __HAL_SYSCFG_REMAPMEMORY_FSMC
#define __HAL_REMAPMEMORY_QUADSPI __HAL_SYSCFG_REMAPMEMORY_QUADSPI
#define __HAL_FMC_BANK __HAL_SYSCFG_FMC_BANK
#define __HAL_GET_FLAG __HAL_SYSCFG_GET_FLAG
#define __HAL_CLEAR_FLAG __HAL_SYSCFG_CLEAR_FLAG
#define __HAL_VREFINT_OUT_ENABLE __HAL_SYSCFG_VREFINT_OUT_ENABLE
#define __HAL_VREFINT_OUT_DISABLE __HAL_SYSCFG_VREFINT_OUT_DISABLE
#define __HAL_SYSCFG_SRAM2_WRP_ENABLE __HAL_SYSCFG_SRAM2_WRP_0_31_ENABLE
#define SYSCFG_FLAG_VREF_READY SYSCFG_FLAG_VREFINT_READY
#define SYSCFG_FLAG_RC48 RCC_FLAG_HSI48
#define IS_SYSCFG_FASTMODEPLUS_CONFIG IS_I2C_FASTMODEPLUS
#define UFB_MODE_BitNumber UFB_MODE_BIT_NUMBER
#define CMP_PD_BitNumber CMP_PD_BIT_NUMBER
/**
* @}
*/
/** @defgroup HAL_ADC_Aliased_Macros HAL ADC Aliased Macros maintained for legacy purpose
* @{
*/
#define __ADC_ENABLE __HAL_ADC_ENABLE
#define __ADC_DISABLE __HAL_ADC_DISABLE
#define __HAL_ADC_ENABLING_CONDITIONS ADC_ENABLING_CONDITIONS
#define __HAL_ADC_DISABLING_CONDITIONS ADC_DISABLING_CONDITIONS
#define __HAL_ADC_IS_ENABLED ADC_IS_ENABLE
#define __ADC_IS_ENABLED ADC_IS_ENABLE
#define __HAL_ADC_IS_SOFTWARE_START_REGULAR ADC_IS_SOFTWARE_START_REGULAR
#define __HAL_ADC_IS_SOFTWARE_START_INJECTED ADC_IS_SOFTWARE_START_INJECTED
#define __HAL_ADC_IS_CONVERSION_ONGOING_REGULAR_INJECTED ADC_IS_CONVERSION_ONGOING_REGULAR_INJECTED
#define __HAL_ADC_IS_CONVERSION_ONGOING_REGULAR ADC_IS_CONVERSION_ONGOING_REGULAR
#define __HAL_ADC_IS_CONVERSION_ONGOING_INJECTED ADC_IS_CONVERSION_ONGOING_INJECTED
#define __HAL_ADC_IS_CONVERSION_ONGOING ADC_IS_CONVERSION_ONGOING
#define __HAL_ADC_CLEAR_ERRORCODE ADC_CLEAR_ERRORCODE
#define __HAL_ADC_GET_RESOLUTION ADC_GET_RESOLUTION
#define __HAL_ADC_JSQR_RK ADC_JSQR_RK
#define __HAL_ADC_CFGR_AWD1CH ADC_CFGR_AWD1CH_SHIFT
#define __HAL_ADC_CFGR_AWD23CR ADC_CFGR_AWD23CR
#define __HAL_ADC_CFGR_INJECT_AUTO_CONVERSION ADC_CFGR_INJECT_AUTO_CONVERSION
#define __HAL_ADC_CFGR_INJECT_CONTEXT_QUEUE ADC_CFGR_INJECT_CONTEXT_QUEUE
#define __HAL_ADC_CFGR_INJECT_DISCCONTINUOUS ADC_CFGR_INJECT_DISCCONTINUOUS
#define __HAL_ADC_CFGR_REG_DISCCONTINUOUS ADC_CFGR_REG_DISCCONTINUOUS
#define __HAL_ADC_CFGR_DISCONTINUOUS_NUM ADC_CFGR_DISCONTINUOUS_NUM
#define __HAL_ADC_CFGR_AUTOWAIT ADC_CFGR_AUTOWAIT
#define __HAL_ADC_CFGR_CONTINUOUS ADC_CFGR_CONTINUOUS
#define __HAL_ADC_CFGR_OVERRUN ADC_CFGR_OVERRUN
#define __HAL_ADC_CFGR_DMACONTREQ ADC_CFGR_DMACONTREQ
#define __HAL_ADC_CFGR_EXTSEL ADC_CFGR_EXTSEL_SET
#define __HAL_ADC_JSQR_JEXTSEL ADC_JSQR_JEXTSEL_SET
#define __HAL_ADC_OFR_CHANNEL ADC_OFR_CHANNEL
#define __HAL_ADC_DIFSEL_CHANNEL ADC_DIFSEL_CHANNEL
#define __HAL_ADC_CALFACT_DIFF_SET ADC_CALFACT_DIFF_SET
#define __HAL_ADC_CALFACT_DIFF_GET ADC_CALFACT_DIFF_GET
#define __HAL_ADC_TRX_HIGHTHRESHOLD ADC_TRX_HIGHTHRESHOLD
#define __HAL_ADC_OFFSET_SHIFT_RESOLUTION ADC_OFFSET_SHIFT_RESOLUTION
#define __HAL_ADC_AWD1THRESHOLD_SHIFT_RESOLUTION ADC_AWD1THRESHOLD_SHIFT_RESOLUTION
#define __HAL_ADC_AWD23THRESHOLD_SHIFT_RESOLUTION ADC_AWD23THRESHOLD_SHIFT_RESOLUTION
#define __HAL_ADC_COMMON_REGISTER ADC_COMMON_REGISTER
#define __HAL_ADC_COMMON_CCR_MULTI ADC_COMMON_CCR_MULTI
#define __HAL_ADC_MULTIMODE_IS_ENABLED ADC_MULTIMODE_IS_ENABLE
#define __ADC_MULTIMODE_IS_ENABLED ADC_MULTIMODE_IS_ENABLE
#define __HAL_ADC_NONMULTIMODE_OR_MULTIMODEMASTER ADC_NONMULTIMODE_OR_MULTIMODEMASTER
#define __HAL_ADC_COMMON_ADC_OTHER ADC_COMMON_ADC_OTHER
#define __HAL_ADC_MULTI_SLAVE ADC_MULTI_SLAVE
#define __HAL_ADC_SQR1_L ADC_SQR1_L_SHIFT
#define __HAL_ADC_JSQR_JL ADC_JSQR_JL_SHIFT
#define __HAL_ADC_JSQR_RK_JL ADC_JSQR_RK_JL
#define __HAL_ADC_CR1_DISCONTINUOUS_NUM ADC_CR1_DISCONTINUOUS_NUM
#define __HAL_ADC_CR1_SCAN ADC_CR1_SCAN_SET
#define __HAL_ADC_CONVCYCLES_MAX_RANGE ADC_CONVCYCLES_MAX_RANGE
#define __HAL_ADC_CLOCK_PRESCALER_RANGE ADC_CLOCK_PRESCALER_RANGE
#define __HAL_ADC_GET_CLOCK_PRESCALER ADC_GET_CLOCK_PRESCALER
#define __HAL_ADC_SQR1 ADC_SQR1
#define __HAL_ADC_SMPR1 ADC_SMPR1
#define __HAL_ADC_SMPR2 ADC_SMPR2
#define __HAL_ADC_SQR3_RK ADC_SQR3_RK
#define __HAL_ADC_SQR2_RK ADC_SQR2_RK
#define __HAL_ADC_SQR1_RK ADC_SQR1_RK
#define __HAL_ADC_CR2_CONTINUOUS ADC_CR2_CONTINUOUS
#define __HAL_ADC_CR1_DISCONTINUOUS ADC_CR1_DISCONTINUOUS
#define __HAL_ADC_CR1_SCANCONV ADC_CR1_SCANCONV
#define __HAL_ADC_CR2_EOCSelection ADC_CR2_EOCSelection
#define __HAL_ADC_CR2_DMAContReq ADC_CR2_DMAContReq
#define __HAL_ADC_JSQR ADC_JSQR
#define __HAL_ADC_CHSELR_CHANNEL ADC_CHSELR_CHANNEL
#define __HAL_ADC_CFGR1_REG_DISCCONTINUOUS ADC_CFGR1_REG_DISCCONTINUOUS
#define __HAL_ADC_CFGR1_AUTOOFF ADC_CFGR1_AUTOOFF
#define __HAL_ADC_CFGR1_AUTOWAIT ADC_CFGR1_AUTOWAIT
#define __HAL_ADC_CFGR1_CONTINUOUS ADC_CFGR1_CONTINUOUS
#define __HAL_ADC_CFGR1_OVERRUN ADC_CFGR1_OVERRUN
#define __HAL_ADC_CFGR1_SCANDIR ADC_CFGR1_SCANDIR
#define __HAL_ADC_CFGR1_DMACONTREQ ADC_CFGR1_DMACONTREQ
/**
* @}
*/
/** @defgroup HAL_DAC_Aliased_Macros HAL DAC Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_DHR12R1_ALIGNEMENT DAC_DHR12R1_ALIGNMENT
#define __HAL_DHR12R2_ALIGNEMENT DAC_DHR12R2_ALIGNMENT
#define __HAL_DHR12RD_ALIGNEMENT DAC_DHR12RD_ALIGNMENT
#define IS_DAC_GENERATE_WAVE IS_DAC_WAVE
/**
* @}
*/
/** @defgroup HAL_DBGMCU_Aliased_Macros HAL DBGMCU Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_FREEZE_TIM1_DBGMCU __HAL_DBGMCU_FREEZE_TIM1
#define __HAL_UNFREEZE_TIM1_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM1
#define __HAL_FREEZE_TIM2_DBGMCU __HAL_DBGMCU_FREEZE_TIM2
#define __HAL_UNFREEZE_TIM2_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM2
#define __HAL_FREEZE_TIM3_DBGMCU __HAL_DBGMCU_FREEZE_TIM3
#define __HAL_UNFREEZE_TIM3_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM3
#define __HAL_FREEZE_TIM4_DBGMCU __HAL_DBGMCU_FREEZE_TIM4
#define __HAL_UNFREEZE_TIM4_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM4
#define __HAL_FREEZE_TIM5_DBGMCU __HAL_DBGMCU_FREEZE_TIM5
#define __HAL_UNFREEZE_TIM5_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM5
#define __HAL_FREEZE_TIM6_DBGMCU __HAL_DBGMCU_FREEZE_TIM6
#define __HAL_UNFREEZE_TIM6_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM6
#define __HAL_FREEZE_TIM7_DBGMCU __HAL_DBGMCU_FREEZE_TIM7
#define __HAL_UNFREEZE_TIM7_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM7
#define __HAL_FREEZE_TIM8_DBGMCU __HAL_DBGMCU_FREEZE_TIM8
#define __HAL_UNFREEZE_TIM8_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM8
#define __HAL_FREEZE_TIM9_DBGMCU __HAL_DBGMCU_FREEZE_TIM9
#define __HAL_UNFREEZE_TIM9_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM9
#define __HAL_FREEZE_TIM10_DBGMCU __HAL_DBGMCU_FREEZE_TIM10
#define __HAL_UNFREEZE_TIM10_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM10
#define __HAL_FREEZE_TIM11_DBGMCU __HAL_DBGMCU_FREEZE_TIM11
#define __HAL_UNFREEZE_TIM11_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM11
#define __HAL_FREEZE_TIM12_DBGMCU __HAL_DBGMCU_FREEZE_TIM12
#define __HAL_UNFREEZE_TIM12_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM12
#define __HAL_FREEZE_TIM13_DBGMCU __HAL_DBGMCU_FREEZE_TIM13
#define __HAL_UNFREEZE_TIM13_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM13
#define __HAL_FREEZE_TIM14_DBGMCU __HAL_DBGMCU_FREEZE_TIM14
#define __HAL_UNFREEZE_TIM14_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM14
#define __HAL_FREEZE_CAN2_DBGMCU __HAL_DBGMCU_FREEZE_CAN2
#define __HAL_UNFREEZE_CAN2_DBGMCU __HAL_DBGMCU_UNFREEZE_CAN2
#define __HAL_FREEZE_TIM15_DBGMCU __HAL_DBGMCU_FREEZE_TIM15
#define __HAL_UNFREEZE_TIM15_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM15
#define __HAL_FREEZE_TIM16_DBGMCU __HAL_DBGMCU_FREEZE_TIM16
#define __HAL_UNFREEZE_TIM16_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM16
#define __HAL_FREEZE_TIM17_DBGMCU __HAL_DBGMCU_FREEZE_TIM17
#define __HAL_UNFREEZE_TIM17_DBGMCU __HAL_DBGMCU_UNFREEZE_TIM17
#define __HAL_FREEZE_RTC_DBGMCU __HAL_DBGMCU_FREEZE_RTC
#define __HAL_UNFREEZE_RTC_DBGMCU __HAL_DBGMCU_UNFREEZE_RTC
#if defined(STM32H7)
#define __HAL_FREEZE_WWDG_DBGMCU __HAL_DBGMCU_FREEZE_WWDG1
#define __HAL_UNFREEZE_WWDG_DBGMCU __HAL_DBGMCU_UnFreeze_WWDG1
#define __HAL_FREEZE_IWDG_DBGMCU __HAL_DBGMCU_FREEZE_IWDG1
#define __HAL_UNFREEZE_IWDG_DBGMCU __HAL_DBGMCU_UnFreeze_IWDG1
#else
#define __HAL_FREEZE_WWDG_DBGMCU __HAL_DBGMCU_FREEZE_WWDG
#define __HAL_UNFREEZE_WWDG_DBGMCU __HAL_DBGMCU_UNFREEZE_WWDG
#define __HAL_FREEZE_IWDG_DBGMCU __HAL_DBGMCU_FREEZE_IWDG
#define __HAL_UNFREEZE_IWDG_DBGMCU __HAL_DBGMCU_UNFREEZE_IWDG
#endif /* STM32H7 */
#define __HAL_FREEZE_I2C1_TIMEOUT_DBGMCU __HAL_DBGMCU_FREEZE_I2C1_TIMEOUT
#define __HAL_UNFREEZE_I2C1_TIMEOUT_DBGMCU __HAL_DBGMCU_UNFREEZE_I2C1_TIMEOUT
#define __HAL_FREEZE_I2C2_TIMEOUT_DBGMCU __HAL_DBGMCU_FREEZE_I2C2_TIMEOUT
#define __HAL_UNFREEZE_I2C2_TIMEOUT_DBGMCU __HAL_DBGMCU_UNFREEZE_I2C2_TIMEOUT
#define __HAL_FREEZE_I2C3_TIMEOUT_DBGMCU __HAL_DBGMCU_FREEZE_I2C3_TIMEOUT
#define __HAL_UNFREEZE_I2C3_TIMEOUT_DBGMCU __HAL_DBGMCU_UNFREEZE_I2C3_TIMEOUT
#define __HAL_FREEZE_CAN1_DBGMCU __HAL_DBGMCU_FREEZE_CAN1
#define __HAL_UNFREEZE_CAN1_DBGMCU __HAL_DBGMCU_UNFREEZE_CAN1
#define __HAL_FREEZE_LPTIM1_DBGMCU __HAL_DBGMCU_FREEZE_LPTIM1
#define __HAL_UNFREEZE_LPTIM1_DBGMCU __HAL_DBGMCU_UNFREEZE_LPTIM1
#define __HAL_FREEZE_LPTIM2_DBGMCU __HAL_DBGMCU_FREEZE_LPTIM2
#define __HAL_UNFREEZE_LPTIM2_DBGMCU __HAL_DBGMCU_UNFREEZE_LPTIM2
/**
* @}
*/
/** @defgroup HAL_COMP_Aliased_Macros HAL COMP Aliased Macros maintained for legacy purpose
* @{
*/
#if defined(STM32F3)
#define COMP_START __HAL_COMP_ENABLE
#define COMP_STOP __HAL_COMP_DISABLE
#define COMP_LOCK __HAL_COMP_LOCK
#if defined(STM32F301x8) || defined(STM32F302x8) || defined(STM32F318xx) || defined(STM32F303x8) || \
defined(STM32F334x8) || defined(STM32F328xx)
#define __HAL_COMP_EXTI_RISING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_RISING_EDGE() : \
__HAL_COMP_COMP6_EXTI_ENABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_RISING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_RISING_EDGE() : \
__HAL_COMP_COMP6_EXTI_DISABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_FALLING_EDGE() : \
__HAL_COMP_COMP6_EXTI_ENABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_FALLING_EDGE() : \
__HAL_COMP_COMP6_EXTI_DISABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_ENABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_IT() : \
__HAL_COMP_COMP6_EXTI_ENABLE_IT())
#define __HAL_COMP_EXTI_DISABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_IT() : \
__HAL_COMP_COMP6_EXTI_DISABLE_IT())
#define __HAL_COMP_EXTI_GET_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_GET_FLAG() : \
__HAL_COMP_COMP6_EXTI_GET_FLAG())
#define __HAL_COMP_EXTI_CLEAR_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_CLEAR_FLAG() : \
__HAL_COMP_COMP6_EXTI_CLEAR_FLAG())
# endif
# if defined(STM32F302xE) || defined(STM32F302xC)
#define __HAL_COMP_EXTI_RISING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_RISING_EDGE() : \
__HAL_COMP_COMP6_EXTI_ENABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_RISING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_RISING_EDGE() : \
__HAL_COMP_COMP6_EXTI_DISABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_FALLING_EDGE() : \
__HAL_COMP_COMP6_EXTI_ENABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_FALLING_EDGE() : \
__HAL_COMP_COMP6_EXTI_DISABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_ENABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_IT() : \
__HAL_COMP_COMP6_EXTI_ENABLE_IT())
#define __HAL_COMP_EXTI_DISABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_IT() : \
__HAL_COMP_COMP6_EXTI_DISABLE_IT())
#define __HAL_COMP_EXTI_GET_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_GET_FLAG() : \
__HAL_COMP_COMP6_EXTI_GET_FLAG())
#define __HAL_COMP_EXTI_CLEAR_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_CLEAR_FLAG() : \
__HAL_COMP_COMP6_EXTI_CLEAR_FLAG())
# endif
# if defined(STM32F303xE) || defined(STM32F398xx) || defined(STM32F303xC) || defined(STM32F358xx)
#define __HAL_COMP_EXTI_RISING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_ENABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_ENABLE_RISING_EDGE() : \
__HAL_COMP_COMP7_EXTI_ENABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_RISING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_DISABLE_RISING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_DISABLE_RISING_EDGE() : \
__HAL_COMP_COMP7_EXTI_DISABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_ENABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_ENABLE_FALLING_EDGE() : \
__HAL_COMP_COMP7_EXTI_ENABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_DISABLE_FALLING_EDGE() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_DISABLE_FALLING_EDGE() : \
__HAL_COMP_COMP7_EXTI_DISABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_ENABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_ENABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_ENABLE_IT() : \
__HAL_COMP_COMP7_EXTI_ENABLE_IT())
#define __HAL_COMP_EXTI_DISABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_DISABLE_IT() : \
((__EXTILINE__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_DISABLE_IT() : \
__HAL_COMP_COMP7_EXTI_DISABLE_IT())
#define __HAL_COMP_EXTI_GET_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_GET_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_GET_FLAG() : \
__HAL_COMP_COMP7_EXTI_GET_FLAG())
#define __HAL_COMP_EXTI_CLEAR_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP2) ? __HAL_COMP_COMP2_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP3) ? __HAL_COMP_COMP3_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP4) ? __HAL_COMP_COMP4_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP5) ? __HAL_COMP_COMP5_EXTI_CLEAR_FLAG() : \
((__FLAG__) == COMP_EXTI_LINE_COMP6) ? __HAL_COMP_COMP6_EXTI_CLEAR_FLAG() : \
__HAL_COMP_COMP7_EXTI_CLEAR_FLAG())
# endif
# if defined(STM32F373xC) ||defined(STM32F378xx)
#define __HAL_COMP_EXTI_RISING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_RISING_EDGE() : \
__HAL_COMP_COMP2_EXTI_ENABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_RISING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_RISING_EDGE() : \
__HAL_COMP_COMP2_EXTI_DISABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_FALLING_EDGE() : \
__HAL_COMP_COMP2_EXTI_ENABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_FALLING_EDGE() : \
__HAL_COMP_COMP2_EXTI_DISABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_ENABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_IT() : \
__HAL_COMP_COMP2_EXTI_ENABLE_IT())
#define __HAL_COMP_EXTI_DISABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_IT() : \
__HAL_COMP_COMP2_EXTI_DISABLE_IT())
#define __HAL_COMP_EXTI_GET_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_GET_FLAG() : \
__HAL_COMP_COMP2_EXTI_GET_FLAG())
#define __HAL_COMP_EXTI_CLEAR_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_CLEAR_FLAG() : \
__HAL_COMP_COMP2_EXTI_CLEAR_FLAG())
# endif
#else
#define __HAL_COMP_EXTI_RISING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_RISING_EDGE() : \
__HAL_COMP_COMP2_EXTI_ENABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_RISING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_RISING_EDGE() : \
__HAL_COMP_COMP2_EXTI_DISABLE_RISING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_ENABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_FALLING_EDGE() : \
__HAL_COMP_COMP2_EXTI_ENABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_FALLING_IT_DISABLE(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_FALLING_EDGE() : \
__HAL_COMP_COMP2_EXTI_DISABLE_FALLING_EDGE())
#define __HAL_COMP_EXTI_ENABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_ENABLE_IT() : \
__HAL_COMP_COMP2_EXTI_ENABLE_IT())
#define __HAL_COMP_EXTI_DISABLE_IT(__EXTILINE__) (((__EXTILINE__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_DISABLE_IT() : \
__HAL_COMP_COMP2_EXTI_DISABLE_IT())
#define __HAL_COMP_EXTI_GET_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_GET_FLAG() : \
__HAL_COMP_COMP2_EXTI_GET_FLAG())
#define __HAL_COMP_EXTI_CLEAR_FLAG(__FLAG__) (((__FLAG__) == COMP_EXTI_LINE_COMP1) ? __HAL_COMP_COMP1_EXTI_CLEAR_FLAG() : \
__HAL_COMP_COMP2_EXTI_CLEAR_FLAG())
#endif
#define __HAL_COMP_GET_EXTI_LINE COMP_GET_EXTI_LINE
#if defined(STM32L0) || defined(STM32L4)
/* Note: On these STM32 families, the only argument of this macro */
/* is COMP_FLAG_LOCK. */
/* This macro is replaced by __HAL_COMP_IS_LOCKED with only HAL handle */
/* argument. */
#define __HAL_COMP_GET_FLAG(__HANDLE__, __FLAG__) (__HAL_COMP_IS_LOCKED(__HANDLE__))
#endif
/**
* @}
*/
#if defined(STM32L0) || defined(STM32L4)
/** @defgroup HAL_COMP_Aliased_Functions HAL COMP Aliased Functions maintained for legacy purpose
* @{
*/
#define HAL_COMP_Start_IT HAL_COMP_Start /* Function considered as legacy as EXTI event or IT configuration is
done into HAL_COMP_Init() */
#define HAL_COMP_Stop_IT HAL_COMP_Stop /* Function considered as legacy as EXTI event or IT configuration is
done into HAL_COMP_Init() */
/**
* @}
*/
#endif
/** @defgroup HAL_DAC_Aliased_Macros HAL DAC Aliased Macros maintained for legacy purpose
* @{
*/
#define IS_DAC_WAVE(WAVE) (((WAVE) == DAC_WAVE_NONE) || \
((WAVE) == DAC_WAVE_NOISE)|| \
((WAVE) == DAC_WAVE_TRIANGLE))
/**
* @}
*/
/** @defgroup HAL_FLASH_Aliased_Macros HAL FLASH Aliased Macros maintained for legacy purpose
* @{
*/
#define IS_WRPAREA IS_OB_WRPAREA
#define IS_TYPEPROGRAM IS_FLASH_TYPEPROGRAM
#define IS_TYPEPROGRAMFLASH IS_FLASH_TYPEPROGRAM
#define IS_TYPEERASE IS_FLASH_TYPEERASE
#define IS_NBSECTORS IS_FLASH_NBSECTORS
#define IS_OB_WDG_SOURCE IS_OB_IWDG_SOURCE
/**
* @}
*/
/** @defgroup HAL_I2C_Aliased_Macros HAL I2C Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_I2C_RESET_CR2 I2C_RESET_CR2
#define __HAL_I2C_GENERATE_START I2C_GENERATE_START
#if defined(STM32F1)
#define __HAL_I2C_FREQ_RANGE I2C_FREQRANGE
#else
#define __HAL_I2C_FREQ_RANGE I2C_FREQ_RANGE
#endif /* STM32F1 */
#define __HAL_I2C_RISE_TIME I2C_RISE_TIME
#define __HAL_I2C_SPEED_STANDARD I2C_SPEED_STANDARD
#define __HAL_I2C_SPEED_FAST I2C_SPEED_FAST
#define __HAL_I2C_SPEED I2C_SPEED
#define __HAL_I2C_7BIT_ADD_WRITE I2C_7BIT_ADD_WRITE
#define __HAL_I2C_7BIT_ADD_READ I2C_7BIT_ADD_READ
#define __HAL_I2C_10BIT_ADDRESS I2C_10BIT_ADDRESS
#define __HAL_I2C_10BIT_HEADER_WRITE I2C_10BIT_HEADER_WRITE
#define __HAL_I2C_10BIT_HEADER_READ I2C_10BIT_HEADER_READ
#define __HAL_I2C_MEM_ADD_MSB I2C_MEM_ADD_MSB
#define __HAL_I2C_MEM_ADD_LSB I2C_MEM_ADD_LSB
#define __HAL_I2C_FREQRANGE I2C_FREQRANGE
/**
* @}
*/
/** @defgroup HAL_I2S_Aliased_Macros HAL I2S Aliased Macros maintained for legacy purpose
* @{
*/
#define IS_I2S_INSTANCE IS_I2S_ALL_INSTANCE
#define IS_I2S_INSTANCE_EXT IS_I2S_ALL_INSTANCE_EXT
#if defined(STM32H7)
#define __HAL_I2S_CLEAR_FREFLAG __HAL_I2S_CLEAR_TIFREFLAG
#endif
/**
* @}
*/
/** @defgroup HAL_IRDA_Aliased_Macros HAL IRDA Aliased Macros maintained for legacy purpose
* @{
*/
#define __IRDA_DISABLE __HAL_IRDA_DISABLE
#define __IRDA_ENABLE __HAL_IRDA_ENABLE
#define __HAL_IRDA_GETCLOCKSOURCE IRDA_GETCLOCKSOURCE
#define __HAL_IRDA_MASK_COMPUTATION IRDA_MASK_COMPUTATION
#define __IRDA_GETCLOCKSOURCE IRDA_GETCLOCKSOURCE
#define __IRDA_MASK_COMPUTATION IRDA_MASK_COMPUTATION
#define IS_IRDA_ONEBIT_SAMPLE IS_IRDA_ONE_BIT_SAMPLE
/**
* @}
*/
/** @defgroup HAL_IWDG_Aliased_Macros HAL IWDG Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_IWDG_ENABLE_WRITE_ACCESS IWDG_ENABLE_WRITE_ACCESS
#define __HAL_IWDG_DISABLE_WRITE_ACCESS IWDG_DISABLE_WRITE_ACCESS
/**
* @}
*/
/** @defgroup HAL_LPTIM_Aliased_Macros HAL LPTIM Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_LPTIM_ENABLE_INTERRUPT __HAL_LPTIM_ENABLE_IT
#define __HAL_LPTIM_DISABLE_INTERRUPT __HAL_LPTIM_DISABLE_IT
#define __HAL_LPTIM_GET_ITSTATUS __HAL_LPTIM_GET_IT_SOURCE
/**
* @}
*/
/** @defgroup HAL_OPAMP_Aliased_Macros HAL OPAMP Aliased Macros maintained for legacy purpose
* @{
*/
#define __OPAMP_CSR_OPAXPD OPAMP_CSR_OPAXPD
#define __OPAMP_CSR_S3SELX OPAMP_CSR_S3SELX
#define __OPAMP_CSR_S4SELX OPAMP_CSR_S4SELX
#define __OPAMP_CSR_S5SELX OPAMP_CSR_S5SELX
#define __OPAMP_CSR_S6SELX OPAMP_CSR_S6SELX
#define __OPAMP_CSR_OPAXCAL_L OPAMP_CSR_OPAXCAL_L
#define __OPAMP_CSR_OPAXCAL_H OPAMP_CSR_OPAXCAL_H
#define __OPAMP_CSR_OPAXLPM OPAMP_CSR_OPAXLPM
#define __OPAMP_CSR_ALL_SWITCHES OPAMP_CSR_ALL_SWITCHES
#define __OPAMP_CSR_ANAWSELX OPAMP_CSR_ANAWSELX
#define __OPAMP_CSR_OPAXCALOUT OPAMP_CSR_OPAXCALOUT
#define __OPAMP_OFFSET_TRIM_BITSPOSITION OPAMP_OFFSET_TRIM_BITSPOSITION
#define __OPAMP_OFFSET_TRIM_SET OPAMP_OFFSET_TRIM_SET
/**
* @}
*/
/** @defgroup HAL_PWR_Aliased_Macros HAL PWR Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_PVD_EVENT_DISABLE __HAL_PWR_PVD_EXTI_DISABLE_EVENT
#define __HAL_PVD_EVENT_ENABLE __HAL_PWR_PVD_EXTI_ENABLE_EVENT
#define __HAL_PVD_EXTI_FALLINGTRIGGER_DISABLE __HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE
#define __HAL_PVD_EXTI_FALLINGTRIGGER_ENABLE __HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE
#define __HAL_PVD_EXTI_RISINGTRIGGER_DISABLE __HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE
#define __HAL_PVD_EXTI_RISINGTRIGGER_ENABLE __HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE
#define __HAL_PVM_EVENT_DISABLE __HAL_PWR_PVM_EVENT_DISABLE
#define __HAL_PVM_EVENT_ENABLE __HAL_PWR_PVM_EVENT_ENABLE
#define __HAL_PVM_EXTI_FALLINGTRIGGER_DISABLE __HAL_PWR_PVM_EXTI_FALLINGTRIGGER_DISABLE
#define __HAL_PVM_EXTI_FALLINGTRIGGER_ENABLE __HAL_PWR_PVM_EXTI_FALLINGTRIGGER_ENABLE
#define __HAL_PVM_EXTI_RISINGTRIGGER_DISABLE __HAL_PWR_PVM_EXTI_RISINGTRIGGER_DISABLE
#define __HAL_PVM_EXTI_RISINGTRIGGER_ENABLE __HAL_PWR_PVM_EXTI_RISINGTRIGGER_ENABLE
#define __HAL_PWR_INTERNALWAKEUP_DISABLE HAL_PWREx_DisableInternalWakeUpLine
#define __HAL_PWR_INTERNALWAKEUP_ENABLE HAL_PWREx_EnableInternalWakeUpLine
#define __HAL_PWR_PULL_UP_DOWN_CONFIG_DISABLE HAL_PWREx_DisablePullUpPullDownConfig
#define __HAL_PWR_PULL_UP_DOWN_CONFIG_ENABLE HAL_PWREx_EnablePullUpPullDownConfig
#define __HAL_PWR_PVD_EXTI_CLEAR_EGDE_TRIGGER() do { __HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE(); \
__HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE(); \
} while(0)
#define __HAL_PWR_PVD_EXTI_EVENT_DISABLE __HAL_PWR_PVD_EXTI_DISABLE_EVENT
#define __HAL_PWR_PVD_EXTI_EVENT_ENABLE __HAL_PWR_PVD_EXTI_ENABLE_EVENT
#define __HAL_PWR_PVD_EXTI_FALLINGTRIGGER_DISABLE __HAL_PWR_PVD_EXTI_DISABLE_FALLING_EDGE
#define __HAL_PWR_PVD_EXTI_FALLINGTRIGGER_ENABLE __HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE
#define __HAL_PWR_PVD_EXTI_RISINGTRIGGER_DISABLE __HAL_PWR_PVD_EXTI_DISABLE_RISING_EDGE
#define __HAL_PWR_PVD_EXTI_RISINGTRIGGER_ENABLE __HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE
#define __HAL_PWR_PVD_EXTI_SET_FALLING_EGDE_TRIGGER __HAL_PWR_PVD_EXTI_ENABLE_FALLING_EDGE
#define __HAL_PWR_PVD_EXTI_SET_RISING_EDGE_TRIGGER __HAL_PWR_PVD_EXTI_ENABLE_RISING_EDGE
#define __HAL_PWR_PVM_DISABLE() do { HAL_PWREx_DisablePVM1();HAL_PWREx_DisablePVM2(); \
HAL_PWREx_DisablePVM3();HAL_PWREx_DisablePVM4(); \
} while(0)
#define __HAL_PWR_PVM_ENABLE() do { HAL_PWREx_EnablePVM1();HAL_PWREx_EnablePVM2(); \
HAL_PWREx_EnablePVM3();HAL_PWREx_EnablePVM4(); \
} while(0)
#define __HAL_PWR_SRAM2CONTENT_PRESERVE_DISABLE HAL_PWREx_DisableSRAM2ContentRetention
#define __HAL_PWR_SRAM2CONTENT_PRESERVE_ENABLE HAL_PWREx_EnableSRAM2ContentRetention
#define __HAL_PWR_VDDIO2_DISABLE HAL_PWREx_DisableVddIO2
#define __HAL_PWR_VDDIO2_ENABLE HAL_PWREx_EnableVddIO2
#define __HAL_PWR_VDDIO2_EXTI_CLEAR_EGDE_TRIGGER __HAL_PWR_VDDIO2_EXTI_DISABLE_FALLING_EDGE
#define __HAL_PWR_VDDIO2_EXTI_SET_FALLING_EGDE_TRIGGER __HAL_PWR_VDDIO2_EXTI_ENABLE_FALLING_EDGE
#define __HAL_PWR_VDDUSB_DISABLE HAL_PWREx_DisableVddUSB
#define __HAL_PWR_VDDUSB_ENABLE HAL_PWREx_EnableVddUSB
#if defined (STM32F4)
#define __HAL_PVD_EXTI_ENABLE_IT(PWR_EXTI_LINE_PVD) __HAL_PWR_PVD_EXTI_ENABLE_IT()
#define __HAL_PVD_EXTI_DISABLE_IT(PWR_EXTI_LINE_PVD) __HAL_PWR_PVD_EXTI_DISABLE_IT()
#define __HAL_PVD_EXTI_GET_FLAG(PWR_EXTI_LINE_PVD) __HAL_PWR_PVD_EXTI_GET_FLAG()
#define __HAL_PVD_EXTI_CLEAR_FLAG(PWR_EXTI_LINE_PVD) __HAL_PWR_PVD_EXTI_CLEAR_FLAG()
#define __HAL_PVD_EXTI_GENERATE_SWIT(PWR_EXTI_LINE_PVD) __HAL_PWR_PVD_EXTI_GENERATE_SWIT()
#else
#define __HAL_PVD_EXTI_CLEAR_FLAG __HAL_PWR_PVD_EXTI_CLEAR_FLAG
#define __HAL_PVD_EXTI_DISABLE_IT __HAL_PWR_PVD_EXTI_DISABLE_IT
#define __HAL_PVD_EXTI_ENABLE_IT __HAL_PWR_PVD_EXTI_ENABLE_IT
#define __HAL_PVD_EXTI_GENERATE_SWIT __HAL_PWR_PVD_EXTI_GENERATE_SWIT
#define __HAL_PVD_EXTI_GET_FLAG __HAL_PWR_PVD_EXTI_GET_FLAG
#endif /* STM32F4 */
/**
* @}
*/
/** @defgroup HAL_RCC_Aliased HAL RCC Aliased maintained for legacy purpose
* @{
*/
#define RCC_StopWakeUpClock_MSI RCC_STOP_WAKEUPCLOCK_MSI
#define RCC_StopWakeUpClock_HSI RCC_STOP_WAKEUPCLOCK_HSI
#define HAL_RCC_CCSCallback HAL_RCC_CSSCallback
#define HAL_RC48_EnableBuffer_Cmd(cmd) (((cmd)==ENABLE) ? \
HAL_RCCEx_EnableHSI48_VREFINT() : HAL_RCCEx_DisableHSI48_VREFINT())
#define __ADC_CLK_DISABLE __HAL_RCC_ADC_CLK_DISABLE
#define __ADC_CLK_ENABLE __HAL_RCC_ADC_CLK_ENABLE
#define __ADC_CLK_SLEEP_DISABLE __HAL_RCC_ADC_CLK_SLEEP_DISABLE
#define __ADC_CLK_SLEEP_ENABLE __HAL_RCC_ADC_CLK_SLEEP_ENABLE
#define __ADC_FORCE_RESET __HAL_RCC_ADC_FORCE_RESET
#define __ADC_RELEASE_RESET __HAL_RCC_ADC_RELEASE_RESET
#define __ADC1_CLK_DISABLE __HAL_RCC_ADC1_CLK_DISABLE
#define __ADC1_CLK_ENABLE __HAL_RCC_ADC1_CLK_ENABLE
#define __ADC1_FORCE_RESET __HAL_RCC_ADC1_FORCE_RESET
#define __ADC1_RELEASE_RESET __HAL_RCC_ADC1_RELEASE_RESET
#define __ADC1_CLK_SLEEP_ENABLE __HAL_RCC_ADC1_CLK_SLEEP_ENABLE
#define __ADC1_CLK_SLEEP_DISABLE __HAL_RCC_ADC1_CLK_SLEEP_DISABLE
#define __ADC2_CLK_DISABLE __HAL_RCC_ADC2_CLK_DISABLE
#define __ADC2_CLK_ENABLE __HAL_RCC_ADC2_CLK_ENABLE
#define __ADC2_FORCE_RESET __HAL_RCC_ADC2_FORCE_RESET
#define __ADC2_RELEASE_RESET __HAL_RCC_ADC2_RELEASE_RESET
#define __ADC3_CLK_DISABLE __HAL_RCC_ADC3_CLK_DISABLE
#define __ADC3_CLK_ENABLE __HAL_RCC_ADC3_CLK_ENABLE
#define __ADC3_FORCE_RESET __HAL_RCC_ADC3_FORCE_RESET
#define __ADC3_RELEASE_RESET __HAL_RCC_ADC3_RELEASE_RESET
#define __AES_CLK_DISABLE __HAL_RCC_AES_CLK_DISABLE
#define __AES_CLK_ENABLE __HAL_RCC_AES_CLK_ENABLE
#define __AES_CLK_SLEEP_DISABLE __HAL_RCC_AES_CLK_SLEEP_DISABLE
#define __AES_CLK_SLEEP_ENABLE __HAL_RCC_AES_CLK_SLEEP_ENABLE
#define __AES_FORCE_RESET __HAL_RCC_AES_FORCE_RESET
#define __AES_RELEASE_RESET __HAL_RCC_AES_RELEASE_RESET
#define __CRYP_CLK_SLEEP_ENABLE __HAL_RCC_CRYP_CLK_SLEEP_ENABLE
#define __CRYP_CLK_SLEEP_DISABLE __HAL_RCC_CRYP_CLK_SLEEP_DISABLE
#define __CRYP_CLK_ENABLE __HAL_RCC_CRYP_CLK_ENABLE
#define __CRYP_CLK_DISABLE __HAL_RCC_CRYP_CLK_DISABLE
#define __CRYP_FORCE_RESET __HAL_RCC_CRYP_FORCE_RESET
#define __CRYP_RELEASE_RESET __HAL_RCC_CRYP_RELEASE_RESET
#define __AFIO_CLK_DISABLE __HAL_RCC_AFIO_CLK_DISABLE
#define __AFIO_CLK_ENABLE __HAL_RCC_AFIO_CLK_ENABLE
#define __AFIO_FORCE_RESET __HAL_RCC_AFIO_FORCE_RESET
#define __AFIO_RELEASE_RESET __HAL_RCC_AFIO_RELEASE_RESET
#define __AHB_FORCE_RESET __HAL_RCC_AHB_FORCE_RESET
#define __AHB_RELEASE_RESET __HAL_RCC_AHB_RELEASE_RESET
#define __AHB1_FORCE_RESET __HAL_RCC_AHB1_FORCE_RESET
#define __AHB1_RELEASE_RESET __HAL_RCC_AHB1_RELEASE_RESET
#define __AHB2_FORCE_RESET __HAL_RCC_AHB2_FORCE_RESET
#define __AHB2_RELEASE_RESET __HAL_RCC_AHB2_RELEASE_RESET
#define __AHB3_FORCE_RESET __HAL_RCC_AHB3_FORCE_RESET
#define __AHB3_RELEASE_RESET __HAL_RCC_AHB3_RELEASE_RESET
#define __APB1_FORCE_RESET __HAL_RCC_APB1_FORCE_RESET
#define __APB1_RELEASE_RESET __HAL_RCC_APB1_RELEASE_RESET
#define __APB2_FORCE_RESET __HAL_RCC_APB2_FORCE_RESET
#define __APB2_RELEASE_RESET __HAL_RCC_APB2_RELEASE_RESET
#define __BKP_CLK_DISABLE __HAL_RCC_BKP_CLK_DISABLE
#define __BKP_CLK_ENABLE __HAL_RCC_BKP_CLK_ENABLE
#define __BKP_FORCE_RESET __HAL_RCC_BKP_FORCE_RESET
#define __BKP_RELEASE_RESET __HAL_RCC_BKP_RELEASE_RESET
#define __CAN1_CLK_DISABLE __HAL_RCC_CAN1_CLK_DISABLE
#define __CAN1_CLK_ENABLE __HAL_RCC_CAN1_CLK_ENABLE
#define __CAN1_CLK_SLEEP_DISABLE __HAL_RCC_CAN1_CLK_SLEEP_DISABLE
#define __CAN1_CLK_SLEEP_ENABLE __HAL_RCC_CAN1_CLK_SLEEP_ENABLE
#define __CAN1_FORCE_RESET __HAL_RCC_CAN1_FORCE_RESET
#define __CAN1_RELEASE_RESET __HAL_RCC_CAN1_RELEASE_RESET
#define __CAN_CLK_DISABLE __HAL_RCC_CAN1_CLK_DISABLE
#define __CAN_CLK_ENABLE __HAL_RCC_CAN1_CLK_ENABLE
#define __CAN_FORCE_RESET __HAL_RCC_CAN1_FORCE_RESET
#define __CAN_RELEASE_RESET __HAL_RCC_CAN1_RELEASE_RESET
#define __CAN2_CLK_DISABLE __HAL_RCC_CAN2_CLK_DISABLE
#define __CAN2_CLK_ENABLE __HAL_RCC_CAN2_CLK_ENABLE
#define __CAN2_FORCE_RESET __HAL_RCC_CAN2_FORCE_RESET
#define __CAN2_RELEASE_RESET __HAL_RCC_CAN2_RELEASE_RESET
#define __CEC_CLK_DISABLE __HAL_RCC_CEC_CLK_DISABLE
#define __CEC_CLK_ENABLE __HAL_RCC_CEC_CLK_ENABLE
#define __COMP_CLK_DISABLE __HAL_RCC_COMP_CLK_DISABLE
#define __COMP_CLK_ENABLE __HAL_RCC_COMP_CLK_ENABLE
#define __COMP_FORCE_RESET __HAL_RCC_COMP_FORCE_RESET
#define __COMP_RELEASE_RESET __HAL_RCC_COMP_RELEASE_RESET
#define __COMP_CLK_SLEEP_ENABLE __HAL_RCC_COMP_CLK_SLEEP_ENABLE
#define __COMP_CLK_SLEEP_DISABLE __HAL_RCC_COMP_CLK_SLEEP_DISABLE
#define __CEC_FORCE_RESET __HAL_RCC_CEC_FORCE_RESET
#define __CEC_RELEASE_RESET __HAL_RCC_CEC_RELEASE_RESET
#define __CRC_CLK_DISABLE __HAL_RCC_CRC_CLK_DISABLE
#define __CRC_CLK_ENABLE __HAL_RCC_CRC_CLK_ENABLE
#define __CRC_CLK_SLEEP_DISABLE __HAL_RCC_CRC_CLK_SLEEP_DISABLE
#define __CRC_CLK_SLEEP_ENABLE __HAL_RCC_CRC_CLK_SLEEP_ENABLE
#define __CRC_FORCE_RESET __HAL_RCC_CRC_FORCE_RESET
#define __CRC_RELEASE_RESET __HAL_RCC_CRC_RELEASE_RESET
#define __DAC_CLK_DISABLE __HAL_RCC_DAC_CLK_DISABLE
#define __DAC_CLK_ENABLE __HAL_RCC_DAC_CLK_ENABLE
#define __DAC_FORCE_RESET __HAL_RCC_DAC_FORCE_RESET
#define __DAC_RELEASE_RESET __HAL_RCC_DAC_RELEASE_RESET
#define __DAC1_CLK_DISABLE __HAL_RCC_DAC1_CLK_DISABLE
#define __DAC1_CLK_ENABLE __HAL_RCC_DAC1_CLK_ENABLE
#define __DAC1_CLK_SLEEP_DISABLE __HAL_RCC_DAC1_CLK_SLEEP_DISABLE
#define __DAC1_CLK_SLEEP_ENABLE __HAL_RCC_DAC1_CLK_SLEEP_ENABLE
#define __DAC1_FORCE_RESET __HAL_RCC_DAC1_FORCE_RESET
#define __DAC1_RELEASE_RESET __HAL_RCC_DAC1_RELEASE_RESET
#define __DBGMCU_CLK_ENABLE __HAL_RCC_DBGMCU_CLK_ENABLE
#define __DBGMCU_CLK_DISABLE __HAL_RCC_DBGMCU_CLK_DISABLE
#define __DBGMCU_FORCE_RESET __HAL_RCC_DBGMCU_FORCE_RESET
#define __DBGMCU_RELEASE_RESET __HAL_RCC_DBGMCU_RELEASE_RESET
#define __DFSDM_CLK_DISABLE __HAL_RCC_DFSDM_CLK_DISABLE
#define __DFSDM_CLK_ENABLE __HAL_RCC_DFSDM_CLK_ENABLE
#define __DFSDM_CLK_SLEEP_DISABLE __HAL_RCC_DFSDM_CLK_SLEEP_DISABLE
#define __DFSDM_CLK_SLEEP_ENABLE __HAL_RCC_DFSDM_CLK_SLEEP_ENABLE
#define __DFSDM_FORCE_RESET __HAL_RCC_DFSDM_FORCE_RESET
#define __DFSDM_RELEASE_RESET __HAL_RCC_DFSDM_RELEASE_RESET
#define __DMA1_CLK_DISABLE __HAL_RCC_DMA1_CLK_DISABLE
#define __DMA1_CLK_ENABLE __HAL_RCC_DMA1_CLK_ENABLE
#define __DMA1_CLK_SLEEP_DISABLE __HAL_RCC_DMA1_CLK_SLEEP_DISABLE
#define __DMA1_CLK_SLEEP_ENABLE __HAL_RCC_DMA1_CLK_SLEEP_ENABLE
#define __DMA1_FORCE_RESET __HAL_RCC_DMA1_FORCE_RESET
#define __DMA1_RELEASE_RESET __HAL_RCC_DMA1_RELEASE_RESET
#define __DMA2_CLK_DISABLE __HAL_RCC_DMA2_CLK_DISABLE
#define __DMA2_CLK_ENABLE __HAL_RCC_DMA2_CLK_ENABLE
#define __DMA2_CLK_SLEEP_DISABLE __HAL_RCC_DMA2_CLK_SLEEP_DISABLE
#define __DMA2_CLK_SLEEP_ENABLE __HAL_RCC_DMA2_CLK_SLEEP_ENABLE
#define __DMA2_FORCE_RESET __HAL_RCC_DMA2_FORCE_RESET
#define __DMA2_RELEASE_RESET __HAL_RCC_DMA2_RELEASE_RESET
#define __ETHMAC_CLK_DISABLE __HAL_RCC_ETHMAC_CLK_DISABLE
#define __ETHMAC_CLK_ENABLE __HAL_RCC_ETHMAC_CLK_ENABLE
#define __ETHMAC_FORCE_RESET __HAL_RCC_ETHMAC_FORCE_RESET
#define __ETHMAC_RELEASE_RESET __HAL_RCC_ETHMAC_RELEASE_RESET
#define __ETHMACRX_CLK_DISABLE __HAL_RCC_ETHMACRX_CLK_DISABLE
#define __ETHMACRX_CLK_ENABLE __HAL_RCC_ETHMACRX_CLK_ENABLE
#define __ETHMACTX_CLK_DISABLE __HAL_RCC_ETHMACTX_CLK_DISABLE
#define __ETHMACTX_CLK_ENABLE __HAL_RCC_ETHMACTX_CLK_ENABLE
#define __FIREWALL_CLK_DISABLE __HAL_RCC_FIREWALL_CLK_DISABLE
#define __FIREWALL_CLK_ENABLE __HAL_RCC_FIREWALL_CLK_ENABLE
#define __FLASH_CLK_DISABLE __HAL_RCC_FLASH_CLK_DISABLE
#define __FLASH_CLK_ENABLE __HAL_RCC_FLASH_CLK_ENABLE
#define __FLASH_CLK_SLEEP_DISABLE __HAL_RCC_FLASH_CLK_SLEEP_DISABLE
#define __FLASH_CLK_SLEEP_ENABLE __HAL_RCC_FLASH_CLK_SLEEP_ENABLE
#define __FLASH_FORCE_RESET __HAL_RCC_FLASH_FORCE_RESET
#define __FLASH_RELEASE_RESET __HAL_RCC_FLASH_RELEASE_RESET
#define __FLITF_CLK_DISABLE __HAL_RCC_FLITF_CLK_DISABLE
#define __FLITF_CLK_ENABLE __HAL_RCC_FLITF_CLK_ENABLE
#define __FLITF_FORCE_RESET __HAL_RCC_FLITF_FORCE_RESET
#define __FLITF_RELEASE_RESET __HAL_RCC_FLITF_RELEASE_RESET
#define __FLITF_CLK_SLEEP_ENABLE __HAL_RCC_FLITF_CLK_SLEEP_ENABLE
#define __FLITF_CLK_SLEEP_DISABLE __HAL_RCC_FLITF_CLK_SLEEP_DISABLE
#define __FMC_CLK_DISABLE __HAL_RCC_FMC_CLK_DISABLE
#define __FMC_CLK_ENABLE __HAL_RCC_FMC_CLK_ENABLE
#define __FMC_CLK_SLEEP_DISABLE __HAL_RCC_FMC_CLK_SLEEP_DISABLE
#define __FMC_CLK_SLEEP_ENABLE __HAL_RCC_FMC_CLK_SLEEP_ENABLE
#define __FMC_FORCE_RESET __HAL_RCC_FMC_FORCE_RESET
#define __FMC_RELEASE_RESET __HAL_RCC_FMC_RELEASE_RESET
#define __FSMC_CLK_DISABLE __HAL_RCC_FSMC_CLK_DISABLE
#define __FSMC_CLK_ENABLE __HAL_RCC_FSMC_CLK_ENABLE
#define __GPIOA_CLK_DISABLE __HAL_RCC_GPIOA_CLK_DISABLE
#define __GPIOA_CLK_ENABLE __HAL_RCC_GPIOA_CLK_ENABLE
#define __GPIOA_CLK_SLEEP_DISABLE __HAL_RCC_GPIOA_CLK_SLEEP_DISABLE
#define __GPIOA_CLK_SLEEP_ENABLE __HAL_RCC_GPIOA_CLK_SLEEP_ENABLE
#define __GPIOA_FORCE_RESET __HAL_RCC_GPIOA_FORCE_RESET
#define __GPIOA_RELEASE_RESET __HAL_RCC_GPIOA_RELEASE_RESET
#define __GPIOB_CLK_DISABLE __HAL_RCC_GPIOB_CLK_DISABLE
#define __GPIOB_CLK_ENABLE __HAL_RCC_GPIOB_CLK_ENABLE
#define __GPIOB_CLK_SLEEP_DISABLE __HAL_RCC_GPIOB_CLK_SLEEP_DISABLE
#define __GPIOB_CLK_SLEEP_ENABLE __HAL_RCC_GPIOB_CLK_SLEEP_ENABLE
#define __GPIOB_FORCE_RESET __HAL_RCC_GPIOB_FORCE_RESET
#define __GPIOB_RELEASE_RESET __HAL_RCC_GPIOB_RELEASE_RESET
#define __GPIOC_CLK_DISABLE __HAL_RCC_GPIOC_CLK_DISABLE
#define __GPIOC_CLK_ENABLE __HAL_RCC_GPIOC_CLK_ENABLE
#define __GPIOC_CLK_SLEEP_DISABLE __HAL_RCC_GPIOC_CLK_SLEEP_DISABLE
#define __GPIOC_CLK_SLEEP_ENABLE __HAL_RCC_GPIOC_CLK_SLEEP_ENABLE
#define __GPIOC_FORCE_RESET __HAL_RCC_GPIOC_FORCE_RESET
#define __GPIOC_RELEASE_RESET __HAL_RCC_GPIOC_RELEASE_RESET
#define __GPIOD_CLK_DISABLE __HAL_RCC_GPIOD_CLK_DISABLE
#define __GPIOD_CLK_ENABLE __HAL_RCC_GPIOD_CLK_ENABLE
#define __GPIOD_CLK_SLEEP_DISABLE __HAL_RCC_GPIOD_CLK_SLEEP_DISABLE
#define __GPIOD_CLK_SLEEP_ENABLE __HAL_RCC_GPIOD_CLK_SLEEP_ENABLE
#define __GPIOD_FORCE_RESET __HAL_RCC_GPIOD_FORCE_RESET
#define __GPIOD_RELEASE_RESET __HAL_RCC_GPIOD_RELEASE_RESET
#define __GPIOE_CLK_DISABLE __HAL_RCC_GPIOE_CLK_DISABLE
#define __GPIOE_CLK_ENABLE __HAL_RCC_GPIOE_CLK_ENABLE
#define __GPIOE_CLK_SLEEP_DISABLE __HAL_RCC_GPIOE_CLK_SLEEP_DISABLE
#define __GPIOE_CLK_SLEEP_ENABLE __HAL_RCC_GPIOE_CLK_SLEEP_ENABLE
#define __GPIOE_FORCE_RESET __HAL_RCC_GPIOE_FORCE_RESET
#define __GPIOE_RELEASE_RESET __HAL_RCC_GPIOE_RELEASE_RESET
#define __GPIOF_CLK_DISABLE __HAL_RCC_GPIOF_CLK_DISABLE
#define __GPIOF_CLK_ENABLE __HAL_RCC_GPIOF_CLK_ENABLE
#define __GPIOF_CLK_SLEEP_DISABLE __HAL_RCC_GPIOF_CLK_SLEEP_DISABLE
#define __GPIOF_CLK_SLEEP_ENABLE __HAL_RCC_GPIOF_CLK_SLEEP_ENABLE
#define __GPIOF_FORCE_RESET __HAL_RCC_GPIOF_FORCE_RESET
#define __GPIOF_RELEASE_RESET __HAL_RCC_GPIOF_RELEASE_RESET
#define __GPIOG_CLK_DISABLE __HAL_RCC_GPIOG_CLK_DISABLE
#define __GPIOG_CLK_ENABLE __HAL_RCC_GPIOG_CLK_ENABLE
#define __GPIOG_CLK_SLEEP_DISABLE __HAL_RCC_GPIOG_CLK_SLEEP_DISABLE
#define __GPIOG_CLK_SLEEP_ENABLE __HAL_RCC_GPIOG_CLK_SLEEP_ENABLE
#define __GPIOG_FORCE_RESET __HAL_RCC_GPIOG_FORCE_RESET
#define __GPIOG_RELEASE_RESET __HAL_RCC_GPIOG_RELEASE_RESET
#define __GPIOH_CLK_DISABLE __HAL_RCC_GPIOH_CLK_DISABLE
#define __GPIOH_CLK_ENABLE __HAL_RCC_GPIOH_CLK_ENABLE
#define __GPIOH_CLK_SLEEP_DISABLE __HAL_RCC_GPIOH_CLK_SLEEP_DISABLE
#define __GPIOH_CLK_SLEEP_ENABLE __HAL_RCC_GPIOH_CLK_SLEEP_ENABLE
#define __GPIOH_FORCE_RESET __HAL_RCC_GPIOH_FORCE_RESET
#define __GPIOH_RELEASE_RESET __HAL_RCC_GPIOH_RELEASE_RESET
#define __I2C1_CLK_DISABLE __HAL_RCC_I2C1_CLK_DISABLE
#define __I2C1_CLK_ENABLE __HAL_RCC_I2C1_CLK_ENABLE
#define __I2C1_CLK_SLEEP_DISABLE __HAL_RCC_I2C1_CLK_SLEEP_DISABLE
#define __I2C1_CLK_SLEEP_ENABLE __HAL_RCC_I2C1_CLK_SLEEP_ENABLE
#define __I2C1_FORCE_RESET __HAL_RCC_I2C1_FORCE_RESET
#define __I2C1_RELEASE_RESET __HAL_RCC_I2C1_RELEASE_RESET
#define __I2C2_CLK_DISABLE __HAL_RCC_I2C2_CLK_DISABLE
#define __I2C2_CLK_ENABLE __HAL_RCC_I2C2_CLK_ENABLE
#define __I2C2_CLK_SLEEP_DISABLE __HAL_RCC_I2C2_CLK_SLEEP_DISABLE
#define __I2C2_CLK_SLEEP_ENABLE __HAL_RCC_I2C2_CLK_SLEEP_ENABLE
#define __I2C2_FORCE_RESET __HAL_RCC_I2C2_FORCE_RESET
#define __I2C2_RELEASE_RESET __HAL_RCC_I2C2_RELEASE_RESET
#define __I2C3_CLK_DISABLE __HAL_RCC_I2C3_CLK_DISABLE
#define __I2C3_CLK_ENABLE __HAL_RCC_I2C3_CLK_ENABLE
#define __I2C3_CLK_SLEEP_DISABLE __HAL_RCC_I2C3_CLK_SLEEP_DISABLE
#define __I2C3_CLK_SLEEP_ENABLE __HAL_RCC_I2C3_CLK_SLEEP_ENABLE
#define __I2C3_FORCE_RESET __HAL_RCC_I2C3_FORCE_RESET
#define __I2C3_RELEASE_RESET __HAL_RCC_I2C3_RELEASE_RESET
#define __LCD_CLK_DISABLE __HAL_RCC_LCD_CLK_DISABLE
#define __LCD_CLK_ENABLE __HAL_RCC_LCD_CLK_ENABLE
#define __LCD_CLK_SLEEP_DISABLE __HAL_RCC_LCD_CLK_SLEEP_DISABLE
#define __LCD_CLK_SLEEP_ENABLE __HAL_RCC_LCD_CLK_SLEEP_ENABLE
#define __LCD_FORCE_RESET __HAL_RCC_LCD_FORCE_RESET
#define __LCD_RELEASE_RESET __HAL_RCC_LCD_RELEASE_RESET
#define __LPTIM1_CLK_DISABLE __HAL_RCC_LPTIM1_CLK_DISABLE
#define __LPTIM1_CLK_ENABLE __HAL_RCC_LPTIM1_CLK_ENABLE
#define __LPTIM1_CLK_SLEEP_DISABLE __HAL_RCC_LPTIM1_CLK_SLEEP_DISABLE
#define __LPTIM1_CLK_SLEEP_ENABLE __HAL_RCC_LPTIM1_CLK_SLEEP_ENABLE
#define __LPTIM1_FORCE_RESET __HAL_RCC_LPTIM1_FORCE_RESET
#define __LPTIM1_RELEASE_RESET __HAL_RCC_LPTIM1_RELEASE_RESET
#define __LPTIM2_CLK_DISABLE __HAL_RCC_LPTIM2_CLK_DISABLE
#define __LPTIM2_CLK_ENABLE __HAL_RCC_LPTIM2_CLK_ENABLE
#define __LPTIM2_CLK_SLEEP_DISABLE __HAL_RCC_LPTIM2_CLK_SLEEP_DISABLE
#define __LPTIM2_CLK_SLEEP_ENABLE __HAL_RCC_LPTIM2_CLK_SLEEP_ENABLE
#define __LPTIM2_FORCE_RESET __HAL_RCC_LPTIM2_FORCE_RESET
#define __LPTIM2_RELEASE_RESET __HAL_RCC_LPTIM2_RELEASE_RESET
#define __LPUART1_CLK_DISABLE __HAL_RCC_LPUART1_CLK_DISABLE
#define __LPUART1_CLK_ENABLE __HAL_RCC_LPUART1_CLK_ENABLE
#define __LPUART1_CLK_SLEEP_DISABLE __HAL_RCC_LPUART1_CLK_SLEEP_DISABLE
#define __LPUART1_CLK_SLEEP_ENABLE __HAL_RCC_LPUART1_CLK_SLEEP_ENABLE
#define __LPUART1_FORCE_RESET __HAL_RCC_LPUART1_FORCE_RESET
#define __LPUART1_RELEASE_RESET __HAL_RCC_LPUART1_RELEASE_RESET
#define __OPAMP_CLK_DISABLE __HAL_RCC_OPAMP_CLK_DISABLE
#define __OPAMP_CLK_ENABLE __HAL_RCC_OPAMP_CLK_ENABLE
#define __OPAMP_CLK_SLEEP_DISABLE __HAL_RCC_OPAMP_CLK_SLEEP_DISABLE
#define __OPAMP_CLK_SLEEP_ENABLE __HAL_RCC_OPAMP_CLK_SLEEP_ENABLE
#define __OPAMP_FORCE_RESET __HAL_RCC_OPAMP_FORCE_RESET
#define __OPAMP_RELEASE_RESET __HAL_RCC_OPAMP_RELEASE_RESET
#define __OTGFS_CLK_DISABLE __HAL_RCC_OTGFS_CLK_DISABLE
#define __OTGFS_CLK_ENABLE __HAL_RCC_OTGFS_CLK_ENABLE
#define __OTGFS_CLK_SLEEP_DISABLE __HAL_RCC_OTGFS_CLK_SLEEP_DISABLE
#define __OTGFS_CLK_SLEEP_ENABLE __HAL_RCC_OTGFS_CLK_SLEEP_ENABLE
#define __OTGFS_FORCE_RESET __HAL_RCC_OTGFS_FORCE_RESET
#define __OTGFS_RELEASE_RESET __HAL_RCC_OTGFS_RELEASE_RESET
#define __PWR_CLK_DISABLE __HAL_RCC_PWR_CLK_DISABLE
#define __PWR_CLK_ENABLE __HAL_RCC_PWR_CLK_ENABLE
#define __PWR_CLK_SLEEP_DISABLE __HAL_RCC_PWR_CLK_SLEEP_DISABLE
#define __PWR_CLK_SLEEP_ENABLE __HAL_RCC_PWR_CLK_SLEEP_ENABLE
#define __PWR_FORCE_RESET __HAL_RCC_PWR_FORCE_RESET
#define __PWR_RELEASE_RESET __HAL_RCC_PWR_RELEASE_RESET
#define __QSPI_CLK_DISABLE __HAL_RCC_QSPI_CLK_DISABLE
#define __QSPI_CLK_ENABLE __HAL_RCC_QSPI_CLK_ENABLE
#define __QSPI_CLK_SLEEP_DISABLE __HAL_RCC_QSPI_CLK_SLEEP_DISABLE
#define __QSPI_CLK_SLEEP_ENABLE __HAL_RCC_QSPI_CLK_SLEEP_ENABLE
#define __QSPI_FORCE_RESET __HAL_RCC_QSPI_FORCE_RESET
#define __QSPI_RELEASE_RESET __HAL_RCC_QSPI_RELEASE_RESET
#if defined(STM32WB)
#define __HAL_RCC_QSPI_CLK_DISABLE __HAL_RCC_QUADSPI_CLK_DISABLE
#define __HAL_RCC_QSPI_CLK_ENABLE __HAL_RCC_QUADSPI_CLK_ENABLE
#define __HAL_RCC_QSPI_CLK_SLEEP_DISABLE __HAL_RCC_QUADSPI_CLK_SLEEP_DISABLE
#define __HAL_RCC_QSPI_CLK_SLEEP_ENABLE __HAL_RCC_QUADSPI_CLK_SLEEP_ENABLE
#define __HAL_RCC_QSPI_FORCE_RESET __HAL_RCC_QUADSPI_FORCE_RESET
#define __HAL_RCC_QSPI_RELEASE_RESET __HAL_RCC_QUADSPI_RELEASE_RESET
#define __HAL_RCC_QSPI_IS_CLK_ENABLED __HAL_RCC_QUADSPI_IS_CLK_ENABLED
#define __HAL_RCC_QSPI_IS_CLK_DISABLED __HAL_RCC_QUADSPI_IS_CLK_DISABLED
#define __HAL_RCC_QSPI_IS_CLK_SLEEP_ENABLED __HAL_RCC_QUADSPI_IS_CLK_SLEEP_ENABLED
#define __HAL_RCC_QSPI_IS_CLK_SLEEP_DISABLED __HAL_RCC_QUADSPI_IS_CLK_SLEEP_DISABLED
#define QSPI_IRQHandler QUADSPI_IRQHandler
#endif /* __HAL_RCC_QUADSPI_CLK_ENABLE */
#define __RNG_CLK_DISABLE __HAL_RCC_RNG_CLK_DISABLE
#define __RNG_CLK_ENABLE __HAL_RCC_RNG_CLK_ENABLE
#define __RNG_CLK_SLEEP_DISABLE __HAL_RCC_RNG_CLK_SLEEP_DISABLE
#define __RNG_CLK_SLEEP_ENABLE __HAL_RCC_RNG_CLK_SLEEP_ENABLE
#define __RNG_FORCE_RESET __HAL_RCC_RNG_FORCE_RESET
#define __RNG_RELEASE_RESET __HAL_RCC_RNG_RELEASE_RESET
#define __SAI1_CLK_DISABLE __HAL_RCC_SAI1_CLK_DISABLE
#define __SAI1_CLK_ENABLE __HAL_RCC_SAI1_CLK_ENABLE
#define __SAI1_CLK_SLEEP_DISABLE __HAL_RCC_SAI1_CLK_SLEEP_DISABLE
#define __SAI1_CLK_SLEEP_ENABLE __HAL_RCC_SAI1_CLK_SLEEP_ENABLE
#define __SAI1_FORCE_RESET __HAL_RCC_SAI1_FORCE_RESET
#define __SAI1_RELEASE_RESET __HAL_RCC_SAI1_RELEASE_RESET
#define __SAI2_CLK_DISABLE __HAL_RCC_SAI2_CLK_DISABLE
#define __SAI2_CLK_ENABLE __HAL_RCC_SAI2_CLK_ENABLE
#define __SAI2_CLK_SLEEP_DISABLE __HAL_RCC_SAI2_CLK_SLEEP_DISABLE
#define __SAI2_CLK_SLEEP_ENABLE __HAL_RCC_SAI2_CLK_SLEEP_ENABLE
#define __SAI2_FORCE_RESET __HAL_RCC_SAI2_FORCE_RESET
#define __SAI2_RELEASE_RESET __HAL_RCC_SAI2_RELEASE_RESET
#define __SDIO_CLK_DISABLE __HAL_RCC_SDIO_CLK_DISABLE
#define __SDIO_CLK_ENABLE __HAL_RCC_SDIO_CLK_ENABLE
#define __SDMMC_CLK_DISABLE __HAL_RCC_SDMMC_CLK_DISABLE
#define __SDMMC_CLK_ENABLE __HAL_RCC_SDMMC_CLK_ENABLE
#define __SDMMC_CLK_SLEEP_DISABLE __HAL_RCC_SDMMC_CLK_SLEEP_DISABLE
#define __SDMMC_CLK_SLEEP_ENABLE __HAL_RCC_SDMMC_CLK_SLEEP_ENABLE
#define __SDMMC_FORCE_RESET __HAL_RCC_SDMMC_FORCE_RESET
#define __SDMMC_RELEASE_RESET __HAL_RCC_SDMMC_RELEASE_RESET
#define __SPI1_CLK_DISABLE __HAL_RCC_SPI1_CLK_DISABLE
#define __SPI1_CLK_ENABLE __HAL_RCC_SPI1_CLK_ENABLE
#define __SPI1_CLK_SLEEP_DISABLE __HAL_RCC_SPI1_CLK_SLEEP_DISABLE
#define __SPI1_CLK_SLEEP_ENABLE __HAL_RCC_SPI1_CLK_SLEEP_ENABLE
#define __SPI1_FORCE_RESET __HAL_RCC_SPI1_FORCE_RESET
#define __SPI1_RELEASE_RESET __HAL_RCC_SPI1_RELEASE_RESET
#define __SPI2_CLK_DISABLE __HAL_RCC_SPI2_CLK_DISABLE
#define __SPI2_CLK_ENABLE __HAL_RCC_SPI2_CLK_ENABLE
#define __SPI2_CLK_SLEEP_DISABLE __HAL_RCC_SPI2_CLK_SLEEP_DISABLE
#define __SPI2_CLK_SLEEP_ENABLE __HAL_RCC_SPI2_CLK_SLEEP_ENABLE
#define __SPI2_FORCE_RESET __HAL_RCC_SPI2_FORCE_RESET
#define __SPI2_RELEASE_RESET __HAL_RCC_SPI2_RELEASE_RESET
#define __SPI3_CLK_DISABLE __HAL_RCC_SPI3_CLK_DISABLE
#define __SPI3_CLK_ENABLE __HAL_RCC_SPI3_CLK_ENABLE
#define __SPI3_CLK_SLEEP_DISABLE __HAL_RCC_SPI3_CLK_SLEEP_DISABLE
#define __SPI3_CLK_SLEEP_ENABLE __HAL_RCC_SPI3_CLK_SLEEP_ENABLE
#define __SPI3_FORCE_RESET __HAL_RCC_SPI3_FORCE_RESET
#define __SPI3_RELEASE_RESET __HAL_RCC_SPI3_RELEASE_RESET
#define __SRAM_CLK_DISABLE __HAL_RCC_SRAM_CLK_DISABLE
#define __SRAM_CLK_ENABLE __HAL_RCC_SRAM_CLK_ENABLE
#define __SRAM1_CLK_SLEEP_DISABLE __HAL_RCC_SRAM1_CLK_SLEEP_DISABLE
#define __SRAM1_CLK_SLEEP_ENABLE __HAL_RCC_SRAM1_CLK_SLEEP_ENABLE
#define __SRAM2_CLK_SLEEP_DISABLE __HAL_RCC_SRAM2_CLK_SLEEP_DISABLE
#define __SRAM2_CLK_SLEEP_ENABLE __HAL_RCC_SRAM2_CLK_SLEEP_ENABLE
#define __SWPMI1_CLK_DISABLE __HAL_RCC_SWPMI1_CLK_DISABLE
#define __SWPMI1_CLK_ENABLE __HAL_RCC_SWPMI1_CLK_ENABLE
#define __SWPMI1_CLK_SLEEP_DISABLE __HAL_RCC_SWPMI1_CLK_SLEEP_DISABLE
#define __SWPMI1_CLK_SLEEP_ENABLE __HAL_RCC_SWPMI1_CLK_SLEEP_ENABLE
#define __SWPMI1_FORCE_RESET __HAL_RCC_SWPMI1_FORCE_RESET
#define __SWPMI1_RELEASE_RESET __HAL_RCC_SWPMI1_RELEASE_RESET
#define __SYSCFG_CLK_DISABLE __HAL_RCC_SYSCFG_CLK_DISABLE
#define __SYSCFG_CLK_ENABLE __HAL_RCC_SYSCFG_CLK_ENABLE
#define __SYSCFG_CLK_SLEEP_DISABLE __HAL_RCC_SYSCFG_CLK_SLEEP_DISABLE
#define __SYSCFG_CLK_SLEEP_ENABLE __HAL_RCC_SYSCFG_CLK_SLEEP_ENABLE
#define __SYSCFG_FORCE_RESET __HAL_RCC_SYSCFG_FORCE_RESET
#define __SYSCFG_RELEASE_RESET __HAL_RCC_SYSCFG_RELEASE_RESET
#define __TIM1_CLK_DISABLE __HAL_RCC_TIM1_CLK_DISABLE
#define __TIM1_CLK_ENABLE __HAL_RCC_TIM1_CLK_ENABLE
#define __TIM1_CLK_SLEEP_DISABLE __HAL_RCC_TIM1_CLK_SLEEP_DISABLE
#define __TIM1_CLK_SLEEP_ENABLE __HAL_RCC_TIM1_CLK_SLEEP_ENABLE
#define __TIM1_FORCE_RESET __HAL_RCC_TIM1_FORCE_RESET
#define __TIM1_RELEASE_RESET __HAL_RCC_TIM1_RELEASE_RESET
#define __TIM10_CLK_DISABLE __HAL_RCC_TIM10_CLK_DISABLE
#define __TIM10_CLK_ENABLE __HAL_RCC_TIM10_CLK_ENABLE
#define __TIM10_FORCE_RESET __HAL_RCC_TIM10_FORCE_RESET
#define __TIM10_RELEASE_RESET __HAL_RCC_TIM10_RELEASE_RESET
#define __TIM11_CLK_DISABLE __HAL_RCC_TIM11_CLK_DISABLE
#define __TIM11_CLK_ENABLE __HAL_RCC_TIM11_CLK_ENABLE
#define __TIM11_FORCE_RESET __HAL_RCC_TIM11_FORCE_RESET
#define __TIM11_RELEASE_RESET __HAL_RCC_TIM11_RELEASE_RESET
#define __TIM12_CLK_DISABLE __HAL_RCC_TIM12_CLK_DISABLE
#define __TIM12_CLK_ENABLE __HAL_RCC_TIM12_CLK_ENABLE
#define __TIM12_FORCE_RESET __HAL_RCC_TIM12_FORCE_RESET
#define __TIM12_RELEASE_RESET __HAL_RCC_TIM12_RELEASE_RESET
#define __TIM13_CLK_DISABLE __HAL_RCC_TIM13_CLK_DISABLE
#define __TIM13_CLK_ENABLE __HAL_RCC_TIM13_CLK_ENABLE
#define __TIM13_FORCE_RESET __HAL_RCC_TIM13_FORCE_RESET
#define __TIM13_RELEASE_RESET __HAL_RCC_TIM13_RELEASE_RESET
#define __TIM14_CLK_DISABLE __HAL_RCC_TIM14_CLK_DISABLE
#define __TIM14_CLK_ENABLE __HAL_RCC_TIM14_CLK_ENABLE
#define __TIM14_FORCE_RESET __HAL_RCC_TIM14_FORCE_RESET
#define __TIM14_RELEASE_RESET __HAL_RCC_TIM14_RELEASE_RESET
#define __TIM15_CLK_DISABLE __HAL_RCC_TIM15_CLK_DISABLE
#define __TIM15_CLK_ENABLE __HAL_RCC_TIM15_CLK_ENABLE
#define __TIM15_CLK_SLEEP_DISABLE __HAL_RCC_TIM15_CLK_SLEEP_DISABLE
#define __TIM15_CLK_SLEEP_ENABLE __HAL_RCC_TIM15_CLK_SLEEP_ENABLE
#define __TIM15_FORCE_RESET __HAL_RCC_TIM15_FORCE_RESET
#define __TIM15_RELEASE_RESET __HAL_RCC_TIM15_RELEASE_RESET
#define __TIM16_CLK_DISABLE __HAL_RCC_TIM16_CLK_DISABLE
#define __TIM16_CLK_ENABLE __HAL_RCC_TIM16_CLK_ENABLE
#define __TIM16_CLK_SLEEP_DISABLE __HAL_RCC_TIM16_CLK_SLEEP_DISABLE
#define __TIM16_CLK_SLEEP_ENABLE __HAL_RCC_TIM16_CLK_SLEEP_ENABLE
#define __TIM16_FORCE_RESET __HAL_RCC_TIM16_FORCE_RESET
#define __TIM16_RELEASE_RESET __HAL_RCC_TIM16_RELEASE_RESET
#define __TIM17_CLK_DISABLE __HAL_RCC_TIM17_CLK_DISABLE
#define __TIM17_CLK_ENABLE __HAL_RCC_TIM17_CLK_ENABLE
#define __TIM17_CLK_SLEEP_DISABLE __HAL_RCC_TIM17_CLK_SLEEP_DISABLE
#define __TIM17_CLK_SLEEP_ENABLE __HAL_RCC_TIM17_CLK_SLEEP_ENABLE
#define __TIM17_FORCE_RESET __HAL_RCC_TIM17_FORCE_RESET
#define __TIM17_RELEASE_RESET __HAL_RCC_TIM17_RELEASE_RESET
#define __TIM2_CLK_DISABLE __HAL_RCC_TIM2_CLK_DISABLE
#define __TIM2_CLK_ENABLE __HAL_RCC_TIM2_CLK_ENABLE
#define __TIM2_CLK_SLEEP_DISABLE __HAL_RCC_TIM2_CLK_SLEEP_DISABLE
#define __TIM2_CLK_SLEEP_ENABLE __HAL_RCC_TIM2_CLK_SLEEP_ENABLE
#define __TIM2_FORCE_RESET __HAL_RCC_TIM2_FORCE_RESET
#define __TIM2_RELEASE_RESET __HAL_RCC_TIM2_RELEASE_RESET
#define __TIM3_CLK_DISABLE __HAL_RCC_TIM3_CLK_DISABLE
#define __TIM3_CLK_ENABLE __HAL_RCC_TIM3_CLK_ENABLE
#define __TIM3_CLK_SLEEP_DISABLE __HAL_RCC_TIM3_CLK_SLEEP_DISABLE
#define __TIM3_CLK_SLEEP_ENABLE __HAL_RCC_TIM3_CLK_SLEEP_ENABLE
#define __TIM3_FORCE_RESET __HAL_RCC_TIM3_FORCE_RESET
#define __TIM3_RELEASE_RESET __HAL_RCC_TIM3_RELEASE_RESET
#define __TIM4_CLK_DISABLE __HAL_RCC_TIM4_CLK_DISABLE
#define __TIM4_CLK_ENABLE __HAL_RCC_TIM4_CLK_ENABLE
#define __TIM4_CLK_SLEEP_DISABLE __HAL_RCC_TIM4_CLK_SLEEP_DISABLE
#define __TIM4_CLK_SLEEP_ENABLE __HAL_RCC_TIM4_CLK_SLEEP_ENABLE
#define __TIM4_FORCE_RESET __HAL_RCC_TIM4_FORCE_RESET
#define __TIM4_RELEASE_RESET __HAL_RCC_TIM4_RELEASE_RESET
#define __TIM5_CLK_DISABLE __HAL_RCC_TIM5_CLK_DISABLE
#define __TIM5_CLK_ENABLE __HAL_RCC_TIM5_CLK_ENABLE
#define __TIM5_CLK_SLEEP_DISABLE __HAL_RCC_TIM5_CLK_SLEEP_DISABLE
#define __TIM5_CLK_SLEEP_ENABLE __HAL_RCC_TIM5_CLK_SLEEP_ENABLE
#define __TIM5_FORCE_RESET __HAL_RCC_TIM5_FORCE_RESET
#define __TIM5_RELEASE_RESET __HAL_RCC_TIM5_RELEASE_RESET
#define __TIM6_CLK_DISABLE __HAL_RCC_TIM6_CLK_DISABLE
#define __TIM6_CLK_ENABLE __HAL_RCC_TIM6_CLK_ENABLE
#define __TIM6_CLK_SLEEP_DISABLE __HAL_RCC_TIM6_CLK_SLEEP_DISABLE
#define __TIM6_CLK_SLEEP_ENABLE __HAL_RCC_TIM6_CLK_SLEEP_ENABLE
#define __TIM6_FORCE_RESET __HAL_RCC_TIM6_FORCE_RESET
#define __TIM6_RELEASE_RESET __HAL_RCC_TIM6_RELEASE_RESET
#define __TIM7_CLK_DISABLE __HAL_RCC_TIM7_CLK_DISABLE
#define __TIM7_CLK_ENABLE __HAL_RCC_TIM7_CLK_ENABLE
#define __TIM7_CLK_SLEEP_DISABLE __HAL_RCC_TIM7_CLK_SLEEP_DISABLE
#define __TIM7_CLK_SLEEP_ENABLE __HAL_RCC_TIM7_CLK_SLEEP_ENABLE
#define __TIM7_FORCE_RESET __HAL_RCC_TIM7_FORCE_RESET
#define __TIM7_RELEASE_RESET __HAL_RCC_TIM7_RELEASE_RESET
#define __TIM8_CLK_DISABLE __HAL_RCC_TIM8_CLK_DISABLE
#define __TIM8_CLK_ENABLE __HAL_RCC_TIM8_CLK_ENABLE
#define __TIM8_CLK_SLEEP_DISABLE __HAL_RCC_TIM8_CLK_SLEEP_DISABLE
#define __TIM8_CLK_SLEEP_ENABLE __HAL_RCC_TIM8_CLK_SLEEP_ENABLE
#define __TIM8_FORCE_RESET __HAL_RCC_TIM8_FORCE_RESET
#define __TIM8_RELEASE_RESET __HAL_RCC_TIM8_RELEASE_RESET
#define __TIM9_CLK_DISABLE __HAL_RCC_TIM9_CLK_DISABLE
#define __TIM9_CLK_ENABLE __HAL_RCC_TIM9_CLK_ENABLE
#define __TIM9_FORCE_RESET __HAL_RCC_TIM9_FORCE_RESET
#define __TIM9_RELEASE_RESET __HAL_RCC_TIM9_RELEASE_RESET
#define __TSC_CLK_DISABLE __HAL_RCC_TSC_CLK_DISABLE
#define __TSC_CLK_ENABLE __HAL_RCC_TSC_CLK_ENABLE
#define __TSC_CLK_SLEEP_DISABLE __HAL_RCC_TSC_CLK_SLEEP_DISABLE
#define __TSC_CLK_SLEEP_ENABLE __HAL_RCC_TSC_CLK_SLEEP_ENABLE
#define __TSC_FORCE_RESET __HAL_RCC_TSC_FORCE_RESET
#define __TSC_RELEASE_RESET __HAL_RCC_TSC_RELEASE_RESET
#define __UART4_CLK_DISABLE __HAL_RCC_UART4_CLK_DISABLE
#define __UART4_CLK_ENABLE __HAL_RCC_UART4_CLK_ENABLE
#define __UART4_CLK_SLEEP_DISABLE __HAL_RCC_UART4_CLK_SLEEP_DISABLE
#define __UART4_CLK_SLEEP_ENABLE __HAL_RCC_UART4_CLK_SLEEP_ENABLE
#define __UART4_FORCE_RESET __HAL_RCC_UART4_FORCE_RESET
#define __UART4_RELEASE_RESET __HAL_RCC_UART4_RELEASE_RESET
#define __UART5_CLK_DISABLE __HAL_RCC_UART5_CLK_DISABLE
#define __UART5_CLK_ENABLE __HAL_RCC_UART5_CLK_ENABLE
#define __UART5_CLK_SLEEP_DISABLE __HAL_RCC_UART5_CLK_SLEEP_DISABLE
#define __UART5_CLK_SLEEP_ENABLE __HAL_RCC_UART5_CLK_SLEEP_ENABLE
#define __UART5_FORCE_RESET __HAL_RCC_UART5_FORCE_RESET
#define __UART5_RELEASE_RESET __HAL_RCC_UART5_RELEASE_RESET
#define __USART1_CLK_DISABLE __HAL_RCC_USART1_CLK_DISABLE
#define __USART1_CLK_ENABLE __HAL_RCC_USART1_CLK_ENABLE
#define __USART1_CLK_SLEEP_DISABLE __HAL_RCC_USART1_CLK_SLEEP_DISABLE
#define __USART1_CLK_SLEEP_ENABLE __HAL_RCC_USART1_CLK_SLEEP_ENABLE
#define __USART1_FORCE_RESET __HAL_RCC_USART1_FORCE_RESET
#define __USART1_RELEASE_RESET __HAL_RCC_USART1_RELEASE_RESET
#define __USART2_CLK_DISABLE __HAL_RCC_USART2_CLK_DISABLE
#define __USART2_CLK_ENABLE __HAL_RCC_USART2_CLK_ENABLE
#define __USART2_CLK_SLEEP_DISABLE __HAL_RCC_USART2_CLK_SLEEP_DISABLE
#define __USART2_CLK_SLEEP_ENABLE __HAL_RCC_USART2_CLK_SLEEP_ENABLE
#define __USART2_FORCE_RESET __HAL_RCC_USART2_FORCE_RESET
#define __USART2_RELEASE_RESET __HAL_RCC_USART2_RELEASE_RESET
#define __USART3_CLK_DISABLE __HAL_RCC_USART3_CLK_DISABLE
#define __USART3_CLK_ENABLE __HAL_RCC_USART3_CLK_ENABLE
#define __USART3_CLK_SLEEP_DISABLE __HAL_RCC_USART3_CLK_SLEEP_DISABLE
#define __USART3_CLK_SLEEP_ENABLE __HAL_RCC_USART3_CLK_SLEEP_ENABLE
#define __USART3_FORCE_RESET __HAL_RCC_USART3_FORCE_RESET
#define __USART3_RELEASE_RESET __HAL_RCC_USART3_RELEASE_RESET
#define __USART4_CLK_DISABLE __HAL_RCC_UART4_CLK_DISABLE
#define __USART4_CLK_ENABLE __HAL_RCC_UART4_CLK_ENABLE
#define __USART4_CLK_SLEEP_ENABLE __HAL_RCC_UART4_CLK_SLEEP_ENABLE
#define __USART4_CLK_SLEEP_DISABLE __HAL_RCC_UART4_CLK_SLEEP_DISABLE
#define __USART4_FORCE_RESET __HAL_RCC_UART4_FORCE_RESET
#define __USART4_RELEASE_RESET __HAL_RCC_UART4_RELEASE_RESET
#define __USART5_CLK_DISABLE __HAL_RCC_UART5_CLK_DISABLE
#define __USART5_CLK_ENABLE __HAL_RCC_UART5_CLK_ENABLE
#define __USART5_CLK_SLEEP_ENABLE __HAL_RCC_UART5_CLK_SLEEP_ENABLE
#define __USART5_CLK_SLEEP_DISABLE __HAL_RCC_UART5_CLK_SLEEP_DISABLE
#define __USART5_FORCE_RESET __HAL_RCC_UART5_FORCE_RESET
#define __USART5_RELEASE_RESET __HAL_RCC_UART5_RELEASE_RESET
#define __USART7_CLK_DISABLE __HAL_RCC_UART7_CLK_DISABLE
#define __USART7_CLK_ENABLE __HAL_RCC_UART7_CLK_ENABLE
#define __USART7_FORCE_RESET __HAL_RCC_UART7_FORCE_RESET
#define __USART7_RELEASE_RESET __HAL_RCC_UART7_RELEASE_RESET
#define __USART8_CLK_DISABLE __HAL_RCC_UART8_CLK_DISABLE
#define __USART8_CLK_ENABLE __HAL_RCC_UART8_CLK_ENABLE
#define __USART8_FORCE_RESET __HAL_RCC_UART8_FORCE_RESET
#define __USART8_RELEASE_RESET __HAL_RCC_UART8_RELEASE_RESET
#define __USB_CLK_DISABLE __HAL_RCC_USB_CLK_DISABLE
#define __USB_CLK_ENABLE __HAL_RCC_USB_CLK_ENABLE
#define __USB_FORCE_RESET __HAL_RCC_USB_FORCE_RESET
#define __USB_CLK_SLEEP_ENABLE __HAL_RCC_USB_CLK_SLEEP_ENABLE
#define __USB_CLK_SLEEP_DISABLE __HAL_RCC_USB_CLK_SLEEP_DISABLE
#define __USB_OTG_FS_CLK_DISABLE __HAL_RCC_USB_OTG_FS_CLK_DISABLE
#define __USB_OTG_FS_CLK_ENABLE __HAL_RCC_USB_OTG_FS_CLK_ENABLE
#define __USB_RELEASE_RESET __HAL_RCC_USB_RELEASE_RESET
#if defined(STM32H7)
#define __HAL_RCC_WWDG_CLK_DISABLE __HAL_RCC_WWDG1_CLK_DISABLE
#define __HAL_RCC_WWDG_CLK_ENABLE __HAL_RCC_WWDG1_CLK_ENABLE
#define __HAL_RCC_WWDG_CLK_SLEEP_DISABLE __HAL_RCC_WWDG1_CLK_SLEEP_DISABLE
#define __HAL_RCC_WWDG_CLK_SLEEP_ENABLE __HAL_RCC_WWDG1_CLK_SLEEP_ENABLE
#define __HAL_RCC_WWDG_FORCE_RESET ((void)0U) /* Not available on the STM32H7*/
#define __HAL_RCC_WWDG_RELEASE_RESET ((void)0U) /* Not available on the STM32H7*/
#define __HAL_RCC_WWDG_IS_CLK_ENABLED __HAL_RCC_WWDG1_IS_CLK_ENABLED
#define __HAL_RCC_WWDG_IS_CLK_DISABLED __HAL_RCC_WWDG1_IS_CLK_DISABLED
#define RCC_SPI4CLKSOURCE_D2PCLK1 RCC_SPI4CLKSOURCE_D2PCLK2
#define RCC_SPI5CLKSOURCE_D2PCLK1 RCC_SPI5CLKSOURCE_D2PCLK2
#define RCC_SPI45CLKSOURCE_D2PCLK1 RCC_SPI45CLKSOURCE_D2PCLK2
#define RCC_SPI45CLKSOURCE_CDPCLK1 RCC_SPI45CLKSOURCE_CDPCLK2
#define RCC_SPI45CLKSOURCE_PCLK1 RCC_SPI45CLKSOURCE_PCLK2
#endif
#define __WWDG_CLK_DISABLE __HAL_RCC_WWDG_CLK_DISABLE
#define __WWDG_CLK_ENABLE __HAL_RCC_WWDG_CLK_ENABLE
#define __WWDG_CLK_SLEEP_DISABLE __HAL_RCC_WWDG_CLK_SLEEP_DISABLE
#define __WWDG_CLK_SLEEP_ENABLE __HAL_RCC_WWDG_CLK_SLEEP_ENABLE
#define __WWDG_FORCE_RESET __HAL_RCC_WWDG_FORCE_RESET
#define __WWDG_RELEASE_RESET __HAL_RCC_WWDG_RELEASE_RESET
#define __TIM21_CLK_ENABLE __HAL_RCC_TIM21_CLK_ENABLE
#define __TIM21_CLK_DISABLE __HAL_RCC_TIM21_CLK_DISABLE
#define __TIM21_FORCE_RESET __HAL_RCC_TIM21_FORCE_RESET
#define __TIM21_RELEASE_RESET __HAL_RCC_TIM21_RELEASE_RESET
#define __TIM21_CLK_SLEEP_ENABLE __HAL_RCC_TIM21_CLK_SLEEP_ENABLE
#define __TIM21_CLK_SLEEP_DISABLE __HAL_RCC_TIM21_CLK_SLEEP_DISABLE
#define __TIM22_CLK_ENABLE __HAL_RCC_TIM22_CLK_ENABLE
#define __TIM22_CLK_DISABLE __HAL_RCC_TIM22_CLK_DISABLE
#define __TIM22_FORCE_RESET __HAL_RCC_TIM22_FORCE_RESET
#define __TIM22_RELEASE_RESET __HAL_RCC_TIM22_RELEASE_RESET
#define __TIM22_CLK_SLEEP_ENABLE __HAL_RCC_TIM22_CLK_SLEEP_ENABLE
#define __TIM22_CLK_SLEEP_DISABLE __HAL_RCC_TIM22_CLK_SLEEP_DISABLE
#define __CRS_CLK_DISABLE __HAL_RCC_CRS_CLK_DISABLE
#define __CRS_CLK_ENABLE __HAL_RCC_CRS_CLK_ENABLE
#define __CRS_CLK_SLEEP_DISABLE __HAL_RCC_CRS_CLK_SLEEP_DISABLE
#define __CRS_CLK_SLEEP_ENABLE __HAL_RCC_CRS_CLK_SLEEP_ENABLE
#define __CRS_FORCE_RESET __HAL_RCC_CRS_FORCE_RESET
#define __CRS_RELEASE_RESET __HAL_RCC_CRS_RELEASE_RESET
#define __RCC_BACKUPRESET_FORCE __HAL_RCC_BACKUPRESET_FORCE
#define __RCC_BACKUPRESET_RELEASE __HAL_RCC_BACKUPRESET_RELEASE
#define __USB_OTG_FS_FORCE_RESET __HAL_RCC_USB_OTG_FS_FORCE_RESET
#define __USB_OTG_FS_RELEASE_RESET __HAL_RCC_USB_OTG_FS_RELEASE_RESET
#define __USB_OTG_FS_CLK_SLEEP_ENABLE __HAL_RCC_USB_OTG_FS_CLK_SLEEP_ENABLE
#define __USB_OTG_FS_CLK_SLEEP_DISABLE __HAL_RCC_USB_OTG_FS_CLK_SLEEP_DISABLE
#define __USB_OTG_HS_CLK_DISABLE __HAL_RCC_USB_OTG_HS_CLK_DISABLE
#define __USB_OTG_HS_CLK_ENABLE __HAL_RCC_USB_OTG_HS_CLK_ENABLE
#define __USB_OTG_HS_ULPI_CLK_ENABLE __HAL_RCC_USB_OTG_HS_ULPI_CLK_ENABLE
#define __USB_OTG_HS_ULPI_CLK_DISABLE __HAL_RCC_USB_OTG_HS_ULPI_CLK_DISABLE
#define __TIM9_CLK_SLEEP_ENABLE __HAL_RCC_TIM9_CLK_SLEEP_ENABLE
#define __TIM9_CLK_SLEEP_DISABLE __HAL_RCC_TIM9_CLK_SLEEP_DISABLE
#define __TIM10_CLK_SLEEP_ENABLE __HAL_RCC_TIM10_CLK_SLEEP_ENABLE
#define __TIM10_CLK_SLEEP_DISABLE __HAL_RCC_TIM10_CLK_SLEEP_DISABLE
#define __TIM11_CLK_SLEEP_ENABLE __HAL_RCC_TIM11_CLK_SLEEP_ENABLE
#define __TIM11_CLK_SLEEP_DISABLE __HAL_RCC_TIM11_CLK_SLEEP_DISABLE
#define __ETHMACPTP_CLK_SLEEP_ENABLE __HAL_RCC_ETHMACPTP_CLK_SLEEP_ENABLE
#define __ETHMACPTP_CLK_SLEEP_DISABLE __HAL_RCC_ETHMACPTP_CLK_SLEEP_DISABLE
#define __ETHMACPTP_CLK_ENABLE __HAL_RCC_ETHMACPTP_CLK_ENABLE
#define __ETHMACPTP_CLK_DISABLE __HAL_RCC_ETHMACPTP_CLK_DISABLE
#define __HASH_CLK_ENABLE __HAL_RCC_HASH_CLK_ENABLE
#define __HASH_FORCE_RESET __HAL_RCC_HASH_FORCE_RESET
#define __HASH_RELEASE_RESET __HAL_RCC_HASH_RELEASE_RESET
#define __HASH_CLK_SLEEP_ENABLE __HAL_RCC_HASH_CLK_SLEEP_ENABLE
#define __HASH_CLK_SLEEP_DISABLE __HAL_RCC_HASH_CLK_SLEEP_DISABLE
#define __HASH_CLK_DISABLE __HAL_RCC_HASH_CLK_DISABLE
#define __SPI5_CLK_ENABLE __HAL_RCC_SPI5_CLK_ENABLE
#define __SPI5_CLK_DISABLE __HAL_RCC_SPI5_CLK_DISABLE
#define __SPI5_FORCE_RESET __HAL_RCC_SPI5_FORCE_RESET
#define __SPI5_RELEASE_RESET __HAL_RCC_SPI5_RELEASE_RESET
#define __SPI5_CLK_SLEEP_ENABLE __HAL_RCC_SPI5_CLK_SLEEP_ENABLE
#define __SPI5_CLK_SLEEP_DISABLE __HAL_RCC_SPI5_CLK_SLEEP_DISABLE
#define __SPI6_CLK_ENABLE __HAL_RCC_SPI6_CLK_ENABLE
#define __SPI6_CLK_DISABLE __HAL_RCC_SPI6_CLK_DISABLE
#define __SPI6_FORCE_RESET __HAL_RCC_SPI6_FORCE_RESET
#define __SPI6_RELEASE_RESET __HAL_RCC_SPI6_RELEASE_RESET
#define __SPI6_CLK_SLEEP_ENABLE __HAL_RCC_SPI6_CLK_SLEEP_ENABLE
#define __SPI6_CLK_SLEEP_DISABLE __HAL_RCC_SPI6_CLK_SLEEP_DISABLE
#define __LTDC_CLK_ENABLE __HAL_RCC_LTDC_CLK_ENABLE
#define __LTDC_CLK_DISABLE __HAL_RCC_LTDC_CLK_DISABLE
#define __LTDC_FORCE_RESET __HAL_RCC_LTDC_FORCE_RESET
#define __LTDC_RELEASE_RESET __HAL_RCC_LTDC_RELEASE_RESET
#define __LTDC_CLK_SLEEP_ENABLE __HAL_RCC_LTDC_CLK_SLEEP_ENABLE
#define __ETHMAC_CLK_SLEEP_ENABLE __HAL_RCC_ETHMAC_CLK_SLEEP_ENABLE
#define __ETHMAC_CLK_SLEEP_DISABLE __HAL_RCC_ETHMAC_CLK_SLEEP_DISABLE
#define __ETHMACTX_CLK_SLEEP_ENABLE __HAL_RCC_ETHMACTX_CLK_SLEEP_ENABLE
#define __ETHMACTX_CLK_SLEEP_DISABLE __HAL_RCC_ETHMACTX_CLK_SLEEP_DISABLE
#define __ETHMACRX_CLK_SLEEP_ENABLE __HAL_RCC_ETHMACRX_CLK_SLEEP_ENABLE
#define __ETHMACRX_CLK_SLEEP_DISABLE __HAL_RCC_ETHMACRX_CLK_SLEEP_DISABLE
#define __TIM12_CLK_SLEEP_ENABLE __HAL_RCC_TIM12_CLK_SLEEP_ENABLE
#define __TIM12_CLK_SLEEP_DISABLE __HAL_RCC_TIM12_CLK_SLEEP_DISABLE
#define __TIM13_CLK_SLEEP_ENABLE __HAL_RCC_TIM13_CLK_SLEEP_ENABLE
#define __TIM13_CLK_SLEEP_DISABLE __HAL_RCC_TIM13_CLK_SLEEP_DISABLE
#define __TIM14_CLK_SLEEP_ENABLE __HAL_RCC_TIM14_CLK_SLEEP_ENABLE
#define __TIM14_CLK_SLEEP_DISABLE __HAL_RCC_TIM14_CLK_SLEEP_DISABLE
#define __BKPSRAM_CLK_ENABLE __HAL_RCC_BKPSRAM_CLK_ENABLE
#define __BKPSRAM_CLK_DISABLE __HAL_RCC_BKPSRAM_CLK_DISABLE
#define __BKPSRAM_CLK_SLEEP_ENABLE __HAL_RCC_BKPSRAM_CLK_SLEEP_ENABLE
#define __BKPSRAM_CLK_SLEEP_DISABLE __HAL_RCC_BKPSRAM_CLK_SLEEP_DISABLE
#define __CCMDATARAMEN_CLK_ENABLE __HAL_RCC_CCMDATARAMEN_CLK_ENABLE
#define __CCMDATARAMEN_CLK_DISABLE __HAL_RCC_CCMDATARAMEN_CLK_DISABLE
#define __USART6_CLK_ENABLE __HAL_RCC_USART6_CLK_ENABLE
#define __USART6_CLK_DISABLE __HAL_RCC_USART6_CLK_DISABLE
#define __USART6_FORCE_RESET __HAL_RCC_USART6_FORCE_RESET
#define __USART6_RELEASE_RESET __HAL_RCC_USART6_RELEASE_RESET
#define __USART6_CLK_SLEEP_ENABLE __HAL_RCC_USART6_CLK_SLEEP_ENABLE
#define __USART6_CLK_SLEEP_DISABLE __HAL_RCC_USART6_CLK_SLEEP_DISABLE
#define __SPI4_CLK_ENABLE __HAL_RCC_SPI4_CLK_ENABLE
#define __SPI4_CLK_DISABLE __HAL_RCC_SPI4_CLK_DISABLE
#define __SPI4_FORCE_RESET __HAL_RCC_SPI4_FORCE_RESET
#define __SPI4_RELEASE_RESET __HAL_RCC_SPI4_RELEASE_RESET
#define __SPI4_CLK_SLEEP_ENABLE __HAL_RCC_SPI4_CLK_SLEEP_ENABLE
#define __SPI4_CLK_SLEEP_DISABLE __HAL_RCC_SPI4_CLK_SLEEP_DISABLE
#define __GPIOI_CLK_ENABLE __HAL_RCC_GPIOI_CLK_ENABLE
#define __GPIOI_CLK_DISABLE __HAL_RCC_GPIOI_CLK_DISABLE
#define __GPIOI_FORCE_RESET __HAL_RCC_GPIOI_FORCE_RESET
#define __GPIOI_RELEASE_RESET __HAL_RCC_GPIOI_RELEASE_RESET
#define __GPIOI_CLK_SLEEP_ENABLE __HAL_RCC_GPIOI_CLK_SLEEP_ENABLE
#define __GPIOI_CLK_SLEEP_DISABLE __HAL_RCC_GPIOI_CLK_SLEEP_DISABLE
#define __GPIOJ_CLK_ENABLE __HAL_RCC_GPIOJ_CLK_ENABLE
#define __GPIOJ_CLK_DISABLE __HAL_RCC_GPIOJ_CLK_DISABLE
#define __GPIOJ_FORCE_RESET __HAL_RCC_GPIOJ_FORCE_RESET
#define __GPIOJ_RELEASE_RESET __HAL_RCC_GPIOJ_RELEASE_RESET
#define __GPIOJ_CLK_SLEEP_ENABLE __HAL_RCC_GPIOJ_CLK_SLEEP_ENABLE
#define __GPIOJ_CLK_SLEEP_DISABLE __HAL_RCC_GPIOJ_CLK_SLEEP_DISABLE
#define __GPIOK_CLK_ENABLE __HAL_RCC_GPIOK_CLK_ENABLE
#define __GPIOK_CLK_DISABLE __HAL_RCC_GPIOK_CLK_DISABLE
#define __GPIOK_RELEASE_RESET __HAL_RCC_GPIOK_RELEASE_RESET
#define __GPIOK_CLK_SLEEP_ENABLE __HAL_RCC_GPIOK_CLK_SLEEP_ENABLE
#define __GPIOK_CLK_SLEEP_DISABLE __HAL_RCC_GPIOK_CLK_SLEEP_DISABLE
#define __ETH_CLK_ENABLE __HAL_RCC_ETH_CLK_ENABLE
#define __ETH_CLK_DISABLE __HAL_RCC_ETH_CLK_DISABLE
#define __DCMI_CLK_ENABLE __HAL_RCC_DCMI_CLK_ENABLE
#define __DCMI_CLK_DISABLE __HAL_RCC_DCMI_CLK_DISABLE
#define __DCMI_FORCE_RESET __HAL_RCC_DCMI_FORCE_RESET
#define __DCMI_RELEASE_RESET __HAL_RCC_DCMI_RELEASE_RESET
#define __DCMI_CLK_SLEEP_ENABLE __HAL_RCC_DCMI_CLK_SLEEP_ENABLE
#define __DCMI_CLK_SLEEP_DISABLE __HAL_RCC_DCMI_CLK_SLEEP_DISABLE
#define __UART7_CLK_ENABLE __HAL_RCC_UART7_CLK_ENABLE
#define __UART7_CLK_DISABLE __HAL_RCC_UART7_CLK_DISABLE
#define __UART7_RELEASE_RESET __HAL_RCC_UART7_RELEASE_RESET
#define __UART7_FORCE_RESET __HAL_RCC_UART7_FORCE_RESET
#define __UART7_CLK_SLEEP_ENABLE __HAL_RCC_UART7_CLK_SLEEP_ENABLE
#define __UART7_CLK_SLEEP_DISABLE __HAL_RCC_UART7_CLK_SLEEP_DISABLE
#define __UART8_CLK_ENABLE __HAL_RCC_UART8_CLK_ENABLE
#define __UART8_CLK_DISABLE __HAL_RCC_UART8_CLK_DISABLE
#define __UART8_FORCE_RESET __HAL_RCC_UART8_FORCE_RESET
#define __UART8_RELEASE_RESET __HAL_RCC_UART8_RELEASE_RESET
#define __UART8_CLK_SLEEP_ENABLE __HAL_RCC_UART8_CLK_SLEEP_ENABLE
#define __UART8_CLK_SLEEP_DISABLE __HAL_RCC_UART8_CLK_SLEEP_DISABLE
#define __OTGHS_CLK_SLEEP_ENABLE __HAL_RCC_USB_OTG_HS_CLK_SLEEP_ENABLE
#define __OTGHS_CLK_SLEEP_DISABLE __HAL_RCC_USB_OTG_HS_CLK_SLEEP_DISABLE
#define __OTGHS_FORCE_RESET __HAL_RCC_USB_OTG_HS_FORCE_RESET
#define __OTGHS_RELEASE_RESET __HAL_RCC_USB_OTG_HS_RELEASE_RESET
#define __OTGHSULPI_CLK_SLEEP_ENABLE __HAL_RCC_USB_OTG_HS_ULPI_CLK_SLEEP_ENABLE
#define __OTGHSULPI_CLK_SLEEP_DISABLE __HAL_RCC_USB_OTG_HS_ULPI_CLK_SLEEP_DISABLE
#define __HAL_RCC_OTGHS_CLK_SLEEP_ENABLE __HAL_RCC_USB_OTG_HS_CLK_SLEEP_ENABLE
#define __HAL_RCC_OTGHS_CLK_SLEEP_DISABLE __HAL_RCC_USB_OTG_HS_CLK_SLEEP_DISABLE
#define __HAL_RCC_OTGHS_IS_CLK_SLEEP_ENABLED __HAL_RCC_USB_OTG_HS_IS_CLK_SLEEP_ENABLED
#define __HAL_RCC_OTGHS_IS_CLK_SLEEP_DISABLED __HAL_RCC_USB_OTG_HS_IS_CLK_SLEEP_DISABLED
#define __HAL_RCC_OTGHS_FORCE_RESET __HAL_RCC_USB_OTG_HS_FORCE_RESET
#define __HAL_RCC_OTGHS_RELEASE_RESET __HAL_RCC_USB_OTG_HS_RELEASE_RESET
#define __HAL_RCC_OTGHSULPI_CLK_SLEEP_ENABLE __HAL_RCC_USB_OTG_HS_ULPI_CLK_SLEEP_ENABLE
#define __HAL_RCC_OTGHSULPI_CLK_SLEEP_DISABLE __HAL_RCC_USB_OTG_HS_ULPI_CLK_SLEEP_DISABLE
#define __HAL_RCC_OTGHSULPI_IS_CLK_SLEEP_ENABLED __HAL_RCC_USB_OTG_HS_ULPI_IS_CLK_SLEEP_ENABLED
#define __HAL_RCC_OTGHSULPI_IS_CLK_SLEEP_DISABLED __HAL_RCC_USB_OTG_HS_ULPI_IS_CLK_SLEEP_DISABLED
#define __SRAM3_CLK_SLEEP_ENABLE __HAL_RCC_SRAM3_CLK_SLEEP_ENABLE
#define __CAN2_CLK_SLEEP_ENABLE __HAL_RCC_CAN2_CLK_SLEEP_ENABLE
#define __CAN2_CLK_SLEEP_DISABLE __HAL_RCC_CAN2_CLK_SLEEP_DISABLE
#define __DAC_CLK_SLEEP_ENABLE __HAL_RCC_DAC_CLK_SLEEP_ENABLE
#define __DAC_CLK_SLEEP_DISABLE __HAL_RCC_DAC_CLK_SLEEP_DISABLE
#define __ADC2_CLK_SLEEP_ENABLE __HAL_RCC_ADC2_CLK_SLEEP_ENABLE
#define __ADC2_CLK_SLEEP_DISABLE __HAL_RCC_ADC2_CLK_SLEEP_DISABLE
#define __ADC3_CLK_SLEEP_ENABLE __HAL_RCC_ADC3_CLK_SLEEP_ENABLE
#define __ADC3_CLK_SLEEP_DISABLE __HAL_RCC_ADC3_CLK_SLEEP_DISABLE
#define __FSMC_FORCE_RESET __HAL_RCC_FSMC_FORCE_RESET
#define __FSMC_RELEASE_RESET __HAL_RCC_FSMC_RELEASE_RESET
#define __FSMC_CLK_SLEEP_ENABLE __HAL_RCC_FSMC_CLK_SLEEP_ENABLE
#define __FSMC_CLK_SLEEP_DISABLE __HAL_RCC_FSMC_CLK_SLEEP_DISABLE
#define __SDIO_FORCE_RESET __HAL_RCC_SDIO_FORCE_RESET
#define __SDIO_RELEASE_RESET __HAL_RCC_SDIO_RELEASE_RESET
#define __SDIO_CLK_SLEEP_DISABLE __HAL_RCC_SDIO_CLK_SLEEP_DISABLE
#define __SDIO_CLK_SLEEP_ENABLE __HAL_RCC_SDIO_CLK_SLEEP_ENABLE
#define __DMA2D_CLK_ENABLE __HAL_RCC_DMA2D_CLK_ENABLE
#define __DMA2D_CLK_DISABLE __HAL_RCC_DMA2D_CLK_DISABLE
#define __DMA2D_FORCE_RESET __HAL_RCC_DMA2D_FORCE_RESET
#define __DMA2D_RELEASE_RESET __HAL_RCC_DMA2D_RELEASE_RESET
#define __DMA2D_CLK_SLEEP_ENABLE __HAL_RCC_DMA2D_CLK_SLEEP_ENABLE
#define __DMA2D_CLK_SLEEP_DISABLE __HAL_RCC_DMA2D_CLK_SLEEP_DISABLE
/* alias define maintained for legacy */
#define __HAL_RCC_OTGFS_FORCE_RESET __HAL_RCC_USB_OTG_FS_FORCE_RESET
#define __HAL_RCC_OTGFS_RELEASE_RESET __HAL_RCC_USB_OTG_FS_RELEASE_RESET
#define __ADC12_CLK_ENABLE __HAL_RCC_ADC12_CLK_ENABLE
#define __ADC12_CLK_DISABLE __HAL_RCC_ADC12_CLK_DISABLE
#define __ADC34_CLK_ENABLE __HAL_RCC_ADC34_CLK_ENABLE
#define __ADC34_CLK_DISABLE __HAL_RCC_ADC34_CLK_DISABLE
#define __DAC2_CLK_ENABLE __HAL_RCC_DAC2_CLK_ENABLE
#define __DAC2_CLK_DISABLE __HAL_RCC_DAC2_CLK_DISABLE
#define __TIM18_CLK_ENABLE __HAL_RCC_TIM18_CLK_ENABLE
#define __TIM18_CLK_DISABLE __HAL_RCC_TIM18_CLK_DISABLE
#define __TIM19_CLK_ENABLE __HAL_RCC_TIM19_CLK_ENABLE
#define __TIM19_CLK_DISABLE __HAL_RCC_TIM19_CLK_DISABLE
#define __TIM20_CLK_ENABLE __HAL_RCC_TIM20_CLK_ENABLE
#define __TIM20_CLK_DISABLE __HAL_RCC_TIM20_CLK_DISABLE
#define __HRTIM1_CLK_ENABLE __HAL_RCC_HRTIM1_CLK_ENABLE
#define __HRTIM1_CLK_DISABLE __HAL_RCC_HRTIM1_CLK_DISABLE
#define __SDADC1_CLK_ENABLE __HAL_RCC_SDADC1_CLK_ENABLE
#define __SDADC2_CLK_ENABLE __HAL_RCC_SDADC2_CLK_ENABLE
#define __SDADC3_CLK_ENABLE __HAL_RCC_SDADC3_CLK_ENABLE
#define __SDADC1_CLK_DISABLE __HAL_RCC_SDADC1_CLK_DISABLE
#define __SDADC2_CLK_DISABLE __HAL_RCC_SDADC2_CLK_DISABLE
#define __SDADC3_CLK_DISABLE __HAL_RCC_SDADC3_CLK_DISABLE
#define __ADC12_FORCE_RESET __HAL_RCC_ADC12_FORCE_RESET
#define __ADC12_RELEASE_RESET __HAL_RCC_ADC12_RELEASE_RESET
#define __ADC34_FORCE_RESET __HAL_RCC_ADC34_FORCE_RESET
#define __ADC34_RELEASE_RESET __HAL_RCC_ADC34_RELEASE_RESET
#define __DAC2_FORCE_RESET __HAL_RCC_DAC2_FORCE_RESET
#define __DAC2_RELEASE_RESET __HAL_RCC_DAC2_RELEASE_RESET
#define __TIM18_FORCE_RESET __HAL_RCC_TIM18_FORCE_RESET
#define __TIM18_RELEASE_RESET __HAL_RCC_TIM18_RELEASE_RESET
#define __TIM19_FORCE_RESET __HAL_RCC_TIM19_FORCE_RESET
#define __TIM19_RELEASE_RESET __HAL_RCC_TIM19_RELEASE_RESET
#define __TIM20_FORCE_RESET __HAL_RCC_TIM20_FORCE_RESET
#define __TIM20_RELEASE_RESET __HAL_RCC_TIM20_RELEASE_RESET
#define __HRTIM1_FORCE_RESET __HAL_RCC_HRTIM1_FORCE_RESET
#define __HRTIM1_RELEASE_RESET __HAL_RCC_HRTIM1_RELEASE_RESET
#define __SDADC1_FORCE_RESET __HAL_RCC_SDADC1_FORCE_RESET
#define __SDADC2_FORCE_RESET __HAL_RCC_SDADC2_FORCE_RESET
#define __SDADC3_FORCE_RESET __HAL_RCC_SDADC3_FORCE_RESET
#define __SDADC1_RELEASE_RESET __HAL_RCC_SDADC1_RELEASE_RESET
#define __SDADC2_RELEASE_RESET __HAL_RCC_SDADC2_RELEASE_RESET
#define __SDADC3_RELEASE_RESET __HAL_RCC_SDADC3_RELEASE_RESET
#define __ADC1_IS_CLK_ENABLED __HAL_RCC_ADC1_IS_CLK_ENABLED
#define __ADC1_IS_CLK_DISABLED __HAL_RCC_ADC1_IS_CLK_DISABLED
#define __ADC12_IS_CLK_ENABLED __HAL_RCC_ADC12_IS_CLK_ENABLED
#define __ADC12_IS_CLK_DISABLED __HAL_RCC_ADC12_IS_CLK_DISABLED
#define __ADC34_IS_CLK_ENABLED __HAL_RCC_ADC34_IS_CLK_ENABLED
#define __ADC34_IS_CLK_DISABLED __HAL_RCC_ADC34_IS_CLK_DISABLED
#define __CEC_IS_CLK_ENABLED __HAL_RCC_CEC_IS_CLK_ENABLED
#define __CEC_IS_CLK_DISABLED __HAL_RCC_CEC_IS_CLK_DISABLED
#define __CRC_IS_CLK_ENABLED __HAL_RCC_CRC_IS_CLK_ENABLED
#define __CRC_IS_CLK_DISABLED __HAL_RCC_CRC_IS_CLK_DISABLED
#define __DAC1_IS_CLK_ENABLED __HAL_RCC_DAC1_IS_CLK_ENABLED
#define __DAC1_IS_CLK_DISABLED __HAL_RCC_DAC1_IS_CLK_DISABLED
#define __DAC2_IS_CLK_ENABLED __HAL_RCC_DAC2_IS_CLK_ENABLED
#define __DAC2_IS_CLK_DISABLED __HAL_RCC_DAC2_IS_CLK_DISABLED
#define __DMA1_IS_CLK_ENABLED __HAL_RCC_DMA1_IS_CLK_ENABLED
#define __DMA1_IS_CLK_DISABLED __HAL_RCC_DMA1_IS_CLK_DISABLED
#define __DMA2_IS_CLK_ENABLED __HAL_RCC_DMA2_IS_CLK_ENABLED
#define __DMA2_IS_CLK_DISABLED __HAL_RCC_DMA2_IS_CLK_DISABLED
#define __FLITF_IS_CLK_ENABLED __HAL_RCC_FLITF_IS_CLK_ENABLED
#define __FLITF_IS_CLK_DISABLED __HAL_RCC_FLITF_IS_CLK_DISABLED
#define __FMC_IS_CLK_ENABLED __HAL_RCC_FMC_IS_CLK_ENABLED
#define __FMC_IS_CLK_DISABLED __HAL_RCC_FMC_IS_CLK_DISABLED
#define __GPIOA_IS_CLK_ENABLED __HAL_RCC_GPIOA_IS_CLK_ENABLED
#define __GPIOA_IS_CLK_DISABLED __HAL_RCC_GPIOA_IS_CLK_DISABLED
#define __GPIOB_IS_CLK_ENABLED __HAL_RCC_GPIOB_IS_CLK_ENABLED
#define __GPIOB_IS_CLK_DISABLED __HAL_RCC_GPIOB_IS_CLK_DISABLED
#define __GPIOC_IS_CLK_ENABLED __HAL_RCC_GPIOC_IS_CLK_ENABLED
#define __GPIOC_IS_CLK_DISABLED __HAL_RCC_GPIOC_IS_CLK_DISABLED
#define __GPIOD_IS_CLK_ENABLED __HAL_RCC_GPIOD_IS_CLK_ENABLED
#define __GPIOD_IS_CLK_DISABLED __HAL_RCC_GPIOD_IS_CLK_DISABLED
#define __GPIOE_IS_CLK_ENABLED __HAL_RCC_GPIOE_IS_CLK_ENABLED
#define __GPIOE_IS_CLK_DISABLED __HAL_RCC_GPIOE_IS_CLK_DISABLED
#define __GPIOF_IS_CLK_ENABLED __HAL_RCC_GPIOF_IS_CLK_ENABLED
#define __GPIOF_IS_CLK_DISABLED __HAL_RCC_GPIOF_IS_CLK_DISABLED
#define __GPIOG_IS_CLK_ENABLED __HAL_RCC_GPIOG_IS_CLK_ENABLED
#define __GPIOG_IS_CLK_DISABLED __HAL_RCC_GPIOG_IS_CLK_DISABLED
#define __GPIOH_IS_CLK_ENABLED __HAL_RCC_GPIOH_IS_CLK_ENABLED
#define __GPIOH_IS_CLK_DISABLED __HAL_RCC_GPIOH_IS_CLK_DISABLED
#define __HRTIM1_IS_CLK_ENABLED __HAL_RCC_HRTIM1_IS_CLK_ENABLED
#define __HRTIM1_IS_CLK_DISABLED __HAL_RCC_HRTIM1_IS_CLK_DISABLED
#define __I2C1_IS_CLK_ENABLED __HAL_RCC_I2C1_IS_CLK_ENABLED
#define __I2C1_IS_CLK_DISABLED __HAL_RCC_I2C1_IS_CLK_DISABLED
#define __I2C2_IS_CLK_ENABLED __HAL_RCC_I2C2_IS_CLK_ENABLED
#define __I2C2_IS_CLK_DISABLED __HAL_RCC_I2C2_IS_CLK_DISABLED
#define __I2C3_IS_CLK_ENABLED __HAL_RCC_I2C3_IS_CLK_ENABLED
#define __I2C3_IS_CLK_DISABLED __HAL_RCC_I2C3_IS_CLK_DISABLED
#define __PWR_IS_CLK_ENABLED __HAL_RCC_PWR_IS_CLK_ENABLED
#define __PWR_IS_CLK_DISABLED __HAL_RCC_PWR_IS_CLK_DISABLED
#define __SYSCFG_IS_CLK_ENABLED __HAL_RCC_SYSCFG_IS_CLK_ENABLED
#define __SYSCFG_IS_CLK_DISABLED __HAL_RCC_SYSCFG_IS_CLK_DISABLED
#define __SPI1_IS_CLK_ENABLED __HAL_RCC_SPI1_IS_CLK_ENABLED
#define __SPI1_IS_CLK_DISABLED __HAL_RCC_SPI1_IS_CLK_DISABLED
#define __SPI2_IS_CLK_ENABLED __HAL_RCC_SPI2_IS_CLK_ENABLED
#define __SPI2_IS_CLK_DISABLED __HAL_RCC_SPI2_IS_CLK_DISABLED
#define __SPI3_IS_CLK_ENABLED __HAL_RCC_SPI3_IS_CLK_ENABLED
#define __SPI3_IS_CLK_DISABLED __HAL_RCC_SPI3_IS_CLK_DISABLED
#define __SPI4_IS_CLK_ENABLED __HAL_RCC_SPI4_IS_CLK_ENABLED
#define __SPI4_IS_CLK_DISABLED __HAL_RCC_SPI4_IS_CLK_DISABLED
#define __SDADC1_IS_CLK_ENABLED __HAL_RCC_SDADC1_IS_CLK_ENABLED
#define __SDADC1_IS_CLK_DISABLED __HAL_RCC_SDADC1_IS_CLK_DISABLED
#define __SDADC2_IS_CLK_ENABLED __HAL_RCC_SDADC2_IS_CLK_ENABLED
#define __SDADC2_IS_CLK_DISABLED __HAL_RCC_SDADC2_IS_CLK_DISABLED
#define __SDADC3_IS_CLK_ENABLED __HAL_RCC_SDADC3_IS_CLK_ENABLED
#define __SDADC3_IS_CLK_DISABLED __HAL_RCC_SDADC3_IS_CLK_DISABLED
#define __SRAM_IS_CLK_ENABLED __HAL_RCC_SRAM_IS_CLK_ENABLED
#define __SRAM_IS_CLK_DISABLED __HAL_RCC_SRAM_IS_CLK_DISABLED
#define __TIM1_IS_CLK_ENABLED __HAL_RCC_TIM1_IS_CLK_ENABLED
#define __TIM1_IS_CLK_DISABLED __HAL_RCC_TIM1_IS_CLK_DISABLED
#define __TIM2_IS_CLK_ENABLED __HAL_RCC_TIM2_IS_CLK_ENABLED
#define __TIM2_IS_CLK_DISABLED __HAL_RCC_TIM2_IS_CLK_DISABLED
#define __TIM3_IS_CLK_ENABLED __HAL_RCC_TIM3_IS_CLK_ENABLED
#define __TIM3_IS_CLK_DISABLED __HAL_RCC_TIM3_IS_CLK_DISABLED
#define __TIM4_IS_CLK_ENABLED __HAL_RCC_TIM4_IS_CLK_ENABLED
#define __TIM4_IS_CLK_DISABLED __HAL_RCC_TIM4_IS_CLK_DISABLED
#define __TIM5_IS_CLK_ENABLED __HAL_RCC_TIM5_IS_CLK_ENABLED
#define __TIM5_IS_CLK_DISABLED __HAL_RCC_TIM5_IS_CLK_DISABLED
#define __TIM6_IS_CLK_ENABLED __HAL_RCC_TIM6_IS_CLK_ENABLED
#define __TIM6_IS_CLK_DISABLED __HAL_RCC_TIM6_IS_CLK_DISABLED
#define __TIM7_IS_CLK_ENABLED __HAL_RCC_TIM7_IS_CLK_ENABLED
#define __TIM7_IS_CLK_DISABLED __HAL_RCC_TIM7_IS_CLK_DISABLED
#define __TIM8_IS_CLK_ENABLED __HAL_RCC_TIM8_IS_CLK_ENABLED
#define __TIM8_IS_CLK_DISABLED __HAL_RCC_TIM8_IS_CLK_DISABLED
#define __TIM12_IS_CLK_ENABLED __HAL_RCC_TIM12_IS_CLK_ENABLED
#define __TIM12_IS_CLK_DISABLED __HAL_RCC_TIM12_IS_CLK_DISABLED
#define __TIM13_IS_CLK_ENABLED __HAL_RCC_TIM13_IS_CLK_ENABLED
#define __TIM13_IS_CLK_DISABLED __HAL_RCC_TIM13_IS_CLK_DISABLED
#define __TIM14_IS_CLK_ENABLED __HAL_RCC_TIM14_IS_CLK_ENABLED
#define __TIM14_IS_CLK_DISABLED __HAL_RCC_TIM14_IS_CLK_DISABLED
#define __TIM15_IS_CLK_ENABLED __HAL_RCC_TIM15_IS_CLK_ENABLED
#define __TIM15_IS_CLK_DISABLED __HAL_RCC_TIM15_IS_CLK_DISABLED
#define __TIM16_IS_CLK_ENABLED __HAL_RCC_TIM16_IS_CLK_ENABLED
#define __TIM16_IS_CLK_DISABLED __HAL_RCC_TIM16_IS_CLK_DISABLED
#define __TIM17_IS_CLK_ENABLED __HAL_RCC_TIM17_IS_CLK_ENABLED
#define __TIM17_IS_CLK_DISABLED __HAL_RCC_TIM17_IS_CLK_DISABLED
#define __TIM18_IS_CLK_ENABLED __HAL_RCC_TIM18_IS_CLK_ENABLED
#define __TIM18_IS_CLK_DISABLED __HAL_RCC_TIM18_IS_CLK_DISABLED
#define __TIM19_IS_CLK_ENABLED __HAL_RCC_TIM19_IS_CLK_ENABLED
#define __TIM19_IS_CLK_DISABLED __HAL_RCC_TIM19_IS_CLK_DISABLED
#define __TIM20_IS_CLK_ENABLED __HAL_RCC_TIM20_IS_CLK_ENABLED
#define __TIM20_IS_CLK_DISABLED __HAL_RCC_TIM20_IS_CLK_DISABLED
#define __TSC_IS_CLK_ENABLED __HAL_RCC_TSC_IS_CLK_ENABLED
#define __TSC_IS_CLK_DISABLED __HAL_RCC_TSC_IS_CLK_DISABLED
#define __UART4_IS_CLK_ENABLED __HAL_RCC_UART4_IS_CLK_ENABLED
#define __UART4_IS_CLK_DISABLED __HAL_RCC_UART4_IS_CLK_DISABLED
#define __UART5_IS_CLK_ENABLED __HAL_RCC_UART5_IS_CLK_ENABLED
#define __UART5_IS_CLK_DISABLED __HAL_RCC_UART5_IS_CLK_DISABLED
#define __USART1_IS_CLK_ENABLED __HAL_RCC_USART1_IS_CLK_ENABLED
#define __USART1_IS_CLK_DISABLED __HAL_RCC_USART1_IS_CLK_DISABLED
#define __USART2_IS_CLK_ENABLED __HAL_RCC_USART2_IS_CLK_ENABLED
#define __USART2_IS_CLK_DISABLED __HAL_RCC_USART2_IS_CLK_DISABLED
#define __USART3_IS_CLK_ENABLED __HAL_RCC_USART3_IS_CLK_ENABLED
#define __USART3_IS_CLK_DISABLED __HAL_RCC_USART3_IS_CLK_DISABLED
#define __USB_IS_CLK_ENABLED __HAL_RCC_USB_IS_CLK_ENABLED
#define __USB_IS_CLK_DISABLED __HAL_RCC_USB_IS_CLK_DISABLED
#define __WWDG_IS_CLK_ENABLED __HAL_RCC_WWDG_IS_CLK_ENABLED
#define __WWDG_IS_CLK_DISABLED __HAL_RCC_WWDG_IS_CLK_DISABLED
#if defined(STM32L1)
#define __HAL_RCC_CRYP_CLK_DISABLE __HAL_RCC_AES_CLK_DISABLE
#define __HAL_RCC_CRYP_CLK_ENABLE __HAL_RCC_AES_CLK_ENABLE
#define __HAL_RCC_CRYP_CLK_SLEEP_DISABLE __HAL_RCC_AES_CLK_SLEEP_DISABLE
#define __HAL_RCC_CRYP_CLK_SLEEP_ENABLE __HAL_RCC_AES_CLK_SLEEP_ENABLE
#define __HAL_RCC_CRYP_FORCE_RESET __HAL_RCC_AES_FORCE_RESET
#define __HAL_RCC_CRYP_RELEASE_RESET __HAL_RCC_AES_RELEASE_RESET
#endif /* STM32L1 */
#if defined(STM32F4)
#define __HAL_RCC_SDMMC1_FORCE_RESET __HAL_RCC_SDIO_FORCE_RESET
#define __HAL_RCC_SDMMC1_RELEASE_RESET __HAL_RCC_SDIO_RELEASE_RESET
#define __HAL_RCC_SDMMC1_CLK_SLEEP_ENABLE __HAL_RCC_SDIO_CLK_SLEEP_ENABLE
#define __HAL_RCC_SDMMC1_CLK_SLEEP_DISABLE __HAL_RCC_SDIO_CLK_SLEEP_DISABLE
#define __HAL_RCC_SDMMC1_CLK_ENABLE __HAL_RCC_SDIO_CLK_ENABLE
#define __HAL_RCC_SDMMC1_CLK_DISABLE __HAL_RCC_SDIO_CLK_DISABLE
#define __HAL_RCC_SDMMC1_IS_CLK_ENABLED __HAL_RCC_SDIO_IS_CLK_ENABLED
#define __HAL_RCC_SDMMC1_IS_CLK_DISABLED __HAL_RCC_SDIO_IS_CLK_DISABLED
#define Sdmmc1ClockSelection SdioClockSelection
#define RCC_PERIPHCLK_SDMMC1 RCC_PERIPHCLK_SDIO
#define RCC_SDMMC1CLKSOURCE_CLK48 RCC_SDIOCLKSOURCE_CK48
#define RCC_SDMMC1CLKSOURCE_SYSCLK RCC_SDIOCLKSOURCE_SYSCLK
#define __HAL_RCC_SDMMC1_CONFIG __HAL_RCC_SDIO_CONFIG
#define __HAL_RCC_GET_SDMMC1_SOURCE __HAL_RCC_GET_SDIO_SOURCE
#endif
#if defined(STM32F7) || defined(STM32L4)
#define __HAL_RCC_SDIO_FORCE_RESET __HAL_RCC_SDMMC1_FORCE_RESET
#define __HAL_RCC_SDIO_RELEASE_RESET __HAL_RCC_SDMMC1_RELEASE_RESET
#define __HAL_RCC_SDIO_CLK_SLEEP_ENABLE __HAL_RCC_SDMMC1_CLK_SLEEP_ENABLE
#define __HAL_RCC_SDIO_CLK_SLEEP_DISABLE __HAL_RCC_SDMMC1_CLK_SLEEP_DISABLE
#define __HAL_RCC_SDIO_CLK_ENABLE __HAL_RCC_SDMMC1_CLK_ENABLE
#define __HAL_RCC_SDIO_CLK_DISABLE __HAL_RCC_SDMMC1_CLK_DISABLE
#define __HAL_RCC_SDIO_IS_CLK_ENABLED __HAL_RCC_SDMMC1_IS_CLK_ENABLED
#define __HAL_RCC_SDIO_IS_CLK_DISABLED __HAL_RCC_SDMMC1_IS_CLK_DISABLED
#define SdioClockSelection Sdmmc1ClockSelection
#define RCC_PERIPHCLK_SDIO RCC_PERIPHCLK_SDMMC1
#define __HAL_RCC_SDIO_CONFIG __HAL_RCC_SDMMC1_CONFIG
#define __HAL_RCC_GET_SDIO_SOURCE __HAL_RCC_GET_SDMMC1_SOURCE
#endif
#if defined(STM32F7)
#define RCC_SDIOCLKSOURCE_CLK48 RCC_SDMMC1CLKSOURCE_CLK48
#define RCC_SDIOCLKSOURCE_SYSCLK RCC_SDMMC1CLKSOURCE_SYSCLK
#endif
#if defined(STM32H7)
#define __HAL_RCC_USB_OTG_HS_CLK_ENABLE() __HAL_RCC_USB1_OTG_HS_CLK_ENABLE()
#define __HAL_RCC_USB_OTG_HS_ULPI_CLK_ENABLE() __HAL_RCC_USB1_OTG_HS_ULPI_CLK_ENABLE()
#define __HAL_RCC_USB_OTG_HS_CLK_DISABLE() __HAL_RCC_USB1_OTG_HS_CLK_DISABLE()
#define __HAL_RCC_USB_OTG_HS_ULPI_CLK_DISABLE() __HAL_RCC_USB1_OTG_HS_ULPI_CLK_DISABLE()
#define __HAL_RCC_USB_OTG_HS_FORCE_RESET() __HAL_RCC_USB1_OTG_HS_FORCE_RESET()
#define __HAL_RCC_USB_OTG_HS_RELEASE_RESET() __HAL_RCC_USB1_OTG_HS_RELEASE_RESET()
#define __HAL_RCC_USB_OTG_HS_CLK_SLEEP_ENABLE() __HAL_RCC_USB1_OTG_HS_CLK_SLEEP_ENABLE()
#define __HAL_RCC_USB_OTG_HS_ULPI_CLK_SLEEP_ENABLE() __HAL_RCC_USB1_OTG_HS_ULPI_CLK_SLEEP_ENABLE()
#define __HAL_RCC_USB_OTG_HS_CLK_SLEEP_DISABLE() __HAL_RCC_USB1_OTG_HS_CLK_SLEEP_DISABLE()
#define __HAL_RCC_USB_OTG_HS_ULPI_CLK_SLEEP_DISABLE() __HAL_RCC_USB1_OTG_HS_ULPI_CLK_SLEEP_DISABLE()
#define __HAL_RCC_USB_OTG_FS_CLK_ENABLE() __HAL_RCC_USB2_OTG_FS_CLK_ENABLE()
#define __HAL_RCC_USB_OTG_FS_ULPI_CLK_ENABLE() __HAL_RCC_USB2_OTG_FS_ULPI_CLK_ENABLE()
#define __HAL_RCC_USB_OTG_FS_CLK_DISABLE() __HAL_RCC_USB2_OTG_FS_CLK_DISABLE()
#define __HAL_RCC_USB_OTG_FS_ULPI_CLK_DISABLE() __HAL_RCC_USB2_OTG_FS_ULPI_CLK_DISABLE()
#define __HAL_RCC_USB_OTG_FS_FORCE_RESET() __HAL_RCC_USB2_OTG_FS_FORCE_RESET()
#define __HAL_RCC_USB_OTG_FS_RELEASE_RESET() __HAL_RCC_USB2_OTG_FS_RELEASE_RESET()
#define __HAL_RCC_USB_OTG_FS_CLK_SLEEP_ENABLE() __HAL_RCC_USB2_OTG_FS_CLK_SLEEP_ENABLE()
#define __HAL_RCC_USB_OTG_FS_ULPI_CLK_SLEEP_ENABLE() __HAL_RCC_USB2_OTG_FS_ULPI_CLK_SLEEP_ENABLE()
#define __HAL_RCC_USB_OTG_FS_CLK_SLEEP_DISABLE() __HAL_RCC_USB2_OTG_FS_CLK_SLEEP_DISABLE()
#define __HAL_RCC_USB_OTG_FS_ULPI_CLK_SLEEP_DISABLE() __HAL_RCC_USB2_OTG_FS_ULPI_CLK_SLEEP_DISABLE()
#endif
#define __HAL_RCC_I2SCLK __HAL_RCC_I2S_CONFIG
#define __HAL_RCC_I2SCLK_CONFIG __HAL_RCC_I2S_CONFIG
#define __RCC_PLLSRC RCC_GET_PLL_OSCSOURCE
#define IS_RCC_MSIRANGE IS_RCC_MSI_CLOCK_RANGE
#define IS_RCC_RTCCLK_SOURCE IS_RCC_RTCCLKSOURCE
#define IS_RCC_SYSCLK_DIV IS_RCC_HCLK
#define IS_RCC_HCLK_DIV IS_RCC_PCLK
#define IS_RCC_PERIPHCLK IS_RCC_PERIPHCLOCK
#define RCC_IT_HSI14 RCC_IT_HSI14RDY
#define RCC_IT_CSSLSE RCC_IT_LSECSS
#define RCC_IT_CSSHSE RCC_IT_CSS
#define RCC_PLLMUL_3 RCC_PLL_MUL3
#define RCC_PLLMUL_4 RCC_PLL_MUL4
#define RCC_PLLMUL_6 RCC_PLL_MUL6
#define RCC_PLLMUL_8 RCC_PLL_MUL8
#define RCC_PLLMUL_12 RCC_PLL_MUL12
#define RCC_PLLMUL_16 RCC_PLL_MUL16
#define RCC_PLLMUL_24 RCC_PLL_MUL24
#define RCC_PLLMUL_32 RCC_PLL_MUL32
#define RCC_PLLMUL_48 RCC_PLL_MUL48
#define RCC_PLLDIV_2 RCC_PLL_DIV2
#define RCC_PLLDIV_3 RCC_PLL_DIV3
#define RCC_PLLDIV_4 RCC_PLL_DIV4
#define IS_RCC_MCOSOURCE IS_RCC_MCO1SOURCE
#define __HAL_RCC_MCO_CONFIG __HAL_RCC_MCO1_CONFIG
#define RCC_MCO_NODIV RCC_MCODIV_1
#define RCC_MCO_DIV1 RCC_MCODIV_1
#define RCC_MCO_DIV2 RCC_MCODIV_2
#define RCC_MCO_DIV4 RCC_MCODIV_4
#define RCC_MCO_DIV8 RCC_MCODIV_8
#define RCC_MCO_DIV16 RCC_MCODIV_16
#define RCC_MCO_DIV32 RCC_MCODIV_32
#define RCC_MCO_DIV64 RCC_MCODIV_64
#define RCC_MCO_DIV128 RCC_MCODIV_128
#define RCC_MCOSOURCE_NONE RCC_MCO1SOURCE_NOCLOCK
#define RCC_MCOSOURCE_LSI RCC_MCO1SOURCE_LSI
#define RCC_MCOSOURCE_LSE RCC_MCO1SOURCE_LSE
#define RCC_MCOSOURCE_SYSCLK RCC_MCO1SOURCE_SYSCLK
#define RCC_MCOSOURCE_HSI RCC_MCO1SOURCE_HSI
#define RCC_MCOSOURCE_HSI14 RCC_MCO1SOURCE_HSI14
#define RCC_MCOSOURCE_HSI48 RCC_MCO1SOURCE_HSI48
#define RCC_MCOSOURCE_HSE RCC_MCO1SOURCE_HSE
#define RCC_MCOSOURCE_PLLCLK_DIV1 RCC_MCO1SOURCE_PLLCLK
#define RCC_MCOSOURCE_PLLCLK_NODIV RCC_MCO1SOURCE_PLLCLK
#define RCC_MCOSOURCE_PLLCLK_DIV2 RCC_MCO1SOURCE_PLLCLK_DIV2
#if defined(STM32L4) || defined(STM32WB) || defined(STM32G0) || defined(STM32G4) || defined(STM32L5)
#define RCC_RTCCLKSOURCE_NO_CLK RCC_RTCCLKSOURCE_NONE
#else
#define RCC_RTCCLKSOURCE_NONE RCC_RTCCLKSOURCE_NO_CLK
#endif
#define RCC_USBCLK_PLLSAI1 RCC_USBCLKSOURCE_PLLSAI1
#define RCC_USBCLK_PLL RCC_USBCLKSOURCE_PLL
#define RCC_USBCLK_MSI RCC_USBCLKSOURCE_MSI
#define RCC_USBCLKSOURCE_PLLCLK RCC_USBCLKSOURCE_PLL
#define RCC_USBPLLCLK_DIV1 RCC_USBCLKSOURCE_PLL
#define RCC_USBPLLCLK_DIV1_5 RCC_USBCLKSOURCE_PLL_DIV1_5
#define RCC_USBPLLCLK_DIV2 RCC_USBCLKSOURCE_PLL_DIV2
#define RCC_USBPLLCLK_DIV3 RCC_USBCLKSOURCE_PLL_DIV3
#define HSION_BitNumber RCC_HSION_BIT_NUMBER
#define HSION_BITNUMBER RCC_HSION_BIT_NUMBER
#define HSEON_BitNumber RCC_HSEON_BIT_NUMBER
#define HSEON_BITNUMBER RCC_HSEON_BIT_NUMBER
#define MSION_BITNUMBER RCC_MSION_BIT_NUMBER
#define CSSON_BitNumber RCC_CSSON_BIT_NUMBER
#define CSSON_BITNUMBER RCC_CSSON_BIT_NUMBER
#define PLLON_BitNumber RCC_PLLON_BIT_NUMBER
#define PLLON_BITNUMBER RCC_PLLON_BIT_NUMBER
#define PLLI2SON_BitNumber RCC_PLLI2SON_BIT_NUMBER
#define I2SSRC_BitNumber RCC_I2SSRC_BIT_NUMBER
#define RTCEN_BitNumber RCC_RTCEN_BIT_NUMBER
#define RTCEN_BITNUMBER RCC_RTCEN_BIT_NUMBER
#define BDRST_BitNumber RCC_BDRST_BIT_NUMBER
#define BDRST_BITNUMBER RCC_BDRST_BIT_NUMBER
#define RTCRST_BITNUMBER RCC_RTCRST_BIT_NUMBER
#define LSION_BitNumber RCC_LSION_BIT_NUMBER
#define LSION_BITNUMBER RCC_LSION_BIT_NUMBER
#define LSEON_BitNumber RCC_LSEON_BIT_NUMBER
#define LSEON_BITNUMBER RCC_LSEON_BIT_NUMBER
#define LSEBYP_BITNUMBER RCC_LSEBYP_BIT_NUMBER
#define PLLSAION_BitNumber RCC_PLLSAION_BIT_NUMBER
#define TIMPRE_BitNumber RCC_TIMPRE_BIT_NUMBER
#define RMVF_BitNumber RCC_RMVF_BIT_NUMBER
#define RMVF_BITNUMBER RCC_RMVF_BIT_NUMBER
#define RCC_CR2_HSI14TRIM_BitNumber RCC_HSI14TRIM_BIT_NUMBER
#define CR_BYTE2_ADDRESS RCC_CR_BYTE2_ADDRESS
#define CIR_BYTE1_ADDRESS RCC_CIR_BYTE1_ADDRESS
#define CIR_BYTE2_ADDRESS RCC_CIR_BYTE2_ADDRESS
#define BDCR_BYTE0_ADDRESS RCC_BDCR_BYTE0_ADDRESS
#define DBP_TIMEOUT_VALUE RCC_DBP_TIMEOUT_VALUE
#define LSE_TIMEOUT_VALUE RCC_LSE_TIMEOUT_VALUE
#define CR_HSION_BB RCC_CR_HSION_BB
#define CR_CSSON_BB RCC_CR_CSSON_BB
#define CR_PLLON_BB RCC_CR_PLLON_BB
#define CR_PLLI2SON_BB RCC_CR_PLLI2SON_BB
#define CR_MSION_BB RCC_CR_MSION_BB
#define CSR_LSION_BB RCC_CSR_LSION_BB
#define CSR_LSEON_BB RCC_CSR_LSEON_BB
#define CSR_LSEBYP_BB RCC_CSR_LSEBYP_BB
#define CSR_RTCEN_BB RCC_CSR_RTCEN_BB
#define CSR_RTCRST_BB RCC_CSR_RTCRST_BB
#define CFGR_I2SSRC_BB RCC_CFGR_I2SSRC_BB
#define BDCR_RTCEN_BB RCC_BDCR_RTCEN_BB
#define BDCR_BDRST_BB RCC_BDCR_BDRST_BB
#define CR_HSEON_BB RCC_CR_HSEON_BB
#define CSR_RMVF_BB RCC_CSR_RMVF_BB
#define CR_PLLSAION_BB RCC_CR_PLLSAION_BB
#define DCKCFGR_TIMPRE_BB RCC_DCKCFGR_TIMPRE_BB
#define __HAL_RCC_CRS_ENABLE_FREQ_ERROR_COUNTER __HAL_RCC_CRS_FREQ_ERROR_COUNTER_ENABLE
#define __HAL_RCC_CRS_DISABLE_FREQ_ERROR_COUNTER __HAL_RCC_CRS_FREQ_ERROR_COUNTER_DISABLE
#define __HAL_RCC_CRS_ENABLE_AUTOMATIC_CALIB __HAL_RCC_CRS_AUTOMATIC_CALIB_ENABLE
#define __HAL_RCC_CRS_DISABLE_AUTOMATIC_CALIB __HAL_RCC_CRS_AUTOMATIC_CALIB_DISABLE
#define __HAL_RCC_CRS_CALCULATE_RELOADVALUE __HAL_RCC_CRS_RELOADVALUE_CALCULATE
#define __HAL_RCC_GET_IT_SOURCE __HAL_RCC_GET_IT
#define RCC_CRS_SYNCWARM RCC_CRS_SYNCWARN
#define RCC_CRS_TRIMOV RCC_CRS_TRIMOVF
#define RCC_PERIPHCLK_CK48 RCC_PERIPHCLK_CLK48
#define RCC_CK48CLKSOURCE_PLLQ RCC_CLK48CLKSOURCE_PLLQ
#define RCC_CK48CLKSOURCE_PLLSAIP RCC_CLK48CLKSOURCE_PLLSAIP
#define RCC_CK48CLKSOURCE_PLLI2SQ RCC_CLK48CLKSOURCE_PLLI2SQ
#define IS_RCC_CK48CLKSOURCE IS_RCC_CLK48CLKSOURCE
#define RCC_SDIOCLKSOURCE_CK48 RCC_SDIOCLKSOURCE_CLK48
#define __HAL_RCC_DFSDM_CLK_ENABLE __HAL_RCC_DFSDM1_CLK_ENABLE
#define __HAL_RCC_DFSDM_CLK_DISABLE __HAL_RCC_DFSDM1_CLK_DISABLE
#define __HAL_RCC_DFSDM_IS_CLK_ENABLED __HAL_RCC_DFSDM1_IS_CLK_ENABLED
#define __HAL_RCC_DFSDM_IS_CLK_DISABLED __HAL_RCC_DFSDM1_IS_CLK_DISABLED
#define __HAL_RCC_DFSDM_FORCE_RESET __HAL_RCC_DFSDM1_FORCE_RESET
#define __HAL_RCC_DFSDM_RELEASE_RESET __HAL_RCC_DFSDM1_RELEASE_RESET
#define __HAL_RCC_DFSDM_CLK_SLEEP_ENABLE __HAL_RCC_DFSDM1_CLK_SLEEP_ENABLE
#define __HAL_RCC_DFSDM_CLK_SLEEP_DISABLE __HAL_RCC_DFSDM1_CLK_SLEEP_DISABLE
#define __HAL_RCC_DFSDM_IS_CLK_SLEEP_ENABLED __HAL_RCC_DFSDM1_IS_CLK_SLEEP_ENABLED
#define __HAL_RCC_DFSDM_IS_CLK_SLEEP_DISABLED __HAL_RCC_DFSDM1_IS_CLK_SLEEP_DISABLED
#define DfsdmClockSelection Dfsdm1ClockSelection
#define RCC_PERIPHCLK_DFSDM RCC_PERIPHCLK_DFSDM1
#define RCC_DFSDMCLKSOURCE_PCLK RCC_DFSDM1CLKSOURCE_PCLK2
#define RCC_DFSDMCLKSOURCE_SYSCLK RCC_DFSDM1CLKSOURCE_SYSCLK
#define __HAL_RCC_DFSDM_CONFIG __HAL_RCC_DFSDM1_CONFIG
#define __HAL_RCC_GET_DFSDM_SOURCE __HAL_RCC_GET_DFSDM1_SOURCE
#define RCC_DFSDM1CLKSOURCE_PCLK RCC_DFSDM1CLKSOURCE_PCLK2
#define RCC_SWPMI1CLKSOURCE_PCLK RCC_SWPMI1CLKSOURCE_PCLK1
#define RCC_LPTIM1CLKSOURCE_PCLK RCC_LPTIM1CLKSOURCE_PCLK1
#define RCC_LPTIM2CLKSOURCE_PCLK RCC_LPTIM2CLKSOURCE_PCLK1
#define RCC_DFSDM1AUDIOCLKSOURCE_I2SAPB1 RCC_DFSDM1AUDIOCLKSOURCE_I2S1
#define RCC_DFSDM1AUDIOCLKSOURCE_I2SAPB2 RCC_DFSDM1AUDIOCLKSOURCE_I2S2
#define RCC_DFSDM2AUDIOCLKSOURCE_I2SAPB1 RCC_DFSDM2AUDIOCLKSOURCE_I2S1
#define RCC_DFSDM2AUDIOCLKSOURCE_I2SAPB2 RCC_DFSDM2AUDIOCLKSOURCE_I2S2
#define RCC_DFSDM1CLKSOURCE_APB2 RCC_DFSDM1CLKSOURCE_PCLK2
#define RCC_DFSDM2CLKSOURCE_APB2 RCC_DFSDM2CLKSOURCE_PCLK2
#define RCC_FMPI2C1CLKSOURCE_APB RCC_FMPI2C1CLKSOURCE_PCLK1
/**
* @}
*/
/** @defgroup HAL_RNG_Aliased_Macros HAL RNG Aliased Macros maintained for legacy purpose
* @{
*/
#define HAL_RNG_ReadyCallback(__HANDLE__) HAL_RNG_ReadyDataCallback((__HANDLE__), uint32_t random32bit)
/**
* @}
*/
/** @defgroup HAL_RTC_Aliased_Macros HAL RTC Aliased Macros maintained for legacy purpose
* @{
*/
#if defined (STM32G0) || defined (STM32L5) || defined (STM32L412xx) || defined (STM32L422xx) || defined (STM32L4P5xx)|| defined (STM32L4Q5xx) || defined (STM32G4)
#else
#define __HAL_RTC_CLEAR_FLAG __HAL_RTC_EXTI_CLEAR_FLAG
#endif
#define __HAL_RTC_DISABLE_IT __HAL_RTC_EXTI_DISABLE_IT
#define __HAL_RTC_ENABLE_IT __HAL_RTC_EXTI_ENABLE_IT
#if defined (STM32F1)
#define __HAL_RTC_EXTI_CLEAR_FLAG(RTC_EXTI_LINE_ALARM_EVENT) __HAL_RTC_ALARM_EXTI_CLEAR_FLAG()
#define __HAL_RTC_EXTI_ENABLE_IT(RTC_EXTI_LINE_ALARM_EVENT) __HAL_RTC_ALARM_EXTI_ENABLE_IT()
#define __HAL_RTC_EXTI_DISABLE_IT(RTC_EXTI_LINE_ALARM_EVENT) __HAL_RTC_ALARM_EXTI_DISABLE_IT()
#define __HAL_RTC_EXTI_GET_FLAG(RTC_EXTI_LINE_ALARM_EVENT) __HAL_RTC_ALARM_EXTI_GET_FLAG()
#define __HAL_RTC_EXTI_GENERATE_SWIT(RTC_EXTI_LINE_ALARM_EVENT) __HAL_RTC_ALARM_EXTI_GENERATE_SWIT()
#else
#define __HAL_RTC_EXTI_CLEAR_FLAG(__EXTI_LINE__) (((__EXTI_LINE__) == RTC_EXTI_LINE_ALARM_EVENT) ? __HAL_RTC_ALARM_EXTI_CLEAR_FLAG() : \
(((__EXTI_LINE__) == RTC_EXTI_LINE_WAKEUPTIMER_EVENT) ? __HAL_RTC_WAKEUPTIMER_EXTI_CLEAR_FLAG() : \
__HAL_RTC_TAMPER_TIMESTAMP_EXTI_CLEAR_FLAG()))
#define __HAL_RTC_EXTI_ENABLE_IT(__EXTI_LINE__) (((__EXTI_LINE__) == RTC_EXTI_LINE_ALARM_EVENT) ? __HAL_RTC_ALARM_EXTI_ENABLE_IT() : \
(((__EXTI_LINE__) == RTC_EXTI_LINE_WAKEUPTIMER_EVENT) ? __HAL_RTC_WAKEUPTIMER_EXTI_ENABLE_IT() : \
__HAL_RTC_TAMPER_TIMESTAMP_EXTI_ENABLE_IT()))
#define __HAL_RTC_EXTI_DISABLE_IT(__EXTI_LINE__) (((__EXTI_LINE__) == RTC_EXTI_LINE_ALARM_EVENT) ? __HAL_RTC_ALARM_EXTI_DISABLE_IT() : \
(((__EXTI_LINE__) == RTC_EXTI_LINE_WAKEUPTIMER_EVENT) ? __HAL_RTC_WAKEUPTIMER_EXTI_DISABLE_IT() : \
__HAL_RTC_TAMPER_TIMESTAMP_EXTI_DISABLE_IT()))
#define __HAL_RTC_EXTI_GET_FLAG(__EXTI_LINE__) (((__EXTI_LINE__) == RTC_EXTI_LINE_ALARM_EVENT) ? __HAL_RTC_ALARM_EXTI_GET_FLAG() : \
(((__EXTI_LINE__) == RTC_EXTI_LINE_WAKEUPTIMER_EVENT) ? __HAL_RTC_WAKEUPTIMER_EXTI_GET_FLAG() : \
__HAL_RTC_TAMPER_TIMESTAMP_EXTI_GET_FLAG()))
#define __HAL_RTC_EXTI_GENERATE_SWIT(__EXTI_LINE__) (((__EXTI_LINE__) == RTC_EXTI_LINE_ALARM_EVENT) ? __HAL_RTC_ALARM_EXTI_GENERATE_SWIT() : \
(((__EXTI_LINE__) == RTC_EXTI_LINE_WAKEUPTIMER_EVENT) ? __HAL_RTC_WAKEUPTIMER_EXTI_GENERATE_SWIT() : \
__HAL_RTC_TAMPER_TIMESTAMP_EXTI_GENERATE_SWIT()))
#endif /* STM32F1 */
#if defined (STM32F0) || defined (STM32F2) || defined (STM32F3) || defined (STM32F4) || defined (STM32F7) || \
defined (STM32H7) || \
defined (STM32L0) || defined (STM32L1) || \
defined (STM32WB)
#define __HAL_RTC_TAMPER_GET_IT __HAL_RTC_TAMPER_GET_FLAG
#endif
#define IS_ALARM IS_RTC_ALARM
#define IS_ALARM_MASK IS_RTC_ALARM_MASK
#define IS_TAMPER IS_RTC_TAMPER
#define IS_TAMPER_ERASE_MODE IS_RTC_TAMPER_ERASE_MODE
#define IS_TAMPER_FILTER IS_RTC_TAMPER_FILTER
#define IS_TAMPER_INTERRUPT IS_RTC_TAMPER_INTERRUPT
#define IS_TAMPER_MASKFLAG_STATE IS_RTC_TAMPER_MASKFLAG_STATE
#define IS_TAMPER_PRECHARGE_DURATION IS_RTC_TAMPER_PRECHARGE_DURATION
#define IS_TAMPER_PULLUP_STATE IS_RTC_TAMPER_PULLUP_STATE
#define IS_TAMPER_SAMPLING_FREQ IS_RTC_TAMPER_SAMPLING_FREQ
#define IS_TAMPER_TIMESTAMPONTAMPER_DETECTION IS_RTC_TAMPER_TIMESTAMPONTAMPER_DETECTION
#define IS_TAMPER_TRIGGER IS_RTC_TAMPER_TRIGGER
#define IS_WAKEUP_CLOCK IS_RTC_WAKEUP_CLOCK
#define IS_WAKEUP_COUNTER IS_RTC_WAKEUP_COUNTER
#define __RTC_WRITEPROTECTION_ENABLE __HAL_RTC_WRITEPROTECTION_ENABLE
#define __RTC_WRITEPROTECTION_DISABLE __HAL_RTC_WRITEPROTECTION_DISABLE
/**
* @}
*/
/** @defgroup HAL_SD_Aliased_Macros HAL SD/MMC Aliased Macros maintained for legacy purpose
* @{
*/
#define SD_OCR_CID_CSD_OVERWRIETE SD_OCR_CID_CSD_OVERWRITE
#define SD_CMD_SD_APP_STAUS SD_CMD_SD_APP_STATUS
#if !defined(STM32F1) && !defined(STM32F2) && !defined(STM32F4) && !defined(STM32L1)
#define eMMC_HIGH_VOLTAGE_RANGE EMMC_HIGH_VOLTAGE_RANGE
#define eMMC_DUAL_VOLTAGE_RANGE EMMC_DUAL_VOLTAGE_RANGE
#define eMMC_LOW_VOLTAGE_RANGE EMMC_LOW_VOLTAGE_RANGE
#define SDMMC_NSpeed_CLK_DIV SDMMC_NSPEED_CLK_DIV
#define SDMMC_HSpeed_CLK_DIV SDMMC_HSPEED_CLK_DIV
#endif
#if defined(STM32F4) || defined(STM32F2)
#define SD_SDMMC_DISABLED SD_SDIO_DISABLED
#define SD_SDMMC_FUNCTION_BUSY SD_SDIO_FUNCTION_BUSY
#define SD_SDMMC_FUNCTION_FAILED SD_SDIO_FUNCTION_FAILED
#define SD_SDMMC_UNKNOWN_FUNCTION SD_SDIO_UNKNOWN_FUNCTION
#define SD_CMD_SDMMC_SEN_OP_COND SD_CMD_SDIO_SEN_OP_COND
#define SD_CMD_SDMMC_RW_DIRECT SD_CMD_SDIO_RW_DIRECT
#define SD_CMD_SDMMC_RW_EXTENDED SD_CMD_SDIO_RW_EXTENDED
#define __HAL_SD_SDMMC_ENABLE __HAL_SD_SDIO_ENABLE
#define __HAL_SD_SDMMC_DISABLE __HAL_SD_SDIO_DISABLE
#define __HAL_SD_SDMMC_DMA_ENABLE __HAL_SD_SDIO_DMA_ENABLE
#define __HAL_SD_SDMMC_DMA_DISABLE __HAL_SD_SDIO_DMA_DISABL
#define __HAL_SD_SDMMC_ENABLE_IT __HAL_SD_SDIO_ENABLE_IT
#define __HAL_SD_SDMMC_DISABLE_IT __HAL_SD_SDIO_DISABLE_IT
#define __HAL_SD_SDMMC_GET_FLAG __HAL_SD_SDIO_GET_FLAG
#define __HAL_SD_SDMMC_CLEAR_FLAG __HAL_SD_SDIO_CLEAR_FLAG
#define __HAL_SD_SDMMC_GET_IT __HAL_SD_SDIO_GET_IT
#define __HAL_SD_SDMMC_CLEAR_IT __HAL_SD_SDIO_CLEAR_IT
#define SDMMC_STATIC_FLAGS SDIO_STATIC_FLAGS
#define SDMMC_CMD0TIMEOUT SDIO_CMD0TIMEOUT
#define SD_SDMMC_SEND_IF_COND SD_SDIO_SEND_IF_COND
/* alias CMSIS */
#define SDMMC1_IRQn SDIO_IRQn
#define SDMMC1_IRQHandler SDIO_IRQHandler
#endif
#if defined(STM32F7) || defined(STM32L4)
#define SD_SDIO_DISABLED SD_SDMMC_DISABLED
#define SD_SDIO_FUNCTION_BUSY SD_SDMMC_FUNCTION_BUSY
#define SD_SDIO_FUNCTION_FAILED SD_SDMMC_FUNCTION_FAILED
#define SD_SDIO_UNKNOWN_FUNCTION SD_SDMMC_UNKNOWN_FUNCTION
#define SD_CMD_SDIO_SEN_OP_COND SD_CMD_SDMMC_SEN_OP_COND
#define SD_CMD_SDIO_RW_DIRECT SD_CMD_SDMMC_RW_DIRECT
#define SD_CMD_SDIO_RW_EXTENDED SD_CMD_SDMMC_RW_EXTENDED
#define __HAL_SD_SDIO_ENABLE __HAL_SD_SDMMC_ENABLE
#define __HAL_SD_SDIO_DISABLE __HAL_SD_SDMMC_DISABLE
#define __HAL_SD_SDIO_DMA_ENABLE __HAL_SD_SDMMC_DMA_ENABLE
#define __HAL_SD_SDIO_DMA_DISABL __HAL_SD_SDMMC_DMA_DISABLE
#define __HAL_SD_SDIO_ENABLE_IT __HAL_SD_SDMMC_ENABLE_IT
#define __HAL_SD_SDIO_DISABLE_IT __HAL_SD_SDMMC_DISABLE_IT
#define __HAL_SD_SDIO_GET_FLAG __HAL_SD_SDMMC_GET_FLAG
#define __HAL_SD_SDIO_CLEAR_FLAG __HAL_SD_SDMMC_CLEAR_FLAG
#define __HAL_SD_SDIO_GET_IT __HAL_SD_SDMMC_GET_IT
#define __HAL_SD_SDIO_CLEAR_IT __HAL_SD_SDMMC_CLEAR_IT
#define SDIO_STATIC_FLAGS SDMMC_STATIC_FLAGS
#define SDIO_CMD0TIMEOUT SDMMC_CMD0TIMEOUT
#define SD_SDIO_SEND_IF_COND SD_SDMMC_SEND_IF_COND
/* alias CMSIS for compatibilities */
#define SDIO_IRQn SDMMC1_IRQn
#define SDIO_IRQHandler SDMMC1_IRQHandler
#endif
#if defined(STM32F7) || defined(STM32F4) || defined(STM32F2) || defined(STM32L4) || defined(STM32H7)
#define HAL_SD_CardCIDTypedef HAL_SD_CardCIDTypeDef
#define HAL_SD_CardCSDTypedef HAL_SD_CardCSDTypeDef
#define HAL_SD_CardStatusTypedef HAL_SD_CardStatusTypeDef
#define HAL_SD_CardStateTypedef HAL_SD_CardStateTypeDef
#endif
#if defined(STM32H7) || defined(STM32L5)
#define HAL_MMCEx_Read_DMADoubleBuffer0CpltCallback HAL_MMCEx_Read_DMADoubleBuf0CpltCallback
#define HAL_MMCEx_Read_DMADoubleBuffer1CpltCallback HAL_MMCEx_Read_DMADoubleBuf1CpltCallback
#define HAL_MMCEx_Write_DMADoubleBuffer0CpltCallback HAL_MMCEx_Write_DMADoubleBuf0CpltCallback
#define HAL_MMCEx_Write_DMADoubleBuffer1CpltCallback HAL_MMCEx_Write_DMADoubleBuf1CpltCallback
#define HAL_SDEx_Read_DMADoubleBuffer0CpltCallback HAL_SDEx_Read_DMADoubleBuf0CpltCallback
#define HAL_SDEx_Read_DMADoubleBuffer1CpltCallback HAL_SDEx_Read_DMADoubleBuf1CpltCallback
#define HAL_SDEx_Write_DMADoubleBuffer0CpltCallback HAL_SDEx_Write_DMADoubleBuf0CpltCallback
#define HAL_SDEx_Write_DMADoubleBuffer1CpltCallback HAL_SDEx_Write_DMADoubleBuf1CpltCallback
#define HAL_SD_DriveTransciver_1_8V_Callback HAL_SD_DriveTransceiver_1_8V_Callback
#endif
/**
* @}
*/
/** @defgroup HAL_SMARTCARD_Aliased_Macros HAL SMARTCARD Aliased Macros maintained for legacy purpose
* @{
*/
#define __SMARTCARD_ENABLE_IT __HAL_SMARTCARD_ENABLE_IT
#define __SMARTCARD_DISABLE_IT __HAL_SMARTCARD_DISABLE_IT
#define __SMARTCARD_ENABLE __HAL_SMARTCARD_ENABLE
#define __SMARTCARD_DISABLE __HAL_SMARTCARD_DISABLE
#define __SMARTCARD_DMA_REQUEST_ENABLE __HAL_SMARTCARD_DMA_REQUEST_ENABLE
#define __SMARTCARD_DMA_REQUEST_DISABLE __HAL_SMARTCARD_DMA_REQUEST_DISABLE
#define __HAL_SMARTCARD_GETCLOCKSOURCE SMARTCARD_GETCLOCKSOURCE
#define __SMARTCARD_GETCLOCKSOURCE SMARTCARD_GETCLOCKSOURCE
#define IS_SMARTCARD_ONEBIT_SAMPLING IS_SMARTCARD_ONE_BIT_SAMPLE
/**
* @}
*/
/** @defgroup HAL_SMBUS_Aliased_Macros HAL SMBUS Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_SMBUS_RESET_CR1 SMBUS_RESET_CR1
#define __HAL_SMBUS_RESET_CR2 SMBUS_RESET_CR2
#define __HAL_SMBUS_GENERATE_START SMBUS_GENERATE_START
#define __HAL_SMBUS_GET_ADDR_MATCH SMBUS_GET_ADDR_MATCH
#define __HAL_SMBUS_GET_DIR SMBUS_GET_DIR
#define __HAL_SMBUS_GET_STOP_MODE SMBUS_GET_STOP_MODE
#define __HAL_SMBUS_GET_PEC_MODE SMBUS_GET_PEC_MODE
#define __HAL_SMBUS_GET_ALERT_ENABLED SMBUS_GET_ALERT_ENABLED
/**
* @}
*/
/** @defgroup HAL_SPI_Aliased_Macros HAL SPI Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_SPI_1LINE_TX SPI_1LINE_TX
#define __HAL_SPI_1LINE_RX SPI_1LINE_RX
#define __HAL_SPI_RESET_CRC SPI_RESET_CRC
/**
* @}
*/
/** @defgroup HAL_UART_Aliased_Macros HAL UART Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_UART_GETCLOCKSOURCE UART_GETCLOCKSOURCE
#define __HAL_UART_MASK_COMPUTATION UART_MASK_COMPUTATION
#define __UART_GETCLOCKSOURCE UART_GETCLOCKSOURCE
#define __UART_MASK_COMPUTATION UART_MASK_COMPUTATION
#define IS_UART_WAKEUPMETHODE IS_UART_WAKEUPMETHOD
#define IS_UART_ONEBIT_SAMPLE IS_UART_ONE_BIT_SAMPLE
#define IS_UART_ONEBIT_SAMPLING IS_UART_ONE_BIT_SAMPLE
/**
* @}
*/
/** @defgroup HAL_USART_Aliased_Macros HAL USART Aliased Macros maintained for legacy purpose
* @{
*/
#define __USART_ENABLE_IT __HAL_USART_ENABLE_IT
#define __USART_DISABLE_IT __HAL_USART_DISABLE_IT
#define __USART_ENABLE __HAL_USART_ENABLE
#define __USART_DISABLE __HAL_USART_DISABLE
#define __HAL_USART_GETCLOCKSOURCE USART_GETCLOCKSOURCE
#define __USART_GETCLOCKSOURCE USART_GETCLOCKSOURCE
#if defined(STM32F0) || defined(STM32F3) || defined(STM32F7)
#define USART_OVERSAMPLING_16 0x00000000U
#define USART_OVERSAMPLING_8 USART_CR1_OVER8
#define IS_USART_OVERSAMPLING(__SAMPLING__) (((__SAMPLING__) == USART_OVERSAMPLING_16) || \
((__SAMPLING__) == USART_OVERSAMPLING_8))
#endif /* STM32F0 || STM32F3 || STM32F7 */
/**
* @}
*/
/** @defgroup HAL_USB_Aliased_Macros HAL USB Aliased Macros maintained for legacy purpose
* @{
*/
#define USB_EXTI_LINE_WAKEUP USB_WAKEUP_EXTI_LINE
#define USB_FS_EXTI_TRIGGER_RISING_EDGE USB_OTG_FS_WAKEUP_EXTI_RISING_EDGE
#define USB_FS_EXTI_TRIGGER_FALLING_EDGE USB_OTG_FS_WAKEUP_EXTI_FALLING_EDGE
#define USB_FS_EXTI_TRIGGER_BOTH_EDGE USB_OTG_FS_WAKEUP_EXTI_RISING_FALLING_EDGE
#define USB_FS_EXTI_LINE_WAKEUP USB_OTG_FS_WAKEUP_EXTI_LINE
#define USB_HS_EXTI_TRIGGER_RISING_EDGE USB_OTG_HS_WAKEUP_EXTI_RISING_EDGE
#define USB_HS_EXTI_TRIGGER_FALLING_EDGE USB_OTG_HS_WAKEUP_EXTI_FALLING_EDGE
#define USB_HS_EXTI_TRIGGER_BOTH_EDGE USB_OTG_HS_WAKEUP_EXTI_RISING_FALLING_EDGE
#define USB_HS_EXTI_LINE_WAKEUP USB_OTG_HS_WAKEUP_EXTI_LINE
#define __HAL_USB_EXTI_ENABLE_IT __HAL_USB_WAKEUP_EXTI_ENABLE_IT
#define __HAL_USB_EXTI_DISABLE_IT __HAL_USB_WAKEUP_EXTI_DISABLE_IT
#define __HAL_USB_EXTI_GET_FLAG __HAL_USB_WAKEUP_EXTI_GET_FLAG
#define __HAL_USB_EXTI_CLEAR_FLAG __HAL_USB_WAKEUP_EXTI_CLEAR_FLAG
#define __HAL_USB_EXTI_SET_RISING_EDGE_TRIGGER __HAL_USB_WAKEUP_EXTI_ENABLE_RISING_EDGE
#define __HAL_USB_EXTI_SET_FALLING_EDGE_TRIGGER __HAL_USB_WAKEUP_EXTI_ENABLE_FALLING_EDGE
#define __HAL_USB_EXTI_SET_FALLINGRISING_TRIGGER __HAL_USB_WAKEUP_EXTI_ENABLE_RISING_FALLING_EDGE
#define __HAL_USB_FS_EXTI_ENABLE_IT __HAL_USB_OTG_FS_WAKEUP_EXTI_ENABLE_IT
#define __HAL_USB_FS_EXTI_DISABLE_IT __HAL_USB_OTG_FS_WAKEUP_EXTI_DISABLE_IT
#define __HAL_USB_FS_EXTI_GET_FLAG __HAL_USB_OTG_FS_WAKEUP_EXTI_GET_FLAG
#define __HAL_USB_FS_EXTI_CLEAR_FLAG __HAL_USB_OTG_FS_WAKEUP_EXTI_CLEAR_FLAG
#define __HAL_USB_FS_EXTI_SET_RISING_EGDE_TRIGGER __HAL_USB_OTG_FS_WAKEUP_EXTI_ENABLE_RISING_EDGE
#define __HAL_USB_FS_EXTI_SET_FALLING_EGDE_TRIGGER __HAL_USB_OTG_FS_WAKEUP_EXTI_ENABLE_FALLING_EDGE
#define __HAL_USB_FS_EXTI_SET_FALLINGRISING_TRIGGER __HAL_USB_OTG_FS_WAKEUP_EXTI_ENABLE_RISING_FALLING_EDGE
#define __HAL_USB_FS_EXTI_GENERATE_SWIT __HAL_USB_OTG_FS_WAKEUP_EXTI_GENERATE_SWIT
#define __HAL_USB_HS_EXTI_ENABLE_IT __HAL_USB_OTG_HS_WAKEUP_EXTI_ENABLE_IT
#define __HAL_USB_HS_EXTI_DISABLE_IT __HAL_USB_OTG_HS_WAKEUP_EXTI_DISABLE_IT
#define __HAL_USB_HS_EXTI_GET_FLAG __HAL_USB_OTG_HS_WAKEUP_EXTI_GET_FLAG
#define __HAL_USB_HS_EXTI_CLEAR_FLAG __HAL_USB_OTG_HS_WAKEUP_EXTI_CLEAR_FLAG
#define __HAL_USB_HS_EXTI_SET_RISING_EGDE_TRIGGER __HAL_USB_OTG_HS_WAKEUP_EXTI_ENABLE_RISING_EDGE
#define __HAL_USB_HS_EXTI_SET_FALLING_EGDE_TRIGGER __HAL_USB_OTG_HS_WAKEUP_EXTI_ENABLE_FALLING_EDGE
#define __HAL_USB_HS_EXTI_SET_FALLINGRISING_TRIGGER __HAL_USB_OTG_HS_WAKEUP_EXTI_ENABLE_RISING_FALLING_EDGE
#define __HAL_USB_HS_EXTI_GENERATE_SWIT __HAL_USB_OTG_HS_WAKEUP_EXTI_GENERATE_SWIT
#define HAL_PCD_ActiveRemoteWakeup HAL_PCD_ActivateRemoteWakeup
#define HAL_PCD_DeActiveRemoteWakeup HAL_PCD_DeActivateRemoteWakeup
#define HAL_PCD_SetTxFiFo HAL_PCDEx_SetTxFiFo
#define HAL_PCD_SetRxFiFo HAL_PCDEx_SetRxFiFo
/**
* @}
*/
/** @defgroup HAL_TIM_Aliased_Macros HAL TIM Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_TIM_SetICPrescalerValue TIM_SET_ICPRESCALERVALUE
#define __HAL_TIM_ResetICPrescalerValue TIM_RESET_ICPRESCALERVALUE
#define TIM_GET_ITSTATUS __HAL_TIM_GET_IT_SOURCE
#define TIM_GET_CLEAR_IT __HAL_TIM_CLEAR_IT
#define __HAL_TIM_GET_ITSTATUS __HAL_TIM_GET_IT_SOURCE
#define __HAL_TIM_DIRECTION_STATUS __HAL_TIM_IS_TIM_COUNTING_DOWN
#define __HAL_TIM_PRESCALER __HAL_TIM_SET_PRESCALER
#define __HAL_TIM_SetCounter __HAL_TIM_SET_COUNTER
#define __HAL_TIM_GetCounter __HAL_TIM_GET_COUNTER
#define __HAL_TIM_SetAutoreload __HAL_TIM_SET_AUTORELOAD
#define __HAL_TIM_GetAutoreload __HAL_TIM_GET_AUTORELOAD
#define __HAL_TIM_SetClockDivision __HAL_TIM_SET_CLOCKDIVISION
#define __HAL_TIM_GetClockDivision __HAL_TIM_GET_CLOCKDIVISION
#define __HAL_TIM_SetICPrescaler __HAL_TIM_SET_ICPRESCALER
#define __HAL_TIM_GetICPrescaler __HAL_TIM_GET_ICPRESCALER
#define __HAL_TIM_SetCompare __HAL_TIM_SET_COMPARE
#define __HAL_TIM_GetCompare __HAL_TIM_GET_COMPARE
#define TIM_BREAKINPUTSOURCE_DFSDM TIM_BREAKINPUTSOURCE_DFSDM1
#define TIM_OCMODE_ASSYMETRIC_PWM1 TIM_OCMODE_ASYMMETRIC_PWM1
#define TIM_OCMODE_ASSYMETRIC_PWM2 TIM_OCMODE_ASYMMETRIC_PWM2
/**
* @}
*/
/** @defgroup HAL_ETH_Aliased_Macros HAL ETH Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_ETH_EXTI_ENABLE_IT __HAL_ETH_WAKEUP_EXTI_ENABLE_IT
#define __HAL_ETH_EXTI_DISABLE_IT __HAL_ETH_WAKEUP_EXTI_DISABLE_IT
#define __HAL_ETH_EXTI_GET_FLAG __HAL_ETH_WAKEUP_EXTI_GET_FLAG
#define __HAL_ETH_EXTI_CLEAR_FLAG __HAL_ETH_WAKEUP_EXTI_CLEAR_FLAG
#define __HAL_ETH_EXTI_SET_RISING_EGDE_TRIGGER __HAL_ETH_WAKEUP_EXTI_ENABLE_RISING_EDGE_TRIGGER
#define __HAL_ETH_EXTI_SET_FALLING_EGDE_TRIGGER __HAL_ETH_WAKEUP_EXTI_ENABLE_FALLING_EDGE_TRIGGER
#define __HAL_ETH_EXTI_SET_FALLINGRISING_TRIGGER __HAL_ETH_WAKEUP_EXTI_ENABLE_FALLINGRISING_TRIGGER
#define ETH_PROMISCIOUSMODE_ENABLE ETH_PROMISCUOUS_MODE_ENABLE
#define ETH_PROMISCIOUSMODE_DISABLE ETH_PROMISCUOUS_MODE_DISABLE
#define IS_ETH_PROMISCIOUS_MODE IS_ETH_PROMISCUOUS_MODE
/**
* @}
*/
/** @defgroup HAL_LTDC_Aliased_Macros HAL LTDC Aliased Macros maintained for legacy purpose
* @{
*/
#define __HAL_LTDC_LAYER LTDC_LAYER
#define __HAL_LTDC_RELOAD_CONFIG __HAL_LTDC_RELOAD_IMMEDIATE_CONFIG
/**
* @}
*/
/** @defgroup HAL_SAI_Aliased_Macros HAL SAI Aliased Macros maintained for legacy purpose
* @{
*/
#define SAI_OUTPUTDRIVE_DISABLED SAI_OUTPUTDRIVE_DISABLE
#define SAI_OUTPUTDRIVE_ENABLED SAI_OUTPUTDRIVE_ENABLE
#define SAI_MASTERDIVIDER_ENABLED SAI_MASTERDIVIDER_ENABLE
#define SAI_MASTERDIVIDER_DISABLED SAI_MASTERDIVIDER_DISABLE
#define SAI_STREOMODE SAI_STEREOMODE
#define SAI_FIFOStatus_Empty SAI_FIFOSTATUS_EMPTY
#define SAI_FIFOStatus_Less1QuarterFull SAI_FIFOSTATUS_LESS1QUARTERFULL
#define SAI_FIFOStatus_1QuarterFull SAI_FIFOSTATUS_1QUARTERFULL
#define SAI_FIFOStatus_HalfFull SAI_FIFOSTATUS_HALFFULL
#define SAI_FIFOStatus_3QuartersFull SAI_FIFOSTATUS_3QUARTERFULL
#define SAI_FIFOStatus_Full SAI_FIFOSTATUS_FULL
#define IS_SAI_BLOCK_MONO_STREO_MODE IS_SAI_BLOCK_MONO_STEREO_MODE
#define SAI_SYNCHRONOUS_EXT SAI_SYNCHRONOUS_EXT_SAI1
#define SAI_SYNCEXT_IN_ENABLE SAI_SYNCEXT_OUTBLOCKA_ENABLE
/**
* @}
*/
/** @defgroup HAL_SPDIFRX_Aliased_Macros HAL SPDIFRX Aliased Macros maintained for legacy purpose
* @{
*/
#if defined(STM32H7)
#define HAL_SPDIFRX_ReceiveControlFlow HAL_SPDIFRX_ReceiveCtrlFlow
#define HAL_SPDIFRX_ReceiveControlFlow_IT HAL_SPDIFRX_ReceiveCtrlFlow_IT
#define HAL_SPDIFRX_ReceiveControlFlow_DMA HAL_SPDIFRX_ReceiveCtrlFlow_DMA
#endif
/**
* @}
*/
/** @defgroup HAL_HRTIM_Aliased_Functions HAL HRTIM Aliased Functions maintained for legacy purpose
* @{
*/
#if defined (STM32H7) || defined (STM32G4) || defined (STM32F3)
#define HAL_HRTIM_WaveformCounterStart_IT HAL_HRTIM_WaveformCountStart_IT
#define HAL_HRTIM_WaveformCounterStart_DMA HAL_HRTIM_WaveformCountStart_DMA
#define HAL_HRTIM_WaveformCounterStart HAL_HRTIM_WaveformCountStart
#define HAL_HRTIM_WaveformCounterStop_IT HAL_HRTIM_WaveformCountStop_IT
#define HAL_HRTIM_WaveformCounterStop_DMA HAL_HRTIM_WaveformCountStop_DMA
#define HAL_HRTIM_WaveformCounterStop HAL_HRTIM_WaveformCountStop
#endif
/**
* @}
*/
/** @defgroup HAL_QSPI_Aliased_Macros HAL QSPI Aliased Macros maintained for legacy purpose
* @{
*/
#if defined (STM32L4) || defined (STM32F4) || defined (STM32F7) || defined(STM32H7)
#define HAL_QPSI_TIMEOUT_DEFAULT_VALUE HAL_QSPI_TIMEOUT_DEFAULT_VALUE
#endif /* STM32L4 || STM32F4 || STM32F7 */
/**
* @}
*/
/** @defgroup HAL_Generic_Aliased_Macros HAL Generic Aliased Macros maintained for legacy purpose
* @{
*/
#if defined (STM32F7)
#define ART_ACCLERATOR_ENABLE ART_ACCELERATOR_ENABLE
#endif /* STM32F7 */
/**
* @}
*/
/** @defgroup HAL_PPP_Aliased_Macros HAL PPP Aliased Macros maintained for legacy purpose
* @{
*/
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /* STM32_HAL_LEGACY */
| 213,381 | C | 53.434184 | 206 | 0.659628 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Device/ST/STM32G4xx/Include/system_stm32g4xx.h | /**
******************************************************************************
* @file system_stm32g4xx.h
* @author MCD Application Team
* @brief CMSIS Cortex-M4 Device System Source File for STM32G4xx devices.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/** @addtogroup CMSIS
* @{
*/
/** @addtogroup stm32g4xx_system
* @{
*/
/**
* @brief Define to prevent recursive inclusion
*/
#ifndef __SYSTEM_STM32G4XX_H
#define __SYSTEM_STM32G4XX_H
#ifdef __cplusplus
extern "C" {
#endif
/** @addtogroup STM32G4xx_System_Includes
* @{
*/
/**
* @}
*/
/** @addtogroup STM32G4xx_System_Exported_Variables
* @{
*/
/* The SystemCoreClock variable is updated in three ways:
1) by calling CMSIS function SystemCoreClockUpdate()
2) by calling HAL API function HAL_RCC_GetSysClockFreq()
3) each time HAL_RCC_ClockConfig() is called to configure the system clock frequency
Note: If you use this function to configure the system clock; then there
is no need to call the 2 first functions listed above, since SystemCoreClock
variable is updated automatically.
*/
extern uint32_t SystemCoreClock; /*!< System Clock Frequency (Core Clock) */
extern const uint8_t AHBPrescTable[16]; /*!< AHB prescalers table values */
extern const uint8_t APBPrescTable[8]; /*!< APB prescalers table values */
/**
* @}
*/
/** @addtogroup STM32G4xx_System_Exported_Constants
* @{
*/
/**
* @}
*/
/** @addtogroup STM32G4xx_System_Exported_Macros
* @{
*/
/**
* @}
*/
/** @addtogroup STM32G4xx_System_Exported_Functions
* @{
*/
extern void SystemInit(void);
extern void SystemCoreClockUpdate(void);
/**
* @}
*/
#ifdef __cplusplus
}
#endif
#endif /*__SYSTEM_STM32G4XX_H */
/**
* @}
*/
/**
* @}
*/
| 2,252 | C | 20.457143 | 91 | 0.569716 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Device/ST/STM32G4xx/Include/stm32g431xx.h | /**
******************************************************************************
* @file stm32g431xx.h
* @author MCD Application Team
* @brief CMSIS STM32G431xx Device Peripheral Access Layer Header File.
*
* This file contains:
* - Data structures and the address mapping for all peripherals
* - Peripheral's registers declarations and bits definition
* - Macros to access peripheral's registers hardware
*
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/** @addtogroup CMSIS_Device
* @{
*/
/** @addtogroup stm32g431xx
* @{
*/
#ifndef __STM32G431xx_H
#define __STM32G431xx_H
#ifdef __cplusplus
extern "C" {
#endif /* __cplusplus */
/** @addtogroup Configuration_section_for_CMSIS
* @{
*/
/**
* @brief Configuration of the Cortex-M4 Processor and Core Peripherals
*/
#define __CM4_REV 0x0001U /*!< Cortex-M4 revision r0p1 */
#define __MPU_PRESENT 1U /*!< STM32G4XX provides an MPU */
#define __NVIC_PRIO_BITS 4U /*!< STM32G4XX uses 4 Bits for the Priority Levels */
#define __Vendor_SysTickConfig 0U /*!< Set to 1 if different SysTick Config is used */
#define __FPU_PRESENT 1U /*!< FPU present */
/**
* @}
*/
/** @addtogroup Peripheral_interrupt_number_definition
* @{
*/
/**
* @brief STM32G4XX Interrupt Number Definition, according to the selected device
* in @ref Library_configuration_section
*/
typedef enum
{
/****** Cortex-M4 Processor Exceptions Numbers *********************************************************************************/
NonMaskableInt_IRQn = -14, /*!< 2 Cortex-M4 Non Maskable Interrupt */
HardFault_IRQn = -13, /*!< 3 Cortex-M4 Hard Fault Interrupt */
MemoryManagement_IRQn = -12, /*!< 4 Cortex-M4 Memory Management Interrupt */
BusFault_IRQn = -11, /*!< 5 Cortex-M4 Bus Fault Interrupt */
UsageFault_IRQn = -10, /*!< 6 Cortex-M4 Usage Fault Interrupt */
SVCall_IRQn = -5, /*!< 11 Cortex-M4 SV Call Interrupt */
DebugMonitor_IRQn = -4, /*!< 12 Cortex-M4 Debug Monitor Interrupt */
PendSV_IRQn = -2, /*!< 14 Cortex-M4 Pend SV Interrupt */
SysTick_IRQn = -1, /*!< 15 Cortex-M4 System Tick Interrupt */
/****** STM32 specific Interrupt Numbers ***************************************************************************************/
WWDG_IRQn = 0, /*!< Window WatchDog Interrupt */
PVD_PVM_IRQn = 1, /*!< PVD/PVM1/PVM2/PVM3/PVM4 through EXTI Line detection Interrupts */
RTC_TAMP_LSECSS_IRQn = 2, /*!< RTC Tamper and TimeStamp and RCC LSE CSS interrupts through the EXTI */
RTC_WKUP_IRQn = 3, /*!< RTC Wakeup interrupt through the EXTI line */
FLASH_IRQn = 4, /*!< FLASH global Interrupt */
RCC_IRQn = 5, /*!< RCC global Interrupt */
EXTI0_IRQn = 6, /*!< EXTI Line0 Interrupt */
EXTI1_IRQn = 7, /*!< EXTI Line1 Interrupt */
EXTI2_IRQn = 8, /*!< EXTI Line2 Interrupt */
EXTI3_IRQn = 9, /*!< EXTI Line3 Interrupt */
EXTI4_IRQn = 10, /*!< EXTI Line4 Interrupt */
DMA1_Channel1_IRQn = 11, /*!< DMA1 Channel 1 global Interrupt */
DMA1_Channel2_IRQn = 12, /*!< DMA1 Channel 2 global Interrupt */
DMA1_Channel3_IRQn = 13, /*!< DMA1 Channel 3 global Interrupt */
DMA1_Channel4_IRQn = 14, /*!< DMA1 Channel 4 global Interrupt */
DMA1_Channel5_IRQn = 15, /*!< DMA1 Channel 5 global Interrupt */
DMA1_Channel6_IRQn = 16, /*!< DMA1 Channel 6 global Interrupt */
ADC1_2_IRQn = 18, /*!< ADC1 and ADC2 global Interrupt */
USB_HP_IRQn = 19, /*!< USB HP Interrupt */
USB_LP_IRQn = 20, /*!< USB LP Interrupt */
FDCAN1_IT0_IRQn = 21, /*!< FDCAN1 IT0 Interrupt */
FDCAN1_IT1_IRQn = 22, /*!< FDCAN1 IT1 Interrupt */
EXTI9_5_IRQn = 23, /*!< External Line[9:5] Interrupts */
TIM1_BRK_TIM15_IRQn = 24, /*!< TIM1 Break, Transition error, Index error and TIM15 global interrupt */
TIM1_UP_TIM16_IRQn = 25, /*!< TIM1 Update Interrupt and TIM16 global interrupt */
TIM1_TRG_COM_TIM17_IRQn = 26, /*!< TIM1 TIM1 Trigger, Commutation, Direction change, Index and TIM17 global interrupt */
TIM1_CC_IRQn = 27, /*!< TIM1 Capture Compare Interrupt */
TIM2_IRQn = 28, /*!< TIM2 global Interrupt */
TIM3_IRQn = 29, /*!< TIM3 global Interrupt */
TIM4_IRQn = 30, /*!< TIM4 global Interrupt */
I2C1_EV_IRQn = 31, /*!< I2C1 Event Interrupt */
I2C1_ER_IRQn = 32, /*!< I2C1 Error Interrupt */
I2C2_EV_IRQn = 33, /*!< I2C2 Event Interrupt */
I2C2_ER_IRQn = 34, /*!< I2C2 Error Interrupt */
SPI1_IRQn = 35, /*!< SPI1 global Interrupt */
SPI2_IRQn = 36, /*!< SPI2 global Interrupt */
USART1_IRQn = 37, /*!< USART1 global Interrupt */
USART2_IRQn = 38, /*!< USART2 global Interrupt */
USART3_IRQn = 39, /*!< USART3 global Interrupt */
EXTI15_10_IRQn = 40, /*!< External Line[15:10] Interrupts */
RTC_Alarm_IRQn = 41, /*!< RTC Alarm (A and B) through EXTI Line Interrupt */
USBWakeUp_IRQn = 42, /*!< USB Wakeup through EXTI line Interrupt */
TIM8_BRK_IRQn = 43, /*!< TIM8 Break, Transition error and Index error Interrupt */
TIM8_UP_IRQn = 44, /*!< TIM8 Update Interrupt */
TIM8_TRG_COM_IRQn = 45, /*!< TIM8 Trigger, Commutation, Direction change and Index Interrupt */
TIM8_CC_IRQn = 46, /*!< TIM8 Capture Compare Interrupt */
LPTIM1_IRQn = 49, /*!< LP TIM1 Interrupt */
SPI3_IRQn = 51, /*!< SPI3 global Interrupt */
UART4_IRQn = 52, /*!< UART4 global Interrupt */
TIM6_DAC_IRQn = 54, /*!< TIM6 global and DAC1&3 underrun error interrupts */
TIM7_IRQn = 55, /*!< TIM7 global interrupts */
DMA2_Channel1_IRQn = 56, /*!< DMA2 Channel 1 global Interrupt */
DMA2_Channel2_IRQn = 57, /*!< DMA2 Channel 2 global Interrupt */
DMA2_Channel3_IRQn = 58, /*!< DMA2 Channel 3 global Interrupt */
DMA2_Channel4_IRQn = 59, /*!< DMA2 Channel 4 global Interrupt */
DMA2_Channel5_IRQn = 60, /*!< DMA2 Channel 5 global Interrupt */
UCPD1_IRQn = 63, /*!< UCPD global Interrupt */
COMP1_2_3_IRQn = 64, /*!< COMP1, COMP2 and COMP3 Interrupts */
COMP4_IRQn = 65, /*!< COMP4 */
CRS_IRQn = 75, /*!< CRS global interrupt */
SAI1_IRQn = 76, /*!< Serial Audio Interface global interrupt */
FPU_IRQn = 81, /*!< FPU global interrupt */
RNG_IRQn = 90, /*!< RNG global interrupt */
LPUART1_IRQn = 91, /*!< LP UART 1 Interrupt */
I2C3_EV_IRQn = 92, /*!< I2C3 Event Interrupt */
I2C3_ER_IRQn = 93, /*!< I2C3 Error interrupt */
DMAMUX_OVR_IRQn = 94, /*!< DMAMUX overrun global interrupt */
DMA2_Channel6_IRQn = 97, /*!< DMA2 Channel 6 interrupt */
CORDIC_IRQn = 100, /*!< CORDIC global Interrupt */
FMAC_IRQn = 101 /*!< FMAC global Interrupt */
} IRQn_Type;
/**
* @}
*/
#include "core_cm4.h" /* Cortex-M4 processor and core peripherals */
#include "system_stm32g4xx.h"
#include <stdint.h>
/** @addtogroup Peripheral_registers_structures
* @{
*/
/**
* @brief Analog to Digital Converter
*/
typedef struct
{
__IO uint32_t ISR; /*!< ADC interrupt and status register, Address offset: 0x00 */
__IO uint32_t IER; /*!< ADC interrupt enable register, Address offset: 0x04 */
__IO uint32_t CR; /*!< ADC control register, Address offset: 0x08 */
__IO uint32_t CFGR; /*!< ADC configuration register 1, Address offset: 0x0C */
__IO uint32_t CFGR2; /*!< ADC configuration register 2, Address offset: 0x10 */
__IO uint32_t SMPR1; /*!< ADC sampling time register 1, Address offset: 0x14 */
__IO uint32_t SMPR2; /*!< ADC sampling time register 2, Address offset: 0x18 */
uint32_t RESERVED1; /*!< Reserved, 0x1C */
__IO uint32_t TR1; /*!< ADC analog watchdog 1 threshold register, Address offset: 0x20 */
__IO uint32_t TR2; /*!< ADC analog watchdog 2 threshold register, Address offset: 0x24 */
__IO uint32_t TR3; /*!< ADC analog watchdog 3 threshold register, Address offset: 0x28 */
uint32_t RESERVED2; /*!< Reserved, 0x2C */
__IO uint32_t SQR1; /*!< ADC group regular sequencer register 1, Address offset: 0x30 */
__IO uint32_t SQR2; /*!< ADC group regular sequencer register 2, Address offset: 0x34 */
__IO uint32_t SQR3; /*!< ADC group regular sequencer register 3, Address offset: 0x38 */
__IO uint32_t SQR4; /*!< ADC group regular sequencer register 4, Address offset: 0x3C */
__IO uint32_t DR; /*!< ADC group regular data register, Address offset: 0x40 */
uint32_t RESERVED3; /*!< Reserved, 0x44 */
uint32_t RESERVED4; /*!< Reserved, 0x48 */
__IO uint32_t JSQR; /*!< ADC group injected sequencer register, Address offset: 0x4C */
uint32_t RESERVED5[4]; /*!< Reserved, 0x50 - 0x5C */
__IO uint32_t OFR1; /*!< ADC offset register 1, Address offset: 0x60 */
__IO uint32_t OFR2; /*!< ADC offset register 2, Address offset: 0x64 */
__IO uint32_t OFR3; /*!< ADC offset register 3, Address offset: 0x68 */
__IO uint32_t OFR4; /*!< ADC offset register 4, Address offset: 0x6C */
uint32_t RESERVED6[4]; /*!< Reserved, 0x70 - 0x7C */
__IO uint32_t JDR1; /*!< ADC group injected rank 1 data register, Address offset: 0x80 */
__IO uint32_t JDR2; /*!< ADC group injected rank 2 data register, Address offset: 0x84 */
__IO uint32_t JDR3; /*!< ADC group injected rank 3 data register, Address offset: 0x88 */
__IO uint32_t JDR4; /*!< ADC group injected rank 4 data register, Address offset: 0x8C */
uint32_t RESERVED7[4]; /*!< Reserved, 0x090 - 0x09C */
__IO uint32_t AWD2CR; /*!< ADC analog watchdog 2 configuration register, Address offset: 0xA0 */
__IO uint32_t AWD3CR; /*!< ADC analog watchdog 3 Configuration Register, Address offset: 0xA4 */
uint32_t RESERVED8; /*!< Reserved, 0x0A8 */
uint32_t RESERVED9; /*!< Reserved, 0x0AC */
__IO uint32_t DIFSEL; /*!< ADC differential mode selection register, Address offset: 0xB0 */
__IO uint32_t CALFACT; /*!< ADC calibration factors, Address offset: 0xB4 */
uint32_t RESERVED10[2];/*!< Reserved, 0x0B8 - 0x0BC */
__IO uint32_t GCOMP; /*!< ADC calibration factors, Address offset: 0xC0 */
} ADC_TypeDef;
typedef struct
{
__IO uint32_t CSR; /*!< ADC common status register, Address offset: 0x300 + 0x00 */
uint32_t RESERVED1; /*!< Reserved, Address offset: 0x300 + 0x04 */
__IO uint32_t CCR; /*!< ADC common configuration register, Address offset: 0x300 + 0x08 */
__IO uint32_t CDR; /*!< ADC common group regular data register Address offset: 0x300 + 0x0C */
} ADC_Common_TypeDef;
/**
* @brief FD Controller Area Network
*/
typedef struct
{
__IO uint32_t CREL; /*!< FDCAN Core Release register, Address offset: 0x000 */
__IO uint32_t ENDN; /*!< FDCAN Endian register, Address offset: 0x004 */
uint32_t RESERVED1; /*!< Reserved, 0x008 */
__IO uint32_t DBTP; /*!< FDCAN Data Bit Timing & Prescaler register, Address offset: 0x00C */
__IO uint32_t TEST; /*!< FDCAN Test register, Address offset: 0x010 */
__IO uint32_t RWD; /*!< FDCAN RAM Watchdog register, Address offset: 0x014 */
__IO uint32_t CCCR; /*!< FDCAN CC Control register, Address offset: 0x018 */
__IO uint32_t NBTP; /*!< FDCAN Nominal Bit Timing & Prescaler register, Address offset: 0x01C */
__IO uint32_t TSCC; /*!< FDCAN Timestamp Counter Configuration register, Address offset: 0x020 */
__IO uint32_t TSCV; /*!< FDCAN Timestamp Counter Value register, Address offset: 0x024 */
__IO uint32_t TOCC; /*!< FDCAN Timeout Counter Configuration register, Address offset: 0x028 */
__IO uint32_t TOCV; /*!< FDCAN Timeout Counter Value register, Address offset: 0x02C */
uint32_t RESERVED2[4]; /*!< Reserved, 0x030 - 0x03C */
__IO uint32_t ECR; /*!< FDCAN Error Counter register, Address offset: 0x040 */
__IO uint32_t PSR; /*!< FDCAN Protocol Status register, Address offset: 0x044 */
__IO uint32_t TDCR; /*!< FDCAN Transmitter Delay Compensation register, Address offset: 0x048 */
uint32_t RESERVED3; /*!< Reserved, 0x04C */
__IO uint32_t IR; /*!< FDCAN Interrupt register, Address offset: 0x050 */
__IO uint32_t IE; /*!< FDCAN Interrupt Enable register, Address offset: 0x054 */
__IO uint32_t ILS; /*!< FDCAN Interrupt Line Select register, Address offset: 0x058 */
__IO uint32_t ILE; /*!< FDCAN Interrupt Line Enable register, Address offset: 0x05C */
uint32_t RESERVED4[8]; /*!< Reserved, 0x060 - 0x07C */
__IO uint32_t RXGFC; /*!< FDCAN Global Filter Configuration register, Address offset: 0x080 */
__IO uint32_t XIDAM; /*!< FDCAN Extended ID AND Mask register, Address offset: 0x084 */
__IO uint32_t HPMS; /*!< FDCAN High Priority Message Status register, Address offset: 0x088 */
uint32_t RESERVED5; /*!< Reserved, 0x08C */
__IO uint32_t RXF0S; /*!< FDCAN Rx FIFO 0 Status register, Address offset: 0x090 */
__IO uint32_t RXF0A; /*!< FDCAN Rx FIFO 0 Acknowledge register, Address offset: 0x094 */
__IO uint32_t RXF1S; /*!< FDCAN Rx FIFO 1 Status register, Address offset: 0x098 */
__IO uint32_t RXF1A; /*!< FDCAN Rx FIFO 1 Acknowledge register, Address offset: 0x09C */
uint32_t RESERVED6[8]; /*!< Reserved, 0x0A0 - 0x0BC */
__IO uint32_t TXBC; /*!< FDCAN Tx Buffer Configuration register, Address offset: 0x0C0 */
__IO uint32_t TXFQS; /*!< FDCAN Tx FIFO/Queue Status register, Address offset: 0x0C4 */
__IO uint32_t TXBRP; /*!< FDCAN Tx Buffer Request Pending register, Address offset: 0x0C8 */
__IO uint32_t TXBAR; /*!< FDCAN Tx Buffer Add Request register, Address offset: 0x0CC */
__IO uint32_t TXBCR; /*!< FDCAN Tx Buffer Cancellation Request register, Address offset: 0x0D0 */
__IO uint32_t TXBTO; /*!< FDCAN Tx Buffer Transmission Occurred register, Address offset: 0x0D4 */
__IO uint32_t TXBCF; /*!< FDCAN Tx Buffer Cancellation Finished register, Address offset: 0x0D8 */
__IO uint32_t TXBTIE; /*!< FDCAN Tx Buffer Transmission Interrupt Enable register, Address offset: 0x0DC */
__IO uint32_t TXBCIE; /*!< FDCAN Tx Buffer Cancellation Finished Interrupt Enable register, Address offset: 0x0E0 */
__IO uint32_t TXEFS; /*!< FDCAN Tx Event FIFO Status register, Address offset: 0x0E4 */
__IO uint32_t TXEFA; /*!< FDCAN Tx Event FIFO Acknowledge register, Address offset: 0x0E8 */
} FDCAN_GlobalTypeDef;
/**
* @brief FD Controller Area Network Configuration
*/
typedef struct
{
__IO uint32_t CKDIV; /*!< FDCAN clock divider register, Address offset: 0x100 + 0x000 */
} FDCAN_Config_TypeDef;
/**
* @brief Comparator
*/
typedef struct
{
__IO uint32_t CSR; /*!< COMP control and status register, Address offset: 0x00 */
} COMP_TypeDef;
/**
* @brief CRC calculation unit
*/
typedef struct
{
__IO uint32_t DR; /*!< CRC Data register, Address offset: 0x00 */
__IO uint32_t IDR; /*!< CRC Independent data register, Address offset: 0x04 */
__IO uint32_t CR; /*!< CRC Control register, Address offset: 0x08 */
uint32_t RESERVED0; /*!< Reserved, 0x0C */
__IO uint32_t INIT; /*!< Initial CRC value register, Address offset: 0x10 */
__IO uint32_t POL; /*!< CRC polynomial register, Address offset: 0x14 */
} CRC_TypeDef;
/**
* @brief Clock Recovery System
*/
typedef struct
{
__IO uint32_t CR; /*!< CRS ccontrol register, Address offset: 0x00 */
__IO uint32_t CFGR; /*!< CRS configuration register, Address offset: 0x04 */
__IO uint32_t ISR; /*!< CRS interrupt and status register, Address offset: 0x08 */
__IO uint32_t ICR; /*!< CRS interrupt flag clear register, Address offset: 0x0C */
} CRS_TypeDef;
/**
* @brief Digital to Analog Converter
*/
typedef struct
{
__IO uint32_t CR; /*!< DAC control register, Address offset: 0x00 */
__IO uint32_t SWTRIGR; /*!< DAC software trigger register, Address offset: 0x04 */
__IO uint32_t DHR12R1; /*!< DAC channel1 12-bit right-aligned data holding register, Address offset: 0x08 */
__IO uint32_t DHR12L1; /*!< DAC channel1 12-bit left aligned data holding register, Address offset: 0x0C */
__IO uint32_t DHR8R1; /*!< DAC channel1 8-bit right aligned data holding register, Address offset: 0x10 */
__IO uint32_t DHR12R2; /*!< DAC channel2 12-bit right aligned data holding register, Address offset: 0x14 */
__IO uint32_t DHR12L2; /*!< DAC channel2 12-bit left aligned data holding register, Address offset: 0x18 */
__IO uint32_t DHR8R2; /*!< DAC channel2 8-bit right-aligned data holding register, Address offset: 0x1C */
__IO uint32_t DHR12RD; /*!< Dual DAC 12-bit right-aligned data holding register, Address offset: 0x20 */
__IO uint32_t DHR12LD; /*!< DUAL DAC 12-bit left aligned data holding register, Address offset: 0x24 */
__IO uint32_t DHR8RD; /*!< DUAL DAC 8-bit right aligned data holding register, Address offset: 0x28 */
__IO uint32_t DOR1; /*!< DAC channel1 data output register, Address offset: 0x2C */
__IO uint32_t DOR2; /*!< DAC channel2 data output register, Address offset: 0x30 */
__IO uint32_t SR; /*!< DAC status register, Address offset: 0x34 */
__IO uint32_t CCR; /*!< DAC calibration control register, Address offset: 0x38 */
__IO uint32_t MCR; /*!< DAC mode control register, Address offset: 0x3C */
__IO uint32_t SHSR1; /*!< DAC Sample and Hold sample time register 1, Address offset: 0x40 */
__IO uint32_t SHSR2; /*!< DAC Sample and Hold sample time register 2, Address offset: 0x44 */
__IO uint32_t SHHR; /*!< DAC Sample and Hold hold time register, Address offset: 0x48 */
__IO uint32_t SHRR; /*!< DAC Sample and Hold refresh time register, Address offset: 0x4C */
__IO uint32_t RESERVED[2];
__IO uint32_t STR1; /*!< DAC Sawtooth register, Address offset: 0x58 */
__IO uint32_t STR2; /*!< DAC Sawtooth register, Address offset: 0x5C */
__IO uint32_t STMODR; /*!< DAC Sawtooth Mode register, Address offset: 0x60 */
} DAC_TypeDef;
/**
* @brief Debug MCU
*/
typedef struct
{
__IO uint32_t IDCODE; /*!< MCU device ID code, Address offset: 0x00 */
__IO uint32_t CR; /*!< Debug MCU configuration register, Address offset: 0x04 */
__IO uint32_t APB1FZR1; /*!< Debug MCU APB1 freeze register 1, Address offset: 0x08 */
__IO uint32_t APB1FZR2; /*!< Debug MCU APB1 freeze register 2, Address offset: 0x0C */
__IO uint32_t APB2FZ; /*!< Debug MCU APB2 freeze register, Address offset: 0x10 */
} DBGMCU_TypeDef;
/**
* @brief DMA Controller
*/
typedef struct
{
__IO uint32_t CCR; /*!< DMA channel x configuration register */
__IO uint32_t CNDTR; /*!< DMA channel x number of data register */
__IO uint32_t CPAR; /*!< DMA channel x peripheral address register */
__IO uint32_t CMAR; /*!< DMA channel x memory address register */
} DMA_Channel_TypeDef;
typedef struct
{
__IO uint32_t ISR; /*!< DMA interrupt status register, Address offset: 0x00 */
__IO uint32_t IFCR; /*!< DMA interrupt flag clear register, Address offset: 0x04 */
} DMA_TypeDef;
/**
* @brief DMA Multiplexer
*/
typedef struct
{
__IO uint32_t CCR; /*!< DMA Multiplexer Channel x Control Register Address offset: 0x0004 * (channel x) */
}DMAMUX_Channel_TypeDef;
typedef struct
{
__IO uint32_t CSR; /*!< DMA Channel Status Register Address offset: 0x0080 */
__IO uint32_t CFR; /*!< DMA Channel Clear Flag Register Address offset: 0x0084 */
}DMAMUX_ChannelStatus_TypeDef;
typedef struct
{
__IO uint32_t RGCR; /*!< DMA Request Generator x Control Register Address offset: 0x0100 + 0x0004 * (Req Gen x) */
}DMAMUX_RequestGen_TypeDef;
typedef struct
{
__IO uint32_t RGSR; /*!< DMA Request Generator Status Register Address offset: 0x0140 */
__IO uint32_t RGCFR; /*!< DMA Request Generator Clear Flag Register Address offset: 0x0144 */
}DMAMUX_RequestGenStatus_TypeDef;
/**
* @brief External Interrupt/Event Controller
*/
typedef struct
{
__IO uint32_t IMR1; /*!< EXTI Interrupt mask register 1, Address offset: 0x00 */
__IO uint32_t EMR1; /*!< EXTI Event mask register 1, Address offset: 0x04 */
__IO uint32_t RTSR1; /*!< EXTI Rising trigger selection register 1, Address offset: 0x08 */
__IO uint32_t FTSR1; /*!< EXTI Falling trigger selection register 1, Address offset: 0x0C */
__IO uint32_t SWIER1; /*!< EXTI Software interrupt event register 1, Address offset: 0x10 */
__IO uint32_t PR1; /*!< EXTI Pending register 1, Address offset: 0x14 */
uint32_t RESERVED1; /*!< Reserved, 0x18 */
uint32_t RESERVED2; /*!< Reserved, 0x1C */
__IO uint32_t IMR2; /*!< EXTI Interrupt mask register 2, Address offset: 0x20 */
__IO uint32_t EMR2; /*!< EXTI Event mask register 2, Address offset: 0x24 */
__IO uint32_t RTSR2; /*!< EXTI Rising trigger selection register 2, Address offset: 0x28 */
__IO uint32_t FTSR2; /*!< EXTI Falling trigger selection register 2, Address offset: 0x2C */
__IO uint32_t SWIER2; /*!< EXTI Software interrupt event register 2, Address offset: 0x30 */
__IO uint32_t PR2; /*!< EXTI Pending register 2, Address offset: 0x34 */
} EXTI_TypeDef;
/**
* @brief FLASH Registers
*/
typedef struct
{
__IO uint32_t ACR; /*!< FLASH access control register, Address offset: 0x00 */
__IO uint32_t PDKEYR; /*!< FLASH power down key register, Address offset: 0x04 */
__IO uint32_t KEYR; /*!< FLASH key register, Address offset: 0x08 */
__IO uint32_t OPTKEYR; /*!< FLASH option key register, Address offset: 0x0C */
__IO uint32_t SR; /*!< FLASH status register, Address offset: 0x10 */
__IO uint32_t CR; /*!< FLASH control register, Address offset: 0x14 */
__IO uint32_t ECCR; /*!< FLASH ECC register, Address offset: 0x18 */
uint32_t RESERVED1; /*!< Reserved1, Address offset: 0x1C */
__IO uint32_t OPTR; /*!< FLASH option register, Address offset: 0x20 */
__IO uint32_t PCROP1SR; /*!< FLASH bank1 PCROP start address register, Address offset: 0x24 */
__IO uint32_t PCROP1ER; /*!< FLASH bank1 PCROP end address register, Address offset: 0x28 */
__IO uint32_t WRP1AR; /*!< FLASH bank1 WRP area A address register, Address offset: 0x2C */
__IO uint32_t WRP1BR; /*!< FLASH bank1 WRP area B address register, Address offset: 0x30 */
uint32_t RESERVED2[15]; /*!< Reserved2, Address offset: 0x34 */
__IO uint32_t SEC1R; /*!< FLASH Securable memory register bank1, Address offset: 0x70 */
} FLASH_TypeDef;
/**
* @brief FMAC
*/
typedef struct
{
__IO uint32_t X1BUFCFG; /*!< FMAC X1 Buffer Configuration register, Address offset: 0x00 */
__IO uint32_t X2BUFCFG; /*!< FMAC X2 Buffer Configuration register, Address offset: 0x04 */
__IO uint32_t YBUFCFG; /*!< FMAC Y Buffer Configuration register, Address offset: 0x08 */
__IO uint32_t PARAM; /*!< FMAC Parameter register, Address offset: 0x0C */
__IO uint32_t CR; /*!< FMAC Control register, Address offset: 0x10 */
__IO uint32_t SR; /*!< FMAC Status register, Address offset: 0x14 */
__IO uint32_t WDATA; /*!< FMAC Write Data register, Address offset: 0x18 */
__IO uint32_t RDATA; /*!< FMAC Read Data register, Address offset: 0x1C */
} FMAC_TypeDef;
/**
* @brief General Purpose I/O
*/
typedef struct
{
__IO uint32_t MODER; /*!< GPIO port mode register, Address offset: 0x00 */
__IO uint32_t OTYPER; /*!< GPIO port output type register, Address offset: 0x04 */
__IO uint32_t OSPEEDR; /*!< GPIO port output speed register, Address offset: 0x08 */
__IO uint32_t PUPDR; /*!< GPIO port pull-up/pull-down register, Address offset: 0x0C */
__IO uint32_t IDR; /*!< GPIO port input data register, Address offset: 0x10 */
__IO uint32_t ODR; /*!< GPIO port output data register, Address offset: 0x14 */
__IO uint32_t BSRR; /*!< GPIO port bit set/reset register, Address offset: 0x18 */
__IO uint32_t LCKR; /*!< GPIO port configuration lock register, Address offset: 0x1C */
__IO uint32_t AFR[2]; /*!< GPIO alternate function registers, Address offset: 0x20-0x24 */
__IO uint32_t BRR; /*!< GPIO Bit Reset register, Address offset: 0x28 */
} GPIO_TypeDef;
/**
* @brief Inter-integrated Circuit Interface
*/
typedef struct
{
__IO uint32_t CR1; /*!< I2C Control register 1, Address offset: 0x00 */
__IO uint32_t CR2; /*!< I2C Control register 2, Address offset: 0x04 */
__IO uint32_t OAR1; /*!< I2C Own address 1 register, Address offset: 0x08 */
__IO uint32_t OAR2; /*!< I2C Own address 2 register, Address offset: 0x0C */
__IO uint32_t TIMINGR; /*!< I2C Timing register, Address offset: 0x10 */
__IO uint32_t TIMEOUTR; /*!< I2C Timeout register, Address offset: 0x14 */
__IO uint32_t ISR; /*!< I2C Interrupt and status register, Address offset: 0x18 */
__IO uint32_t ICR; /*!< I2C Interrupt clear register, Address offset: 0x1C */
__IO uint32_t PECR; /*!< I2C PEC register, Address offset: 0x20 */
__IO uint32_t RXDR; /*!< I2C Receive data register, Address offset: 0x24 */
__IO uint32_t TXDR; /*!< I2C Transmit data register, Address offset: 0x28 */
} I2C_TypeDef;
/**
* @brief Independent WATCHDOG
*/
typedef struct
{
__IO uint32_t KR; /*!< IWDG Key register, Address offset: 0x00 */
__IO uint32_t PR; /*!< IWDG Prescaler register, Address offset: 0x04 */
__IO uint32_t RLR; /*!< IWDG Reload register, Address offset: 0x08 */
__IO uint32_t SR; /*!< IWDG Status register, Address offset: 0x0C */
__IO uint32_t WINR; /*!< IWDG Window register, Address offset: 0x10 */
} IWDG_TypeDef;
/**
* @brief LPTIMER
*/
typedef struct
{
__IO uint32_t ISR; /*!< LPTIM Interrupt and Status register, Address offset: 0x00 */
__IO uint32_t ICR; /*!< LPTIM Interrupt Clear register, Address offset: 0x04 */
__IO uint32_t IER; /*!< LPTIM Interrupt Enable register, Address offset: 0x08 */
__IO uint32_t CFGR; /*!< LPTIM Configuration register, Address offset: 0x0C */
__IO uint32_t CR; /*!< LPTIM Control register, Address offset: 0x10 */
__IO uint32_t CMP; /*!< LPTIM Compare register, Address offset: 0x14 */
__IO uint32_t ARR; /*!< LPTIM Autoreload register, Address offset: 0x18 */
__IO uint32_t CNT; /*!< LPTIM Counter register, Address offset: 0x1C */
__IO uint32_t OR; /*!< LPTIM Option register, Address offset: 0x20 */
} LPTIM_TypeDef;
/**
* @brief Operational Amplifier (OPAMP)
*/
typedef struct
{
__IO uint32_t CSR; /*!< OPAMP control/status register, Address offset: 0x00 */
__IO uint32_t RESERVED[5]; /*!< OPAMP offset trimming register for normal mode, Address offset: 0x04 */
__IO uint32_t TCMR; /*!< OPAMP timer controlled mux mode register, Address offset: 0x18 */
} OPAMP_TypeDef;
/**
* @brief Power Control
*/
typedef struct
{
__IO uint32_t CR1; /*!< PWR power control register 1, Address offset: 0x00 */
__IO uint32_t CR2; /*!< PWR power control register 2, Address offset: 0x04 */
__IO uint32_t CR3; /*!< PWR power control register 3, Address offset: 0x08 */
__IO uint32_t CR4; /*!< PWR power control register 4, Address offset: 0x0C */
__IO uint32_t SR1; /*!< PWR power status register 1, Address offset: 0x10 */
__IO uint32_t SR2; /*!< PWR power status register 2, Address offset: 0x14 */
__IO uint32_t SCR; /*!< PWR power status reset register, Address offset: 0x18 */
uint32_t RESERVED; /*!< Reserved, Address offset: 0x1C */
__IO uint32_t PUCRA; /*!< Pull_up control register of portA, Address offset: 0x20 */
__IO uint32_t PDCRA; /*!< Pull_Down control register of portA, Address offset: 0x24 */
__IO uint32_t PUCRB; /*!< Pull_up control register of portB, Address offset: 0x28 */
__IO uint32_t PDCRB; /*!< Pull_Down control register of portB, Address offset: 0x2C */
__IO uint32_t PUCRC; /*!< Pull_up control register of portC, Address offset: 0x30 */
__IO uint32_t PDCRC; /*!< Pull_Down control register of portC, Address offset: 0x34 */
__IO uint32_t PUCRD; /*!< Pull_up control register of portD, Address offset: 0x38 */
__IO uint32_t PDCRD; /*!< Pull_Down control register of portD, Address offset: 0x3C */
__IO uint32_t PUCRE; /*!< Pull_up control register of portE, Address offset: 0x40 */
__IO uint32_t PDCRE; /*!< Pull_Down control register of portE, Address offset: 0x44 */
__IO uint32_t PUCRF; /*!< Pull_up control register of portF, Address offset: 0x48 */
__IO uint32_t PDCRF; /*!< Pull_Down control register of portF, Address offset: 0x4C */
__IO uint32_t PUCRG; /*!< Pull_up control register of portG, Address offset: 0x50 */
__IO uint32_t PDCRG; /*!< Pull_Down control register of portG, Address offset: 0x54 */
uint32_t RESERVED1[10]; /*!< Reserved Address offset: 0x58 - 0x7C */
__IO uint32_t CR5; /*!< PWR power control register 5, Address offset: 0x80 */
} PWR_TypeDef;
/**
* @brief Reset and Clock Control
*/
typedef struct
{
__IO uint32_t CR; /*!< RCC clock control register, Address offset: 0x00 */
__IO uint32_t ICSCR; /*!< RCC internal clock sources calibration register, Address offset: 0x04 */
__IO uint32_t CFGR; /*!< RCC clock configuration register, Address offset: 0x08 */
__IO uint32_t PLLCFGR; /*!< RCC system PLL configuration register, Address offset: 0x0C */
uint32_t RESERVED0; /*!< Reserved, Address offset: 0x10 */
uint32_t RESERVED1; /*!< Reserved, Address offset: 0x14 */
__IO uint32_t CIER; /*!< RCC clock interrupt enable register, Address offset: 0x18 */
__IO uint32_t CIFR; /*!< RCC clock interrupt flag register, Address offset: 0x1C */
__IO uint32_t CICR; /*!< RCC clock interrupt clear register, Address offset: 0x20 */
uint32_t RESERVED2; /*!< Reserved, Address offset: 0x24 */
__IO uint32_t AHB1RSTR; /*!< RCC AHB1 peripheral reset register, Address offset: 0x28 */
__IO uint32_t AHB2RSTR; /*!< RCC AHB2 peripheral reset register, Address offset: 0x2C */
__IO uint32_t AHB3RSTR; /*!< RCC AHB3 peripheral reset register, Address offset: 0x30 */
uint32_t RESERVED3; /*!< Reserved, Address offset: 0x34 */
__IO uint32_t APB1RSTR1; /*!< RCC APB1 peripheral reset register 1, Address offset: 0x38 */
__IO uint32_t APB1RSTR2; /*!< RCC APB1 peripheral reset register 2, Address offset: 0x3C */
__IO uint32_t APB2RSTR; /*!< RCC APB2 peripheral reset register, Address offset: 0x40 */
uint32_t RESERVED4; /*!< Reserved, Address offset: 0x44 */
__IO uint32_t AHB1ENR; /*!< RCC AHB1 peripheral clocks enable register, Address offset: 0x48 */
__IO uint32_t AHB2ENR; /*!< RCC AHB2 peripheral clocks enable register, Address offset: 0x4C */
__IO uint32_t AHB3ENR; /*!< RCC AHB3 peripheral clocks enable register, Address offset: 0x50 */
uint32_t RESERVED5; /*!< Reserved, Address offset: 0x54 */
__IO uint32_t APB1ENR1; /*!< RCC APB1 peripheral clocks enable register 1, Address offset: 0x58 */
__IO uint32_t APB1ENR2; /*!< RCC APB1 peripheral clocks enable register 2, Address offset: 0x5C */
__IO uint32_t APB2ENR; /*!< RCC APB2 peripheral clocks enable register, Address offset: 0x60 */
uint32_t RESERVED6; /*!< Reserved, Address offset: 0x64 */
__IO uint32_t AHB1SMENR; /*!< RCC AHB1 peripheral clocks enable in sleep and stop modes register, Address offset: 0x68 */
__IO uint32_t AHB2SMENR; /*!< RCC AHB2 peripheral clocks enable in sleep and stop modes register, Address offset: 0x6C */
__IO uint32_t AHB3SMENR; /*!< RCC AHB3 peripheral clocks enable in sleep and stop modes register, Address offset: 0x70 */
uint32_t RESERVED7; /*!< Reserved, Address offset: 0x74 */
__IO uint32_t APB1SMENR1; /*!< RCC APB1 peripheral clocks enable in sleep mode and stop modes register 1, Address offset: 0x78 */
__IO uint32_t APB1SMENR2; /*!< RCC APB1 peripheral clocks enable in sleep mode and stop modes register 2, Address offset: 0x7C */
__IO uint32_t APB2SMENR; /*!< RCC APB2 peripheral clocks enable in sleep mode and stop modes register, Address offset: 0x80 */
uint32_t RESERVED8; /*!< Reserved, Address offset: 0x84 */
__IO uint32_t CCIPR; /*!< RCC peripherals independent clock configuration register, Address offset: 0x88 */
uint32_t RESERVED9; /*!< Reserved, Address offset: 0x8C */
__IO uint32_t BDCR; /*!< RCC backup domain control register, Address offset: 0x90 */
__IO uint32_t CSR; /*!< RCC clock control & status register, Address offset: 0x94 */
__IO uint32_t CRRCR; /*!< RCC clock recovery RC register, Address offset: 0x98 */
__IO uint32_t CCIPR2; /*!< RCC peripherals independent clock configuration register 2, Address offset: 0x9C */
} RCC_TypeDef;
/**
* @brief Real-Time Clock
*/
/*
* @brief Specific device feature definitions
*/
#define RTC_TAMP_INT_6_SUPPORT
#define RTC_TAMP_INT_NB 4u
#define RTC_TAMP_NB 3u
#define RTC_BACKUP_NB 16u
typedef struct
{
__IO uint32_t TR; /*!< RTC time register, Address offset: 0x00 */
__IO uint32_t DR; /*!< RTC date register, Address offset: 0x04 */
__IO uint32_t SSR; /*!< RTC sub second register, Address offset: 0x08 */
__IO uint32_t ICSR; /*!< RTC initialization control and status register, Address offset: 0x0C */
__IO uint32_t PRER; /*!< RTC prescaler register, Address offset: 0x10 */
__IO uint32_t WUTR; /*!< RTC wakeup timer register, Address offset: 0x14 */
__IO uint32_t CR; /*!< RTC control register, Address offset: 0x18 */
uint32_t RESERVED0; /*!< Reserved Address offset: 0x1C */
uint32_t RESERVED1; /*!< Reserved Address offset: 0x20 */
__IO uint32_t WPR; /*!< RTC write protection register, Address offset: 0x24 */
__IO uint32_t CALR; /*!< RTC calibration register, Address offset: 0x28 */
__IO uint32_t SHIFTR; /*!< RTC shift control register, Address offset: 0x2C */
__IO uint32_t TSTR; /*!< RTC time stamp time register, Address offset: 0x30 */
__IO uint32_t TSDR; /*!< RTC time stamp date register, Address offset: 0x34 */
__IO uint32_t TSSSR; /*!< RTC time-stamp sub second register, Address offset: 0x38 */
uint32_t RESERVED2; /*!< Reserved Address offset: 0x3C */
__IO uint32_t ALRMAR; /*!< RTC alarm A register, Address offset: 0x40 */
__IO uint32_t ALRMASSR; /*!< RTC alarm A sub second register, Address offset: 0x44 */
__IO uint32_t ALRMBR; /*!< RTC alarm B register, Address offset: 0x48 */
__IO uint32_t ALRMBSSR; /*!< RTC alarm B sub second register, Address offset: 0x4C */
__IO uint32_t SR; /*!< RTC Status register, Address offset: 0x50 */
__IO uint32_t MISR; /*!< RTC Masked Interrupt Status register, Address offset: 0x54 */
uint32_t RESERVED3; /*!< Reserved Address offset: 0x58 */
__IO uint32_t SCR; /*!< RTC Status Clear register, Address offset: 0x5C */
} RTC_TypeDef;
/**
* @brief Tamper and backup registers
*/
typedef struct
{
__IO uint32_t CR1; /*!< TAMP configuration register 1, Address offset: 0x00 */
__IO uint32_t CR2; /*!< TAMP configuration register 2, Address offset: 0x04 */
uint32_t RESERVED0; /*!< no configuration register 3, Address offset: 0x08 */
__IO uint32_t FLTCR; /*!< TAMP filter control register, Address offset: 0x0C */
uint32_t RESERVED1[6]; /*!< Reserved Address offset: 0x10 - 0x24 */
uint32_t RESERVED2; /*!< Reserved Address offset: 0x28 */
__IO uint32_t IER; /*!< TAMP Interrupt enable register, Address offset: 0x2C */
__IO uint32_t SR; /*!< TAMP Status register, Address offset: 0x30 */
__IO uint32_t MISR; /*!< TAMP Masked Interrupt Status register Address offset: 0x34 */
uint32_t RESERVED3; /*!< Reserved Address offset: 0x38 */
__IO uint32_t SCR; /*!< TAMP Status clear register, Address offset: 0x3C */
uint32_t RESERVED4[48]; /*!< Reserved Address offset: 0x040 - 0xFC */
__IO uint32_t BKP0R; /*!< TAMP backup register 0, Address offset: 0x100 */
__IO uint32_t BKP1R; /*!< TAMP backup register 1, Address offset: 0x104 */
__IO uint32_t BKP2R; /*!< TAMP backup register 2, Address offset: 0x108 */
__IO uint32_t BKP3R; /*!< TAMP backup register 3, Address offset: 0x10C */
__IO uint32_t BKP4R; /*!< TAMP backup register 4, Address offset: 0x110 */
__IO uint32_t BKP5R; /*!< TAMP backup register 5, Address offset: 0x114 */
__IO uint32_t BKP6R; /*!< TAMP backup register 6, Address offset: 0x118 */
__IO uint32_t BKP7R; /*!< TAMP backup register 7, Address offset: 0x11C */
__IO uint32_t BKP8R; /*!< TAMP backup register 8, Address offset: 0x120 */
__IO uint32_t BKP9R; /*!< TAMP backup register 9, Address offset: 0x124 */
__IO uint32_t BKP10R; /*!< TAMP backup register 10, Address offset: 0x128 */
__IO uint32_t BKP11R; /*!< TAMP backup register 11, Address offset: 0x12C */
__IO uint32_t BKP12R; /*!< TAMP backup register 12, Address offset: 0x130 */
__IO uint32_t BKP13R; /*!< TAMP backup register 13, Address offset: 0x134 */
__IO uint32_t BKP14R; /*!< TAMP backup register 14, Address offset: 0x138 */
__IO uint32_t BKP15R; /*!< TAMP backup register 15, Address offset: 0x13C */
} TAMP_TypeDef;
/**
* @brief Serial Audio Interface
*/
typedef struct
{
uint32_t RESERVED[17]; /*!< Reserved, Address offset: 0x00 to 0x40 */
__IO uint32_t PDMCR; /*!< SAI PDM control register, Address offset: 0x44 */
__IO uint32_t PDMDLY; /*!< SAI PDM delay register, Address offset: 0x48 */
} SAI_TypeDef;
typedef struct
{
__IO uint32_t CR1; /*!< SAI block x configuration register 1, Address offset: 0x04 */
__IO uint32_t CR2; /*!< SAI block x configuration register 2, Address offset: 0x08 */
__IO uint32_t FRCR; /*!< SAI block x frame configuration register, Address offset: 0x0C */
__IO uint32_t SLOTR; /*!< SAI block x slot register, Address offset: 0x10 */
__IO uint32_t IMR; /*!< SAI block x interrupt mask register, Address offset: 0x14 */
__IO uint32_t SR; /*!< SAI block x status register, Address offset: 0x18 */
__IO uint32_t CLRFR; /*!< SAI block x clear flag register, Address offset: 0x1C */
__IO uint32_t DR; /*!< SAI block x data register, Address offset: 0x20 */
} SAI_Block_TypeDef;
/**
* @brief Serial Peripheral Interface
*/
typedef struct
{
__IO uint32_t CR1; /*!< SPI Control register 1, Address offset: 0x00 */
__IO uint32_t CR2; /*!< SPI Control register 2, Address offset: 0x04 */
__IO uint32_t SR; /*!< SPI Status register, Address offset: 0x08 */
__IO uint32_t DR; /*!< SPI data register, Address offset: 0x0C */
__IO uint32_t CRCPR; /*!< SPI CRC polynomial register, Address offset: 0x10 */
__IO uint32_t RXCRCR; /*!< SPI Rx CRC register, Address offset: 0x14 */
__IO uint32_t TXCRCR; /*!< SPI Tx CRC register, Address offset: 0x18 */
__IO uint32_t I2SCFGR; /*!< SPI_I2S configuration register, Address offset: 0x1C */
__IO uint32_t I2SPR; /*!< SPI_I2S prescaler register, Address offset: 0x20 */
} SPI_TypeDef;
/**
* @brief System configuration controller
*/
typedef struct
{
__IO uint32_t MEMRMP; /*!< SYSCFG memory remap register, Address offset: 0x00 */
__IO uint32_t CFGR1; /*!< SYSCFG configuration register 1, Address offset: 0x04 */
__IO uint32_t EXTICR[4]; /*!< SYSCFG external interrupt configuration registers, Address offset: 0x08-0x14 */
__IO uint32_t SCSR; /*!< SYSCFG CCMSRAM control and status register, Address offset: 0x18 */
__IO uint32_t CFGR2; /*!< SYSCFG configuration register 2, Address offset: 0x1C */
__IO uint32_t SWPR; /*!< SYSCFG CCMSRAM write protection register, Address offset: 0x20 */
__IO uint32_t SKR; /*!< SYSCFG CCMSRAM Key Register, Address offset: 0x24 */
} SYSCFG_TypeDef;
/**
* @brief TIM
*/
typedef struct
{
__IO uint32_t CR1; /*!< TIM control register 1, Address offset: 0x00 */
__IO uint32_t CR2; /*!< TIM control register 2, Address offset: 0x04 */
__IO uint32_t SMCR; /*!< TIM slave mode control register, Address offset: 0x08 */
__IO uint32_t DIER; /*!< TIM DMA/interrupt enable register, Address offset: 0x0C */
__IO uint32_t SR; /*!< TIM status register, Address offset: 0x10 */
__IO uint32_t EGR; /*!< TIM event generation register, Address offset: 0x14 */
__IO uint32_t CCMR1; /*!< TIM capture/compare mode register 1, Address offset: 0x18 */
__IO uint32_t CCMR2; /*!< TIM capture/compare mode register 2, Address offset: 0x1C */
__IO uint32_t CCER; /*!< TIM capture/compare enable register, Address offset: 0x20 */
__IO uint32_t CNT; /*!< TIM counter register, Address offset: 0x24 */
__IO uint32_t PSC; /*!< TIM prescaler, Address offset: 0x28 */
__IO uint32_t ARR; /*!< TIM auto-reload register, Address offset: 0x2C */
__IO uint32_t RCR; /*!< TIM repetition counter register, Address offset: 0x30 */
__IO uint32_t CCR1; /*!< TIM capture/compare register 1, Address offset: 0x34 */
__IO uint32_t CCR2; /*!< TIM capture/compare register 2, Address offset: 0x38 */
__IO uint32_t CCR3; /*!< TIM capture/compare register 3, Address offset: 0x3C */
__IO uint32_t CCR4; /*!< TIM capture/compare register 4, Address offset: 0x40 */
__IO uint32_t BDTR; /*!< TIM break and dead-time register, Address offset: 0x44 */
__IO uint32_t CCR5; /*!< TIM capture/compare register 5, Address offset: 0x48 */
__IO uint32_t CCR6; /*!< TIM capture/compare register 6, Address offset: 0x4C */
__IO uint32_t CCMR3; /*!< TIM capture/compare mode register 3, Address offset: 0x50 */
__IO uint32_t DTR2; /*!< TIM deadtime register 2, Address offset: 0x54 */
__IO uint32_t ECR; /*!< TIM encoder control register, Address offset: 0x58 */
__IO uint32_t TISEL; /*!< TIM Input Selection register, Address offset: 0x5C */
__IO uint32_t AF1; /*!< TIM alternate function option register 1, Address offset: 0x60 */
__IO uint32_t AF2; /*!< TIM alternate function option register 2, Address offset: 0x64 */
__IO uint32_t OR ; /*!< TIM option register, Address offset: 0x68 */
uint32_t RESERVED0[220];/*!< Reserved, Address offset: 0x6C */
__IO uint32_t DCR; /*!< TIM DMA control register, Address offset: 0x3DC */
__IO uint32_t DMAR; /*!< TIM DMA address for full transfer, Address offset: 0x3E0 */
} TIM_TypeDef;
/**
* @brief Universal Synchronous Asynchronous Receiver Transmitter
*/
typedef struct
{
__IO uint32_t CR1; /*!< USART Control register 1, Address offset: 0x00 */
__IO uint32_t CR2; /*!< USART Control register 2, Address offset: 0x04 */
__IO uint32_t CR3; /*!< USART Control register 3, Address offset: 0x08 */
__IO uint32_t BRR; /*!< USART Baud rate register, Address offset: 0x0C */
__IO uint32_t GTPR; /*!< USART Guard time and prescaler register, Address offset: 0x10 */
__IO uint32_t RTOR; /*!< USART Receiver Timeout register, Address offset: 0x14 */
__IO uint32_t RQR; /*!< USART Request register, Address offset: 0x18 */
__IO uint32_t ISR; /*!< USART Interrupt and status register, Address offset: 0x1C */
__IO uint32_t ICR; /*!< USART Interrupt flag Clear register, Address offset: 0x20 */
__IO uint32_t RDR; /*!< USART Receive Data register, Address offset: 0x24 */
__IO uint32_t TDR; /*!< USART Transmit Data register, Address offset: 0x28 */
__IO uint32_t PRESC; /*!< USART Prescaler register, Address offset: 0x2C */
} USART_TypeDef;
/**
* @brief Universal Serial Bus Full Speed Device
*/
typedef struct
{
__IO uint16_t EP0R; /*!< USB Endpoint 0 register, Address offset: 0x00 */
__IO uint16_t RESERVED0; /*!< Reserved */
__IO uint16_t EP1R; /*!< USB Endpoint 1 register, Address offset: 0x04 */
__IO uint16_t RESERVED1; /*!< Reserved */
__IO uint16_t EP2R; /*!< USB Endpoint 2 register, Address offset: 0x08 */
__IO uint16_t RESERVED2; /*!< Reserved */
__IO uint16_t EP3R; /*!< USB Endpoint 3 register, Address offset: 0x0C */
__IO uint16_t RESERVED3; /*!< Reserved */
__IO uint16_t EP4R; /*!< USB Endpoint 4 register, Address offset: 0x10 */
__IO uint16_t RESERVED4; /*!< Reserved */
__IO uint16_t EP5R; /*!< USB Endpoint 5 register, Address offset: 0x14 */
__IO uint16_t RESERVED5; /*!< Reserved */
__IO uint16_t EP6R; /*!< USB Endpoint 6 register, Address offset: 0x18 */
__IO uint16_t RESERVED6; /*!< Reserved */
__IO uint16_t EP7R; /*!< USB Endpoint 7 register, Address offset: 0x1C */
__IO uint16_t RESERVED7[17]; /*!< Reserved */
__IO uint16_t CNTR; /*!< Control register, Address offset: 0x40 */
__IO uint16_t RESERVED8; /*!< Reserved */
__IO uint16_t ISTR; /*!< Interrupt status register, Address offset: 0x44 */
__IO uint16_t RESERVED9; /*!< Reserved */
__IO uint16_t FNR; /*!< Frame number register, Address offset: 0x48 */
__IO uint16_t RESERVEDA; /*!< Reserved */
__IO uint16_t DADDR; /*!< Device address register, Address offset: 0x4C */
__IO uint16_t RESERVEDB; /*!< Reserved */
__IO uint16_t BTABLE; /*!< Buffer Table address register, Address offset: 0x50 */
__IO uint16_t RESERVEDC; /*!< Reserved */
__IO uint16_t LPMCSR; /*!< LPM Control and Status register, Address offset: 0x54 */
__IO uint16_t RESERVEDD; /*!< Reserved */
__IO uint16_t BCDR; /*!< Battery Charging detector register, Address offset: 0x58 */
__IO uint16_t RESERVEDE; /*!< Reserved */
} USB_TypeDef;
/**
* @brief VREFBUF
*/
typedef struct
{
__IO uint32_t CSR; /*!< VREFBUF control and status register, Address offset: 0x00 */
__IO uint32_t CCR; /*!< VREFBUF calibration and control register, Address offset: 0x04 */
} VREFBUF_TypeDef;
/**
* @brief Window WATCHDOG
*/
typedef struct
{
__IO uint32_t CR; /*!< WWDG Control register, Address offset: 0x00 */
__IO uint32_t CFR; /*!< WWDG Configuration register, Address offset: 0x04 */
__IO uint32_t SR; /*!< WWDG Status register, Address offset: 0x08 */
} WWDG_TypeDef;
/**
* @brief RNG
*/
typedef struct
{
__IO uint32_t CR; /*!< RNG control register, Address offset: 0x00 */
__IO uint32_t SR; /*!< RNG status register, Address offset: 0x04 */
__IO uint32_t DR; /*!< RNG data register, Address offset: 0x08 */
} RNG_TypeDef;
/**
* @brief CORDIC
*/
typedef struct
{
__IO uint32_t CSR; /*!< CORDIC control and status register, Address offset: 0x00 */
__IO uint32_t WDATA; /*!< CORDIC argument register, Address offset: 0x04 */
__IO uint32_t RDATA; /*!< CORDIC result register, Address offset: 0x08 */
} CORDIC_TypeDef;
/**
* @brief UCPD
*/
typedef struct
{
__IO uint32_t CFG1; /*!< UCPD configuration register 1, Address offset: 0x00 */
__IO uint32_t CFG2; /*!< UCPD configuration register 2, Address offset: 0x04 */
__IO uint32_t RESERVED0; /*!< UCPD reserved register, Address offset: 0x08 */
__IO uint32_t CR; /*!< UCPD control register, Address offset: 0x0C */
__IO uint32_t IMR; /*!< UCPD interrupt mask register, Address offset: 0x10 */
__IO uint32_t SR; /*!< UCPD status register, Address offset: 0x14 */
__IO uint32_t ICR; /*!< UCPD interrupt flag clear register Address offset: 0x18 */
__IO uint32_t TX_ORDSET; /*!< UCPD Tx ordered set type register, Address offset: 0x1C */
__IO uint32_t TX_PAYSZ; /*!< UCPD Tx payload size register, Address offset: 0x20 */
__IO uint32_t TXDR; /*!< UCPD Tx data register, Address offset: 0x24 */
__IO uint32_t RX_ORDSET; /*!< UCPD Rx ordered set type register, Address offset: 0x28 */
__IO uint32_t RX_PAYSZ; /*!< UCPD Rx payload size register, Address offset: 0x2C */
__IO uint32_t RXDR; /*!< UCPD Rx data register, Address offset: 0x30 */
__IO uint32_t RX_ORDEXT1; /*!< UCPD Rx ordered set extension 1 register, Address offset: 0x34 */
__IO uint32_t RX_ORDEXT2; /*!< UCPD Rx ordered set extension 2 register, Address offset: 0x38 */
} UCPD_TypeDef;
/**
* @}
*/
/** @addtogroup Peripheral_memory_map
* @{
*/
#define FLASH_BASE (0x08000000UL) /*!< FLASH (up to 128 kB) base address */
#define SRAM1_BASE (0x20000000UL) /*!< SRAM1(up to 16 KB) base address */
#define SRAM2_BASE (0x20004000UL) /*!< SRAM2(6 KB) base address */
#define CCMSRAM_BASE (0x10000000UL) /*!< CCMSRAM(10 KB) base address */
#define PERIPH_BASE (0x40000000UL) /*!< Peripheral base address */
#define SRAM1_BB_BASE (0x22000000UL) /*!< SRAM1(16 KB) base address in the bit-band region */
#define SRAM2_BB_BASE (0x22080000UL) /*!< SRAM2(6 KB) base address in the bit-band region */
#define CCMSRAM_BB_BASE (0x220B0000UL) /*!< CCMSRAM(10 KB) base address in the bit-band region */
#define PERIPH_BB_BASE (0x42000000UL) /*!< Peripheral base address in the bit-band region */
/* Legacy defines */
#define SRAM_BASE SRAM1_BASE
#define SRAM_BB_BASE SRAM1_BB_BASE
#define SRAM1_SIZE_MAX (0x00004000UL) /*!< maximum SRAM1 size (up to 16 KBytes) */
#define SRAM2_SIZE (0x00001800UL) /*!< SRAM2 size (6 KBytes) */
#define CCMSRAM_SIZE (0x00002800UL) /*!< CCMSRAM size (10 KBytes) */
/*!< Peripheral memory map */
#define APB1PERIPH_BASE PERIPH_BASE
#define APB2PERIPH_BASE (PERIPH_BASE + 0x00010000UL)
#define AHB1PERIPH_BASE (PERIPH_BASE + 0x00020000UL)
#define AHB2PERIPH_BASE (PERIPH_BASE + 0x08000000UL)
/*!< APB1 peripherals */
#define TIM2_BASE (APB1PERIPH_BASE + 0x0000UL)
#define TIM3_BASE (APB1PERIPH_BASE + 0x0400UL)
#define TIM4_BASE (APB1PERIPH_BASE + 0x0800UL)
#define TIM6_BASE (APB1PERIPH_BASE + 0x1000UL)
#define TIM7_BASE (APB1PERIPH_BASE + 0x1400UL)
#define CRS_BASE (APB1PERIPH_BASE + 0x2000UL)
#define TAMP_BASE (APB1PERIPH_BASE + 0x2400UL)
#define RTC_BASE (APB1PERIPH_BASE + 0x2800UL)
#define WWDG_BASE (APB1PERIPH_BASE + 0x2C00UL)
#define IWDG_BASE (APB1PERIPH_BASE + 0x3000UL)
#define SPI2_BASE (APB1PERIPH_BASE + 0x3800UL)
#define SPI3_BASE (APB1PERIPH_BASE + 0x3C00UL)
#define USART2_BASE (APB1PERIPH_BASE + 0x4400UL)
#define USART3_BASE (APB1PERIPH_BASE + 0x4800UL)
#define UART4_BASE (APB1PERIPH_BASE + 0x4C00UL)
#define I2C1_BASE (APB1PERIPH_BASE + 0x5400UL)
#define I2C2_BASE (APB1PERIPH_BASE + 0x5800UL)
#define USB_BASE (APB1PERIPH_BASE + 0x5C00UL) /*!< USB_IP Peripheral Registers base address */
#define USB_PMAADDR (APB1PERIPH_BASE + 0x6000UL) /*!< USB_IP Packet Memory Area base address */
#define FDCAN1_BASE (APB1PERIPH_BASE + 0x6400UL)
#define FDCAN_CONFIG_BASE (APB1PERIPH_BASE + 0x6500UL) /*!< FDCAN configuration registers base address */
#define PWR_BASE (APB1PERIPH_BASE + 0x7000UL)
#define I2C3_BASE (APB1PERIPH_BASE + 0x7800UL)
#define LPTIM1_BASE (APB1PERIPH_BASE + 0x7C00UL)
#define LPUART1_BASE (APB1PERIPH_BASE + 0x8000UL)
#define UCPD1_BASE (APB1PERIPH_BASE + 0xA000UL)
#define SRAMCAN_BASE (APB1PERIPH_BASE + 0xA400UL)
/*!< APB2 peripherals */
#define SYSCFG_BASE (APB2PERIPH_BASE + 0x0000UL)
#define VREFBUF_BASE (APB2PERIPH_BASE + 0x0030UL)
#define COMP1_BASE (APB2PERIPH_BASE + 0x0200UL)
#define COMP2_BASE (APB2PERIPH_BASE + 0x0204UL)
#define COMP3_BASE (APB2PERIPH_BASE + 0x0208UL)
#define COMP4_BASE (APB2PERIPH_BASE + 0x020CUL)
#define OPAMP_BASE (APB2PERIPH_BASE + 0x0300UL)
#define OPAMP1_BASE (APB2PERIPH_BASE + 0x0300UL)
#define OPAMP2_BASE (APB2PERIPH_BASE + 0x0304UL)
#define OPAMP3_BASE (APB2PERIPH_BASE + 0x0308UL)
#define EXTI_BASE (APB2PERIPH_BASE + 0x0400UL)
#define TIM1_BASE (APB2PERIPH_BASE + 0x2C00UL)
#define SPI1_BASE (APB2PERIPH_BASE + 0x3000UL)
#define TIM8_BASE (APB2PERIPH_BASE + 0x3400UL)
#define USART1_BASE (APB2PERIPH_BASE + 0x3800UL)
#define TIM15_BASE (APB2PERIPH_BASE + 0x4000UL)
#define TIM16_BASE (APB2PERIPH_BASE + 0x4400UL)
#define TIM17_BASE (APB2PERIPH_BASE + 0x4800UL)
#define SAI1_BASE (APB2PERIPH_BASE + 0x5400UL)
#define SAI1_Block_A_BASE (SAI1_BASE + 0x0004UL)
#define SAI1_Block_B_BASE (SAI1_BASE + 0x0024UL)
/*!< AHB1 peripherals */
#define DMA1_BASE (AHB1PERIPH_BASE)
#define DMA2_BASE (AHB1PERIPH_BASE + 0x0400UL)
#define DMAMUX1_BASE (AHB1PERIPH_BASE + 0x0800UL)
#define CORDIC_BASE (AHB1PERIPH_BASE + 0x0C00UL)
#define RCC_BASE (AHB1PERIPH_BASE + 0x1000UL)
#define FMAC_BASE (AHB1PERIPH_BASE + 0x1400UL)
#define FLASH_R_BASE (AHB1PERIPH_BASE + 0x2000UL)
#define CRC_BASE (AHB1PERIPH_BASE + 0x3000UL)
#define DMA1_Channel1_BASE (DMA1_BASE + 0x0008UL)
#define DMA1_Channel2_BASE (DMA1_BASE + 0x001CUL)
#define DMA1_Channel3_BASE (DMA1_BASE + 0x0030UL)
#define DMA1_Channel4_BASE (DMA1_BASE + 0x0044UL)
#define DMA1_Channel5_BASE (DMA1_BASE + 0x0058UL)
#define DMA1_Channel6_BASE (DMA1_BASE + 0x006CUL)
#define DMA2_Channel1_BASE (DMA2_BASE + 0x0008UL)
#define DMA2_Channel2_BASE (DMA2_BASE + 0x001CUL)
#define DMA2_Channel3_BASE (DMA2_BASE + 0x0030UL)
#define DMA2_Channel4_BASE (DMA2_BASE + 0x0044UL)
#define DMA2_Channel5_BASE (DMA2_BASE + 0x0058UL)
#define DMA2_Channel6_BASE (DMA2_BASE + 0x006CUL)
#define DMAMUX1_Channel0_BASE (DMAMUX1_BASE)
#define DMAMUX1_Channel1_BASE (DMAMUX1_BASE + 0x0004UL)
#define DMAMUX1_Channel2_BASE (DMAMUX1_BASE + 0x0008UL)
#define DMAMUX1_Channel3_BASE (DMAMUX1_BASE + 0x000CUL)
#define DMAMUX1_Channel4_BASE (DMAMUX1_BASE + 0x0010UL)
#define DMAMUX1_Channel5_BASE (DMAMUX1_BASE + 0x0014UL)
#define DMAMUX1_Channel6_BASE (DMAMUX1_BASE + 0x0020UL)
#define DMAMUX1_Channel7_BASE (DMAMUX1_BASE + 0x0024UL)
#define DMAMUX1_Channel8_BASE (DMAMUX1_BASE + 0x0028UL)
#define DMAMUX1_Channel9_BASE (DMAMUX1_BASE + 0x002CUL)
#define DMAMUX1_Channel10_BASE (DMAMUX1_BASE + 0x0030UL)
#define DMAMUX1_Channel11_BASE (DMAMUX1_BASE + 0x0034UL)
#define DMAMUX1_RequestGenerator0_BASE (DMAMUX1_BASE + 0x0100UL)
#define DMAMUX1_RequestGenerator1_BASE (DMAMUX1_BASE + 0x0104UL)
#define DMAMUX1_RequestGenerator2_BASE (DMAMUX1_BASE + 0x0108UL)
#define DMAMUX1_RequestGenerator3_BASE (DMAMUX1_BASE + 0x010CUL)
#define DMAMUX1_ChannelStatus_BASE (DMAMUX1_BASE + 0x0080UL)
#define DMAMUX1_RequestGenStatus_BASE (DMAMUX1_BASE + 0x0140UL)
/*!< AHB2 peripherals */
#define GPIOA_BASE (AHB2PERIPH_BASE + 0x0000UL)
#define GPIOB_BASE (AHB2PERIPH_BASE + 0x0400UL)
#define GPIOC_BASE (AHB2PERIPH_BASE + 0x0800UL)
#define GPIOD_BASE (AHB2PERIPH_BASE + 0x0C00UL)
#define GPIOE_BASE (AHB2PERIPH_BASE + 0x1000UL)
#define GPIOF_BASE (AHB2PERIPH_BASE + 0x1400UL)
#define GPIOG_BASE (AHB2PERIPH_BASE + 0x1800UL)
#define ADC1_BASE (AHB2PERIPH_BASE + 0x08000000UL)
#define ADC2_BASE (AHB2PERIPH_BASE + 0x08000100UL)
#define ADC12_COMMON_BASE (AHB2PERIPH_BASE + 0x08000300UL)
#define DAC_BASE (AHB2PERIPH_BASE + 0x08000800UL)
#define DAC1_BASE (AHB2PERIPH_BASE + 0x08000800UL)
#define DAC3_BASE (AHB2PERIPH_BASE + 0x08001000UL)
#define RNG_BASE (AHB2PERIPH_BASE + 0x08060800UL)
/* Debug MCU registers base address */
#define DBGMCU_BASE (0xE0042000UL)
#define PACKAGE_BASE (0x1FFF7500UL) /*!< Package data register base address */
#define UID_BASE (0x1FFF7590UL) /*!< Unique device ID register base address */
#define FLASHSIZE_BASE (0x1FFF75E0UL) /*!< Flash size data register base address */
/**
* @}
*/
/** @addtogroup Peripheral_declaration
* @{
*/
#define TIM2 ((TIM_TypeDef *) TIM2_BASE)
#define TIM3 ((TIM_TypeDef *) TIM3_BASE)
#define TIM4 ((TIM_TypeDef *) TIM4_BASE)
#define TIM6 ((TIM_TypeDef *) TIM6_BASE)
#define TIM7 ((TIM_TypeDef *) TIM7_BASE)
#define CRS ((CRS_TypeDef *) CRS_BASE)
#define TAMP ((TAMP_TypeDef *) TAMP_BASE)
#define RTC ((RTC_TypeDef *) RTC_BASE)
#define WWDG ((WWDG_TypeDef *) WWDG_BASE)
#define IWDG ((IWDG_TypeDef *) IWDG_BASE)
#define SPI2 ((SPI_TypeDef *) SPI2_BASE)
#define SPI3 ((SPI_TypeDef *) SPI3_BASE)
#define USART2 ((USART_TypeDef *) USART2_BASE)
#define USART3 ((USART_TypeDef *) USART3_BASE)
#define UART4 ((USART_TypeDef *) UART4_BASE)
#define I2C1 ((I2C_TypeDef *) I2C1_BASE)
#define I2C2 ((I2C_TypeDef *) I2C2_BASE)
#define USB ((USB_TypeDef *) USB_BASE)
#define FDCAN1 ((FDCAN_GlobalTypeDef *) FDCAN1_BASE)
#define FDCAN_CONFIG ((FDCAN_Config_TypeDef *) FDCAN_CONFIG_BASE)
#define PWR ((PWR_TypeDef *) PWR_BASE)
#define I2C3 ((I2C_TypeDef *) I2C3_BASE)
#define LPTIM1 ((LPTIM_TypeDef *) LPTIM1_BASE)
#define LPUART1 ((USART_TypeDef *) LPUART1_BASE)
#define UCPD1 ((UCPD_TypeDef *) UCPD1_BASE)
#define SYSCFG ((SYSCFG_TypeDef *) SYSCFG_BASE)
#define VREFBUF ((VREFBUF_TypeDef *) VREFBUF_BASE)
#define COMP1 ((COMP_TypeDef *) COMP1_BASE)
#define COMP2 ((COMP_TypeDef *) COMP2_BASE)
#define COMP3 ((COMP_TypeDef *) COMP3_BASE)
#define COMP4 ((COMP_TypeDef *) COMP4_BASE)
#define OPAMP ((OPAMP_TypeDef *) OPAMP_BASE)
#define OPAMP1 ((OPAMP_TypeDef *) OPAMP1_BASE)
#define OPAMP2 ((OPAMP_TypeDef *) OPAMP2_BASE)
#define OPAMP3 ((OPAMP_TypeDef *) OPAMP3_BASE)
#define EXTI ((EXTI_TypeDef *) EXTI_BASE)
#define TIM1 ((TIM_TypeDef *) TIM1_BASE)
#define SPI1 ((SPI_TypeDef *) SPI1_BASE)
#define TIM8 ((TIM_TypeDef *) TIM8_BASE)
#define USART1 ((USART_TypeDef *) USART1_BASE)
#define TIM15 ((TIM_TypeDef *) TIM15_BASE)
#define TIM16 ((TIM_TypeDef *) TIM16_BASE)
#define TIM17 ((TIM_TypeDef *) TIM17_BASE)
#define SAI1 ((SAI_TypeDef *) SAI1_BASE)
#define SAI1_Block_A ((SAI_Block_TypeDef *)SAI1_Block_A_BASE)
#define SAI1_Block_B ((SAI_Block_TypeDef *)SAI1_Block_B_BASE)
#define DMA1 ((DMA_TypeDef *) DMA1_BASE)
#define DMA2 ((DMA_TypeDef *) DMA2_BASE)
#define DMAMUX1 ((DMAMUX_Channel_TypeDef *) DMAMUX1_BASE)
#define CORDIC ((CORDIC_TypeDef *) CORDIC_BASE)
#define RCC ((RCC_TypeDef *) RCC_BASE)
#define FMAC ((FMAC_TypeDef *) FMAC_BASE)
#define FLASH ((FLASH_TypeDef *) FLASH_R_BASE)
#define CRC ((CRC_TypeDef *) CRC_BASE)
#define GPIOA ((GPIO_TypeDef *) GPIOA_BASE)
#define GPIOB ((GPIO_TypeDef *) GPIOB_BASE)
#define GPIOC ((GPIO_TypeDef *) GPIOC_BASE)
#define GPIOD ((GPIO_TypeDef *) GPIOD_BASE)
#define GPIOE ((GPIO_TypeDef *) GPIOE_BASE)
#define GPIOF ((GPIO_TypeDef *) GPIOF_BASE)
#define GPIOG ((GPIO_TypeDef *) GPIOG_BASE)
#define ADC1 ((ADC_TypeDef *) ADC1_BASE)
#define ADC2 ((ADC_TypeDef *) ADC2_BASE)
#define ADC12_COMMON ((ADC_Common_TypeDef *) ADC12_COMMON_BASE)
#define DAC ((DAC_TypeDef *) DAC_BASE)
#define DAC1 ((DAC_TypeDef *) DAC1_BASE)
#define DAC3 ((DAC_TypeDef *) DAC3_BASE)
#define RNG ((RNG_TypeDef *) RNG_BASE)
#define DMA1_Channel1 ((DMA_Channel_TypeDef *) DMA1_Channel1_BASE)
#define DMA1_Channel2 ((DMA_Channel_TypeDef *) DMA1_Channel2_BASE)
#define DMA1_Channel3 ((DMA_Channel_TypeDef *) DMA1_Channel3_BASE)
#define DMA1_Channel4 ((DMA_Channel_TypeDef *) DMA1_Channel4_BASE)
#define DMA1_Channel5 ((DMA_Channel_TypeDef *) DMA1_Channel5_BASE)
#define DMA1_Channel6 ((DMA_Channel_TypeDef *) DMA1_Channel6_BASE)
#define DMA2_Channel1 ((DMA_Channel_TypeDef *) DMA2_Channel1_BASE)
#define DMA2_Channel2 ((DMA_Channel_TypeDef *) DMA2_Channel2_BASE)
#define DMA2_Channel3 ((DMA_Channel_TypeDef *) DMA2_Channel3_BASE)
#define DMA2_Channel4 ((DMA_Channel_TypeDef *) DMA2_Channel4_BASE)
#define DMA2_Channel5 ((DMA_Channel_TypeDef *) DMA2_Channel5_BASE)
#define DMA2_Channel6 ((DMA_Channel_TypeDef *) DMA2_Channel6_BASE)
#define DMAMUX1_Channel0 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel0_BASE)
#define DMAMUX1_Channel1 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel1_BASE)
#define DMAMUX1_Channel2 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel2_BASE)
#define DMAMUX1_Channel3 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel3_BASE)
#define DMAMUX1_Channel4 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel4_BASE)
#define DMAMUX1_Channel5 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel5_BASE)
#define DMAMUX1_Channel6 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel6_BASE)
#define DMAMUX1_Channel7 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel7_BASE)
#define DMAMUX1_Channel8 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel8_BASE)
#define DMAMUX1_Channel9 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel9_BASE)
#define DMAMUX1_Channel10 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel10_BASE)
#define DMAMUX1_Channel11 ((DMAMUX_Channel_TypeDef *) DMAMUX1_Channel11_BASE)
#define DMAMUX1_RequestGenerator0 ((DMAMUX_RequestGen_TypeDef *) DMAMUX1_RequestGenerator0_BASE)
#define DMAMUX1_RequestGenerator1 ((DMAMUX_RequestGen_TypeDef *) DMAMUX1_RequestGenerator1_BASE)
#define DMAMUX1_RequestGenerator2 ((DMAMUX_RequestGen_TypeDef *) DMAMUX1_RequestGenerator2_BASE)
#define DMAMUX1_RequestGenerator3 ((DMAMUX_RequestGen_TypeDef *) DMAMUX1_RequestGenerator3_BASE)
#define DMAMUX1_ChannelStatus ((DMAMUX_ChannelStatus_TypeDef *) DMAMUX1_ChannelStatus_BASE)
#define DMAMUX1_RequestGenStatus ((DMAMUX_RequestGenStatus_TypeDef *) DMAMUX1_RequestGenStatus_BASE)
#define DBGMCU ((DBGMCU_TypeDef *) DBGMCU_BASE)
/**
* @}
*/
/** @addtogroup Exported_constants
* @{
*/
/** @addtogroup Hardware_Constant_Definition
* @{
*/
#define LSI_STARTUP_TIME 130U /*!< LSI Maximum startup time in us */
/**
* @}
*/
/** @addtogroup Peripheral_Registers_Bits_Definition
* @{
*/
/******************************************************************************/
/* Peripheral Registers_Bits_Definition */
/******************************************************************************/
/******************************************************************************/
/* */
/* Analog to Digital Converter */
/* */
/******************************************************************************/
/*
* @brief Specific device feature definitions (not present on all devices in the STM32G4 series)
*/
#define ADC_MULTIMODE_SUPPORT /*!< ADC feature available only on specific devices: multimode available on devices with several ADC instances */
/******************** Bit definition for ADC_ISR register *******************/
#define ADC_ISR_ADRDY_Pos (0U)
#define ADC_ISR_ADRDY_Msk (0x1UL << ADC_ISR_ADRDY_Pos) /*!< 0x00000001 */
#define ADC_ISR_ADRDY ADC_ISR_ADRDY_Msk /*!< ADC ready flag */
#define ADC_ISR_EOSMP_Pos (1U)
#define ADC_ISR_EOSMP_Msk (0x1UL << ADC_ISR_EOSMP_Pos) /*!< 0x00000002 */
#define ADC_ISR_EOSMP ADC_ISR_EOSMP_Msk /*!< ADC group regular end of sampling flag */
#define ADC_ISR_EOC_Pos (2U)
#define ADC_ISR_EOC_Msk (0x1UL << ADC_ISR_EOC_Pos) /*!< 0x00000004 */
#define ADC_ISR_EOC ADC_ISR_EOC_Msk /*!< ADC group regular end of unitary conversion flag */
#define ADC_ISR_EOS_Pos (3U)
#define ADC_ISR_EOS_Msk (0x1UL << ADC_ISR_EOS_Pos) /*!< 0x00000008 */
#define ADC_ISR_EOS ADC_ISR_EOS_Msk /*!< ADC group regular end of sequence conversions flag */
#define ADC_ISR_OVR_Pos (4U)
#define ADC_ISR_OVR_Msk (0x1UL << ADC_ISR_OVR_Pos) /*!< 0x00000010 */
#define ADC_ISR_OVR ADC_ISR_OVR_Msk /*!< ADC group regular overrun flag */
#define ADC_ISR_JEOC_Pos (5U)
#define ADC_ISR_JEOC_Msk (0x1UL << ADC_ISR_JEOC_Pos) /*!< 0x00000020 */
#define ADC_ISR_JEOC ADC_ISR_JEOC_Msk /*!< ADC group injected end of unitary conversion flag */
#define ADC_ISR_JEOS_Pos (6U)
#define ADC_ISR_JEOS_Msk (0x1UL << ADC_ISR_JEOS_Pos) /*!< 0x00000040 */
#define ADC_ISR_JEOS ADC_ISR_JEOS_Msk /*!< ADC group injected end of sequence conversions flag */
#define ADC_ISR_AWD1_Pos (7U)
#define ADC_ISR_AWD1_Msk (0x1UL << ADC_ISR_AWD1_Pos) /*!< 0x00000080 */
#define ADC_ISR_AWD1 ADC_ISR_AWD1_Msk /*!< ADC analog watchdog 1 flag */
#define ADC_ISR_AWD2_Pos (8U)
#define ADC_ISR_AWD2_Msk (0x1UL << ADC_ISR_AWD2_Pos) /*!< 0x00000100 */
#define ADC_ISR_AWD2 ADC_ISR_AWD2_Msk /*!< ADC analog watchdog 2 flag */
#define ADC_ISR_AWD3_Pos (9U)
#define ADC_ISR_AWD3_Msk (0x1UL << ADC_ISR_AWD3_Pos) /*!< 0x00000200 */
#define ADC_ISR_AWD3 ADC_ISR_AWD3_Msk /*!< ADC analog watchdog 3 flag */
#define ADC_ISR_JQOVF_Pos (10U)
#define ADC_ISR_JQOVF_Msk (0x1UL << ADC_ISR_JQOVF_Pos) /*!< 0x00000400 */
#define ADC_ISR_JQOVF ADC_ISR_JQOVF_Msk /*!< ADC group injected contexts queue overflow flag */
/******************** Bit definition for ADC_IER register *******************/
#define ADC_IER_ADRDYIE_Pos (0U)
#define ADC_IER_ADRDYIE_Msk (0x1UL << ADC_IER_ADRDYIE_Pos) /*!< 0x00000001 */
#define ADC_IER_ADRDYIE ADC_IER_ADRDYIE_Msk /*!< ADC ready interrupt */
#define ADC_IER_EOSMPIE_Pos (1U)
#define ADC_IER_EOSMPIE_Msk (0x1UL << ADC_IER_EOSMPIE_Pos) /*!< 0x00000002 */
#define ADC_IER_EOSMPIE ADC_IER_EOSMPIE_Msk /*!< ADC group regular end of sampling interrupt */
#define ADC_IER_EOCIE_Pos (2U)
#define ADC_IER_EOCIE_Msk (0x1UL << ADC_IER_EOCIE_Pos) /*!< 0x00000004 */
#define ADC_IER_EOCIE ADC_IER_EOCIE_Msk /*!< ADC group regular end of unitary conversion interrupt */
#define ADC_IER_EOSIE_Pos (3U)
#define ADC_IER_EOSIE_Msk (0x1UL << ADC_IER_EOSIE_Pos) /*!< 0x00000008 */
#define ADC_IER_EOSIE ADC_IER_EOSIE_Msk /*!< ADC group regular end of sequence conversions interrupt */
#define ADC_IER_OVRIE_Pos (4U)
#define ADC_IER_OVRIE_Msk (0x1UL << ADC_IER_OVRIE_Pos) /*!< 0x00000010 */
#define ADC_IER_OVRIE ADC_IER_OVRIE_Msk /*!< ADC group regular overrun interrupt */
#define ADC_IER_JEOCIE_Pos (5U)
#define ADC_IER_JEOCIE_Msk (0x1UL << ADC_IER_JEOCIE_Pos) /*!< 0x00000020 */
#define ADC_IER_JEOCIE ADC_IER_JEOCIE_Msk /*!< ADC group injected end of unitary conversion interrupt */
#define ADC_IER_JEOSIE_Pos (6U)
#define ADC_IER_JEOSIE_Msk (0x1UL << ADC_IER_JEOSIE_Pos) /*!< 0x00000040 */
#define ADC_IER_JEOSIE ADC_IER_JEOSIE_Msk /*!< ADC group injected end of sequence conversions interrupt */
#define ADC_IER_AWD1IE_Pos (7U)
#define ADC_IER_AWD1IE_Msk (0x1UL << ADC_IER_AWD1IE_Pos) /*!< 0x00000080 */
#define ADC_IER_AWD1IE ADC_IER_AWD1IE_Msk /*!< ADC analog watchdog 1 interrupt */
#define ADC_IER_AWD2IE_Pos (8U)
#define ADC_IER_AWD2IE_Msk (0x1UL << ADC_IER_AWD2IE_Pos) /*!< 0x00000100 */
#define ADC_IER_AWD2IE ADC_IER_AWD2IE_Msk /*!< ADC analog watchdog 2 interrupt */
#define ADC_IER_AWD3IE_Pos (9U)
#define ADC_IER_AWD3IE_Msk (0x1UL << ADC_IER_AWD3IE_Pos) /*!< 0x00000200 */
#define ADC_IER_AWD3IE ADC_IER_AWD3IE_Msk /*!< ADC analog watchdog 3 interrupt */
#define ADC_IER_JQOVFIE_Pos (10U)
#define ADC_IER_JQOVFIE_Msk (0x1UL << ADC_IER_JQOVFIE_Pos) /*!< 0x00000400 */
#define ADC_IER_JQOVFIE ADC_IER_JQOVFIE_Msk /*!< ADC group injected contexts queue overflow interrupt */
/******************** Bit definition for ADC_CR register ********************/
#define ADC_CR_ADEN_Pos (0U)
#define ADC_CR_ADEN_Msk (0x1UL << ADC_CR_ADEN_Pos) /*!< 0x00000001 */
#define ADC_CR_ADEN ADC_CR_ADEN_Msk /*!< ADC enable */
#define ADC_CR_ADDIS_Pos (1U)
#define ADC_CR_ADDIS_Msk (0x1UL << ADC_CR_ADDIS_Pos) /*!< 0x00000002 */
#define ADC_CR_ADDIS ADC_CR_ADDIS_Msk /*!< ADC disable */
#define ADC_CR_ADSTART_Pos (2U)
#define ADC_CR_ADSTART_Msk (0x1UL << ADC_CR_ADSTART_Pos) /*!< 0x00000004 */
#define ADC_CR_ADSTART ADC_CR_ADSTART_Msk /*!< ADC group regular conversion start */
#define ADC_CR_JADSTART_Pos (3U)
#define ADC_CR_JADSTART_Msk (0x1UL << ADC_CR_JADSTART_Pos) /*!< 0x00000008 */
#define ADC_CR_JADSTART ADC_CR_JADSTART_Msk /*!< ADC group injected conversion start */
#define ADC_CR_ADSTP_Pos (4U)
#define ADC_CR_ADSTP_Msk (0x1UL << ADC_CR_ADSTP_Pos) /*!< 0x00000010 */
#define ADC_CR_ADSTP ADC_CR_ADSTP_Msk /*!< ADC group regular conversion stop */
#define ADC_CR_JADSTP_Pos (5U)
#define ADC_CR_JADSTP_Msk (0x1UL << ADC_CR_JADSTP_Pos) /*!< 0x00000020 */
#define ADC_CR_JADSTP ADC_CR_JADSTP_Msk /*!< ADC group injected conversion stop */
#define ADC_CR_ADVREGEN_Pos (28U)
#define ADC_CR_ADVREGEN_Msk (0x1UL << ADC_CR_ADVREGEN_Pos) /*!< 0x10000000 */
#define ADC_CR_ADVREGEN ADC_CR_ADVREGEN_Msk /*!< ADC voltage regulator enable */
#define ADC_CR_DEEPPWD_Pos (29U)
#define ADC_CR_DEEPPWD_Msk (0x1UL << ADC_CR_DEEPPWD_Pos) /*!< 0x20000000 */
#define ADC_CR_DEEPPWD ADC_CR_DEEPPWD_Msk /*!< ADC deep power down enable */
#define ADC_CR_ADCALDIF_Pos (30U)
#define ADC_CR_ADCALDIF_Msk (0x1UL << ADC_CR_ADCALDIF_Pos) /*!< 0x40000000 */
#define ADC_CR_ADCALDIF ADC_CR_ADCALDIF_Msk /*!< ADC differential mode for calibration */
#define ADC_CR_ADCAL_Pos (31U)
#define ADC_CR_ADCAL_Msk (0x1UL << ADC_CR_ADCAL_Pos) /*!< 0x80000000 */
#define ADC_CR_ADCAL ADC_CR_ADCAL_Msk /*!< ADC calibration */
/******************** Bit definition for ADC_CFGR register ******************/
#define ADC_CFGR_DMAEN_Pos (0U)
#define ADC_CFGR_DMAEN_Msk (0x1UL << ADC_CFGR_DMAEN_Pos) /*!< 0x00000001 */
#define ADC_CFGR_DMAEN ADC_CFGR_DMAEN_Msk /*!< ADC DMA transfer enable */
#define ADC_CFGR_DMACFG_Pos (1U)
#define ADC_CFGR_DMACFG_Msk (0x1UL << ADC_CFGR_DMACFG_Pos) /*!< 0x00000002 */
#define ADC_CFGR_DMACFG ADC_CFGR_DMACFG_Msk /*!< ADC DMA transfer configuration */
#define ADC_CFGR_RES_Pos (3U)
#define ADC_CFGR_RES_Msk (0x3UL << ADC_CFGR_RES_Pos) /*!< 0x00000018 */
#define ADC_CFGR_RES ADC_CFGR_RES_Msk /*!< ADC data resolution */
#define ADC_CFGR_RES_0 (0x1UL << ADC_CFGR_RES_Pos) /*!< 0x00000008 */
#define ADC_CFGR_RES_1 (0x2UL << ADC_CFGR_RES_Pos) /*!< 0x00000010 */
#define ADC_CFGR_EXTSEL_Pos (5U)
#define ADC_CFGR_EXTSEL_Msk (0x1FUL << ADC_CFGR_EXTSEL_Pos) /*!< 0x000003E0 */
#define ADC_CFGR_EXTSEL ADC_CFGR_EXTSEL_Msk /*!< ADC group regular external trigger source */
#define ADC_CFGR_EXTSEL_0 (0x1UL << ADC_CFGR_EXTSEL_Pos) /*!< 0x00000020 */
#define ADC_CFGR_EXTSEL_1 (0x2UL << ADC_CFGR_EXTSEL_Pos) /*!< 0x00000040 */
#define ADC_CFGR_EXTSEL_2 (0x4UL << ADC_CFGR_EXTSEL_Pos) /*!< 0x00000080 */
#define ADC_CFGR_EXTSEL_3 (0x8UL << ADC_CFGR_EXTSEL_Pos) /*!< 0x00000100 */
#define ADC_CFGR_EXTSEL_4 (0x10UL << ADC_CFGR_EXTSEL_Pos) /*!< 0x00000200 */
#define ADC_CFGR_EXTEN_Pos (10U)
#define ADC_CFGR_EXTEN_Msk (0x3UL << ADC_CFGR_EXTEN_Pos) /*!< 0x00000C00 */
#define ADC_CFGR_EXTEN ADC_CFGR_EXTEN_Msk /*!< ADC group regular external trigger polarity */
#define ADC_CFGR_EXTEN_0 (0x1UL << ADC_CFGR_EXTEN_Pos) /*!< 0x00000400 */
#define ADC_CFGR_EXTEN_1 (0x2UL << ADC_CFGR_EXTEN_Pos) /*!< 0x00000800 */
#define ADC_CFGR_OVRMOD_Pos (12U)
#define ADC_CFGR_OVRMOD_Msk (0x1UL << ADC_CFGR_OVRMOD_Pos) /*!< 0x00001000 */
#define ADC_CFGR_OVRMOD ADC_CFGR_OVRMOD_Msk /*!< ADC group regular overrun configuration */
#define ADC_CFGR_CONT_Pos (13U)
#define ADC_CFGR_CONT_Msk (0x1UL << ADC_CFGR_CONT_Pos) /*!< 0x00002000 */
#define ADC_CFGR_CONT ADC_CFGR_CONT_Msk /*!< ADC group regular continuous conversion mode */
#define ADC_CFGR_AUTDLY_Pos (14U)
#define ADC_CFGR_AUTDLY_Msk (0x1UL << ADC_CFGR_AUTDLY_Pos) /*!< 0x00004000 */
#define ADC_CFGR_AUTDLY ADC_CFGR_AUTDLY_Msk /*!< ADC low power auto wait */
#define ADC_CFGR_ALIGN_Pos (15U)
#define ADC_CFGR_ALIGN_Msk (0x1UL << ADC_CFGR_ALIGN_Pos) /*!< 0x00008000 */
#define ADC_CFGR_ALIGN ADC_CFGR_ALIGN_Msk /*!< ADC data alignment */
#define ADC_CFGR_DISCEN_Pos (16U)
#define ADC_CFGR_DISCEN_Msk (0x1UL << ADC_CFGR_DISCEN_Pos) /*!< 0x00010000 */
#define ADC_CFGR_DISCEN ADC_CFGR_DISCEN_Msk /*!< ADC group regular sequencer discontinuous mode */
#define ADC_CFGR_DISCNUM_Pos (17U)
#define ADC_CFGR_DISCNUM_Msk (0x7UL << ADC_CFGR_DISCNUM_Pos) /*!< 0x000E0000 */
#define ADC_CFGR_DISCNUM ADC_CFGR_DISCNUM_Msk /*!< ADC group regular sequencer discontinuous number of ranks */
#define ADC_CFGR_DISCNUM_0 (0x1UL << ADC_CFGR_DISCNUM_Pos) /*!< 0x00020000 */
#define ADC_CFGR_DISCNUM_1 (0x2UL << ADC_CFGR_DISCNUM_Pos) /*!< 0x00040000 */
#define ADC_CFGR_DISCNUM_2 (0x4UL << ADC_CFGR_DISCNUM_Pos) /*!< 0x00080000 */
#define ADC_CFGR_JDISCEN_Pos (20U)
#define ADC_CFGR_JDISCEN_Msk (0x1UL << ADC_CFGR_JDISCEN_Pos) /*!< 0x00100000 */
#define ADC_CFGR_JDISCEN ADC_CFGR_JDISCEN_Msk /*!< ADC group injected sequencer discontinuous mode */
#define ADC_CFGR_JQM_Pos (21U)
#define ADC_CFGR_JQM_Msk (0x1UL << ADC_CFGR_JQM_Pos) /*!< 0x00200000 */
#define ADC_CFGR_JQM ADC_CFGR_JQM_Msk /*!< ADC group injected contexts queue mode */
#define ADC_CFGR_AWD1SGL_Pos (22U)
#define ADC_CFGR_AWD1SGL_Msk (0x1UL << ADC_CFGR_AWD1SGL_Pos) /*!< 0x00400000 */
#define ADC_CFGR_AWD1SGL ADC_CFGR_AWD1SGL_Msk /*!< ADC analog watchdog 1 monitoring a single channel or all channels */
#define ADC_CFGR_AWD1EN_Pos (23U)
#define ADC_CFGR_AWD1EN_Msk (0x1UL << ADC_CFGR_AWD1EN_Pos) /*!< 0x00800000 */
#define ADC_CFGR_AWD1EN ADC_CFGR_AWD1EN_Msk /*!< ADC analog watchdog 1 enable on scope ADC group regular */
#define ADC_CFGR_JAWD1EN_Pos (24U)
#define ADC_CFGR_JAWD1EN_Msk (0x1UL << ADC_CFGR_JAWD1EN_Pos) /*!< 0x01000000 */
#define ADC_CFGR_JAWD1EN ADC_CFGR_JAWD1EN_Msk /*!< ADC analog watchdog 1 enable on scope ADC group injected */
#define ADC_CFGR_JAUTO_Pos (25U)
#define ADC_CFGR_JAUTO_Msk (0x1UL << ADC_CFGR_JAUTO_Pos) /*!< 0x02000000 */
#define ADC_CFGR_JAUTO ADC_CFGR_JAUTO_Msk /*!< ADC group injected automatic trigger mode */
#define ADC_CFGR_AWD1CH_Pos (26U)
#define ADC_CFGR_AWD1CH_Msk (0x1FUL << ADC_CFGR_AWD1CH_Pos) /*!< 0x7C000000 */
#define ADC_CFGR_AWD1CH ADC_CFGR_AWD1CH_Msk /*!< ADC analog watchdog 1 monitored channel selection */
#define ADC_CFGR_AWD1CH_0 (0x01UL << ADC_CFGR_AWD1CH_Pos) /*!< 0x04000000 */
#define ADC_CFGR_AWD1CH_1 (0x02UL << ADC_CFGR_AWD1CH_Pos) /*!< 0x08000000 */
#define ADC_CFGR_AWD1CH_2 (0x04UL << ADC_CFGR_AWD1CH_Pos) /*!< 0x10000000 */
#define ADC_CFGR_AWD1CH_3 (0x08UL << ADC_CFGR_AWD1CH_Pos) /*!< 0x20000000 */
#define ADC_CFGR_AWD1CH_4 (0x10UL << ADC_CFGR_AWD1CH_Pos) /*!< 0x40000000 */
#define ADC_CFGR_JQDIS_Pos (31U)
#define ADC_CFGR_JQDIS_Msk (0x1UL << ADC_CFGR_JQDIS_Pos) /*!< 0x80000000 */
#define ADC_CFGR_JQDIS ADC_CFGR_JQDIS_Msk /*!< ADC group injected contexts queue disable */
/******************** Bit definition for ADC_CFGR2 register *****************/
#define ADC_CFGR2_ROVSE_Pos (0U)
#define ADC_CFGR2_ROVSE_Msk (0x1UL << ADC_CFGR2_ROVSE_Pos) /*!< 0x00000001 */
#define ADC_CFGR2_ROVSE ADC_CFGR2_ROVSE_Msk /*!< ADC oversampler enable on scope ADC group regular */
#define ADC_CFGR2_JOVSE_Pos (1U)
#define ADC_CFGR2_JOVSE_Msk (0x1UL << ADC_CFGR2_JOVSE_Pos) /*!< 0x00000002 */
#define ADC_CFGR2_JOVSE ADC_CFGR2_JOVSE_Msk /*!< ADC oversampler enable on scope ADC group injected */
#define ADC_CFGR2_OVSR_Pos (2U)
#define ADC_CFGR2_OVSR_Msk (0x7UL << ADC_CFGR2_OVSR_Pos) /*!< 0x0000001C */
#define ADC_CFGR2_OVSR ADC_CFGR2_OVSR_Msk /*!< ADC oversampling ratio */
#define ADC_CFGR2_OVSR_0 (0x1UL << ADC_CFGR2_OVSR_Pos) /*!< 0x00000004 */
#define ADC_CFGR2_OVSR_1 (0x2UL << ADC_CFGR2_OVSR_Pos) /*!< 0x00000008 */
#define ADC_CFGR2_OVSR_2 (0x4UL << ADC_CFGR2_OVSR_Pos) /*!< 0x00000010 */
#define ADC_CFGR2_OVSS_Pos (5U)
#define ADC_CFGR2_OVSS_Msk (0xFUL << ADC_CFGR2_OVSS_Pos) /*!< 0x000001E0 */
#define ADC_CFGR2_OVSS ADC_CFGR2_OVSS_Msk /*!< ADC oversampling shift */
#define ADC_CFGR2_OVSS_0 (0x1UL << ADC_CFGR2_OVSS_Pos) /*!< 0x00000020 */
#define ADC_CFGR2_OVSS_1 (0x2UL << ADC_CFGR2_OVSS_Pos) /*!< 0x00000040 */
#define ADC_CFGR2_OVSS_2 (0x4UL << ADC_CFGR2_OVSS_Pos) /*!< 0x00000080 */
#define ADC_CFGR2_OVSS_3 (0x8UL << ADC_CFGR2_OVSS_Pos) /*!< 0x00000100 */
#define ADC_CFGR2_TROVS_Pos (9U)
#define ADC_CFGR2_TROVS_Msk (0x1UL << ADC_CFGR2_TROVS_Pos) /*!< 0x00000200 */
#define ADC_CFGR2_TROVS ADC_CFGR2_TROVS_Msk /*!< ADC oversampling discontinuous mode (triggered mode) for ADC group regular */
#define ADC_CFGR2_ROVSM_Pos (10U)
#define ADC_CFGR2_ROVSM_Msk (0x1UL << ADC_CFGR2_ROVSM_Pos) /*!< 0x00000400 */
#define ADC_CFGR2_ROVSM ADC_CFGR2_ROVSM_Msk /*!< ADC oversampling mode managing interlaced conversions of ADC group regular and group injected */
#define ADC_CFGR2_GCOMP_Pos (16U)
#define ADC_CFGR2_GCOMP_Msk (0x1UL << ADC_CFGR2_GCOMP_Pos) /*!< 0x00010000 */
#define ADC_CFGR2_GCOMP ADC_CFGR2_GCOMP_Msk /*!< ADC Gain Compensation mode */
#define ADC_CFGR2_SWTRIG_Pos (25U)
#define ADC_CFGR2_SWTRIG_Msk (0x1UL << ADC_CFGR2_SWTRIG_Pos) /*!< 0x02000000 */
#define ADC_CFGR2_SWTRIG ADC_CFGR2_SWTRIG_Msk /*!< ADC Software Trigger Bit for Sample time control trigger mode */
#define ADC_CFGR2_BULB_Pos (26U)
#define ADC_CFGR2_BULB_Msk (0x1UL << ADC_CFGR2_BULB_Pos) /*!< 0x04000000 */
#define ADC_CFGR2_BULB ADC_CFGR2_BULB_Msk /*!< ADC Bulb sampling mode */
#define ADC_CFGR2_SMPTRIG_Pos (27U)
#define ADC_CFGR2_SMPTRIG_Msk (0x1UL << ADC_CFGR2_SMPTRIG_Pos) /*!< 0x08000000 */
#define ADC_CFGR2_SMPTRIG ADC_CFGR2_SMPTRIG_Msk /*!< ADC Sample Time Control Trigger mode */
/******************** Bit definition for ADC_SMPR1 register *****************/
#define ADC_SMPR1_SMP0_Pos (0U)
#define ADC_SMPR1_SMP0_Msk (0x7UL << ADC_SMPR1_SMP0_Pos) /*!< 0x00000007 */
#define ADC_SMPR1_SMP0 ADC_SMPR1_SMP0_Msk /*!< ADC channel 0 sampling time selection */
#define ADC_SMPR1_SMP0_0 (0x1UL << ADC_SMPR1_SMP0_Pos) /*!< 0x00000001 */
#define ADC_SMPR1_SMP0_1 (0x2UL << ADC_SMPR1_SMP0_Pos) /*!< 0x00000002 */
#define ADC_SMPR1_SMP0_2 (0x4UL << ADC_SMPR1_SMP0_Pos) /*!< 0x00000004 */
#define ADC_SMPR1_SMP1_Pos (3U)
#define ADC_SMPR1_SMP1_Msk (0x7UL << ADC_SMPR1_SMP1_Pos) /*!< 0x00000038 */
#define ADC_SMPR1_SMP1 ADC_SMPR1_SMP1_Msk /*!< ADC channel 1 sampling time selection */
#define ADC_SMPR1_SMP1_0 (0x1UL << ADC_SMPR1_SMP1_Pos) /*!< 0x00000008 */
#define ADC_SMPR1_SMP1_1 (0x2UL << ADC_SMPR1_SMP1_Pos) /*!< 0x00000010 */
#define ADC_SMPR1_SMP1_2 (0x4UL << ADC_SMPR1_SMP1_Pos) /*!< 0x00000020 */
#define ADC_SMPR1_SMP2_Pos (6U)
#define ADC_SMPR1_SMP2_Msk (0x7UL << ADC_SMPR1_SMP2_Pos) /*!< 0x000001C0 */
#define ADC_SMPR1_SMP2 ADC_SMPR1_SMP2_Msk /*!< ADC channel 2 sampling time selection */
#define ADC_SMPR1_SMP2_0 (0x1UL << ADC_SMPR1_SMP2_Pos) /*!< 0x00000040 */
#define ADC_SMPR1_SMP2_1 (0x2UL << ADC_SMPR1_SMP2_Pos) /*!< 0x00000080 */
#define ADC_SMPR1_SMP2_2 (0x4UL << ADC_SMPR1_SMP2_Pos) /*!< 0x00000100 */
#define ADC_SMPR1_SMP3_Pos (9U)
#define ADC_SMPR1_SMP3_Msk (0x7UL << ADC_SMPR1_SMP3_Pos) /*!< 0x00000E00 */
#define ADC_SMPR1_SMP3 ADC_SMPR1_SMP3_Msk /*!< ADC channel 3 sampling time selection */
#define ADC_SMPR1_SMP3_0 (0x1UL << ADC_SMPR1_SMP3_Pos) /*!< 0x00000200 */
#define ADC_SMPR1_SMP3_1 (0x2UL << ADC_SMPR1_SMP3_Pos) /*!< 0x00000400 */
#define ADC_SMPR1_SMP3_2 (0x4UL << ADC_SMPR1_SMP3_Pos) /*!< 0x00000800 */
#define ADC_SMPR1_SMP4_Pos (12U)
#define ADC_SMPR1_SMP4_Msk (0x7UL << ADC_SMPR1_SMP4_Pos) /*!< 0x00007000 */
#define ADC_SMPR1_SMP4 ADC_SMPR1_SMP4_Msk /*!< ADC channel 4 sampling time selection */
#define ADC_SMPR1_SMP4_0 (0x1UL << ADC_SMPR1_SMP4_Pos) /*!< 0x00001000 */
#define ADC_SMPR1_SMP4_1 (0x2UL << ADC_SMPR1_SMP4_Pos) /*!< 0x00002000 */
#define ADC_SMPR1_SMP4_2 (0x4UL << ADC_SMPR1_SMP4_Pos) /*!< 0x00004000 */
#define ADC_SMPR1_SMP5_Pos (15U)
#define ADC_SMPR1_SMP5_Msk (0x7UL << ADC_SMPR1_SMP5_Pos) /*!< 0x00038000 */
#define ADC_SMPR1_SMP5 ADC_SMPR1_SMP5_Msk /*!< ADC channel 5 sampling time selection */
#define ADC_SMPR1_SMP5_0 (0x1UL << ADC_SMPR1_SMP5_Pos) /*!< 0x00008000 */
#define ADC_SMPR1_SMP5_1 (0x2UL << ADC_SMPR1_SMP5_Pos) /*!< 0x00010000 */
#define ADC_SMPR1_SMP5_2 (0x4UL << ADC_SMPR1_SMP5_Pos) /*!< 0x00020000 */
#define ADC_SMPR1_SMP6_Pos (18U)
#define ADC_SMPR1_SMP6_Msk (0x7UL << ADC_SMPR1_SMP6_Pos) /*!< 0x001C0000 */
#define ADC_SMPR1_SMP6 ADC_SMPR1_SMP6_Msk /*!< ADC channel 6 sampling time selection */
#define ADC_SMPR1_SMP6_0 (0x1UL << ADC_SMPR1_SMP6_Pos) /*!< 0x00040000 */
#define ADC_SMPR1_SMP6_1 (0x2UL << ADC_SMPR1_SMP6_Pos) /*!< 0x00080000 */
#define ADC_SMPR1_SMP6_2 (0x4UL << ADC_SMPR1_SMP6_Pos) /*!< 0x00100000 */
#define ADC_SMPR1_SMP7_Pos (21U)
#define ADC_SMPR1_SMP7_Msk (0x7UL << ADC_SMPR1_SMP7_Pos) /*!< 0x00E00000 */
#define ADC_SMPR1_SMP7 ADC_SMPR1_SMP7_Msk /*!< ADC channel 7 sampling time selection */
#define ADC_SMPR1_SMP7_0 (0x1UL << ADC_SMPR1_SMP7_Pos) /*!< 0x00200000 */
#define ADC_SMPR1_SMP7_1 (0x2UL << ADC_SMPR1_SMP7_Pos) /*!< 0x00400000 */
#define ADC_SMPR1_SMP7_2 (0x4UL << ADC_SMPR1_SMP7_Pos) /*!< 0x00800000 */
#define ADC_SMPR1_SMP8_Pos (24U)
#define ADC_SMPR1_SMP8_Msk (0x7UL << ADC_SMPR1_SMP8_Pos) /*!< 0x07000000 */
#define ADC_SMPR1_SMP8 ADC_SMPR1_SMP8_Msk /*!< ADC channel 8 sampling time selection */
#define ADC_SMPR1_SMP8_0 (0x1UL << ADC_SMPR1_SMP8_Pos) /*!< 0x01000000 */
#define ADC_SMPR1_SMP8_1 (0x2UL << ADC_SMPR1_SMP8_Pos) /*!< 0x02000000 */
#define ADC_SMPR1_SMP8_2 (0x4UL << ADC_SMPR1_SMP8_Pos) /*!< 0x04000000 */
#define ADC_SMPR1_SMP9_Pos (27U)
#define ADC_SMPR1_SMP9_Msk (0x7UL << ADC_SMPR1_SMP9_Pos) /*!< 0x38000000 */
#define ADC_SMPR1_SMP9 ADC_SMPR1_SMP9_Msk /*!< ADC channel 9 sampling time selection */
#define ADC_SMPR1_SMP9_0 (0x1UL << ADC_SMPR1_SMP9_Pos) /*!< 0x08000000 */
#define ADC_SMPR1_SMP9_1 (0x2UL << ADC_SMPR1_SMP9_Pos) /*!< 0x10000000 */
#define ADC_SMPR1_SMP9_2 (0x4UL << ADC_SMPR1_SMP9_Pos) /*!< 0x20000000 */
#define ADC_SMPR1_SMPPLUS_Pos (31U)
#define ADC_SMPR1_SMPPLUS_Msk (0x1UL << ADC_SMPR1_SMPPLUS_Pos) /*!< 0x80000000 */
#define ADC_SMPR1_SMPPLUS ADC_SMPR1_SMPPLUS_Msk /*!< ADC channels sampling time additional setting */
/******************** Bit definition for ADC_SMPR2 register *****************/
#define ADC_SMPR2_SMP10_Pos (0U)
#define ADC_SMPR2_SMP10_Msk (0x7UL << ADC_SMPR2_SMP10_Pos) /*!< 0x00000007 */
#define ADC_SMPR2_SMP10 ADC_SMPR2_SMP10_Msk /*!< ADC channel 10 sampling time selection */
#define ADC_SMPR2_SMP10_0 (0x1UL << ADC_SMPR2_SMP10_Pos) /*!< 0x00000001 */
#define ADC_SMPR2_SMP10_1 (0x2UL << ADC_SMPR2_SMP10_Pos) /*!< 0x00000002 */
#define ADC_SMPR2_SMP10_2 (0x4UL << ADC_SMPR2_SMP10_Pos) /*!< 0x00000004 */
#define ADC_SMPR2_SMP11_Pos (3U)
#define ADC_SMPR2_SMP11_Msk (0x7UL << ADC_SMPR2_SMP11_Pos) /*!< 0x00000038 */
#define ADC_SMPR2_SMP11 ADC_SMPR2_SMP11_Msk /*!< ADC channel 11 sampling time selection */
#define ADC_SMPR2_SMP11_0 (0x1UL << ADC_SMPR2_SMP11_Pos) /*!< 0x00000008 */
#define ADC_SMPR2_SMP11_1 (0x2UL << ADC_SMPR2_SMP11_Pos) /*!< 0x00000010 */
#define ADC_SMPR2_SMP11_2 (0x4UL << ADC_SMPR2_SMP11_Pos) /*!< 0x00000020 */
#define ADC_SMPR2_SMP12_Pos (6U)
#define ADC_SMPR2_SMP12_Msk (0x7UL << ADC_SMPR2_SMP12_Pos) /*!< 0x000001C0 */
#define ADC_SMPR2_SMP12 ADC_SMPR2_SMP12_Msk /*!< ADC channel 12 sampling time selection */
#define ADC_SMPR2_SMP12_0 (0x1UL << ADC_SMPR2_SMP12_Pos) /*!< 0x00000040 */
#define ADC_SMPR2_SMP12_1 (0x2UL << ADC_SMPR2_SMP12_Pos) /*!< 0x00000080 */
#define ADC_SMPR2_SMP12_2 (0x4UL << ADC_SMPR2_SMP12_Pos) /*!< 0x00000100 */
#define ADC_SMPR2_SMP13_Pos (9U)
#define ADC_SMPR2_SMP13_Msk (0x7UL << ADC_SMPR2_SMP13_Pos) /*!< 0x00000E00 */
#define ADC_SMPR2_SMP13 ADC_SMPR2_SMP13_Msk /*!< ADC channel 13 sampling time selection */
#define ADC_SMPR2_SMP13_0 (0x1UL << ADC_SMPR2_SMP13_Pos) /*!< 0x00000200 */
#define ADC_SMPR2_SMP13_1 (0x2UL << ADC_SMPR2_SMP13_Pos) /*!< 0x00000400 */
#define ADC_SMPR2_SMP13_2 (0x4UL << ADC_SMPR2_SMP13_Pos) /*!< 0x00000800 */
#define ADC_SMPR2_SMP14_Pos (12U)
#define ADC_SMPR2_SMP14_Msk (0x7UL << ADC_SMPR2_SMP14_Pos) /*!< 0x00007000 */
#define ADC_SMPR2_SMP14 ADC_SMPR2_SMP14_Msk /*!< ADC channel 14 sampling time selection */
#define ADC_SMPR2_SMP14_0 (0x1UL << ADC_SMPR2_SMP14_Pos) /*!< 0x00001000 */
#define ADC_SMPR2_SMP14_1 (0x2UL << ADC_SMPR2_SMP14_Pos) /*!< 0x00002000 */
#define ADC_SMPR2_SMP14_2 (0x4UL << ADC_SMPR2_SMP14_Pos) /*!< 0x00004000 */
#define ADC_SMPR2_SMP15_Pos (15U)
#define ADC_SMPR2_SMP15_Msk (0x7UL << ADC_SMPR2_SMP15_Pos) /*!< 0x00038000 */
#define ADC_SMPR2_SMP15 ADC_SMPR2_SMP15_Msk /*!< ADC channel 15 sampling time selection */
#define ADC_SMPR2_SMP15_0 (0x1UL << ADC_SMPR2_SMP15_Pos) /*!< 0x00008000 */
#define ADC_SMPR2_SMP15_1 (0x2UL << ADC_SMPR2_SMP15_Pos) /*!< 0x00010000 */
#define ADC_SMPR2_SMP15_2 (0x4UL << ADC_SMPR2_SMP15_Pos) /*!< 0x00020000 */
#define ADC_SMPR2_SMP16_Pos (18U)
#define ADC_SMPR2_SMP16_Msk (0x7UL << ADC_SMPR2_SMP16_Pos) /*!< 0x001C0000 */
#define ADC_SMPR2_SMP16 ADC_SMPR2_SMP16_Msk /*!< ADC channel 16 sampling time selection */
#define ADC_SMPR2_SMP16_0 (0x1UL << ADC_SMPR2_SMP16_Pos) /*!< 0x00040000 */
#define ADC_SMPR2_SMP16_1 (0x2UL << ADC_SMPR2_SMP16_Pos) /*!< 0x00080000 */
#define ADC_SMPR2_SMP16_2 (0x4UL << ADC_SMPR2_SMP16_Pos) /*!< 0x00100000 */
#define ADC_SMPR2_SMP17_Pos (21U)
#define ADC_SMPR2_SMP17_Msk (0x7UL << ADC_SMPR2_SMP17_Pos) /*!< 0x00E00000 */
#define ADC_SMPR2_SMP17 ADC_SMPR2_SMP17_Msk /*!< ADC channel 17 sampling time selection */
#define ADC_SMPR2_SMP17_0 (0x1UL << ADC_SMPR2_SMP17_Pos) /*!< 0x00200000 */
#define ADC_SMPR2_SMP17_1 (0x2UL << ADC_SMPR2_SMP17_Pos) /*!< 0x00400000 */
#define ADC_SMPR2_SMP17_2 (0x4UL << ADC_SMPR2_SMP17_Pos) /*!< 0x00800000 */
#define ADC_SMPR2_SMP18_Pos (24U)
#define ADC_SMPR2_SMP18_Msk (0x7UL << ADC_SMPR2_SMP18_Pos) /*!< 0x07000000 */
#define ADC_SMPR2_SMP18 ADC_SMPR2_SMP18_Msk /*!< ADC channel 18 sampling time selection */
#define ADC_SMPR2_SMP18_0 (0x1UL << ADC_SMPR2_SMP18_Pos) /*!< 0x01000000 */
#define ADC_SMPR2_SMP18_1 (0x2UL << ADC_SMPR2_SMP18_Pos) /*!< 0x02000000 */
#define ADC_SMPR2_SMP18_2 (0x4UL << ADC_SMPR2_SMP18_Pos) /*!< 0x04000000 */
/******************** Bit definition for ADC_TR1 register *******************/
#define ADC_TR1_LT1_Pos (0U)
#define ADC_TR1_LT1_Msk (0xFFFUL << ADC_TR1_LT1_Pos) /*!< 0x00000FFF */
#define ADC_TR1_LT1 ADC_TR1_LT1_Msk /*!< ADC analog watchdog 1 threshold low */
#define ADC_TR1_AWDFILT_Pos (12U)
#define ADC_TR1_AWDFILT_Msk (0x7UL << ADC_TR1_AWDFILT_Pos) /*!< 0x00007000 */
#define ADC_TR1_AWDFILT ADC_TR1_AWDFILT_Msk /*!< ADC analog watchdog filtering parameter */
#define ADC_TR1_AWDFILT_0 (0x1UL << ADC_TR1_AWDFILT_Pos) /*!< 0x00001000 */
#define ADC_TR1_AWDFILT_1 (0x2UL << ADC_TR1_AWDFILT_Pos) /*!< 0x00002000 */
#define ADC_TR1_AWDFILT_2 (0x4UL << ADC_TR1_AWDFILT_Pos) /*!< 0x00004000 */
#define ADC_TR1_HT1_Pos (16U)
#define ADC_TR1_HT1_Msk (0xFFFUL << ADC_TR1_HT1_Pos) /*!< 0x0FFF0000 */
#define ADC_TR1_HT1 ADC_TR1_HT1_Msk /*!< ADC analog watchdog 1 threshold high */
/******************** Bit definition for ADC_TR2 register *******************/
#define ADC_TR2_LT2_Pos (0U)
#define ADC_TR2_LT2_Msk (0xFFUL << ADC_TR2_LT2_Pos) /*!< 0x000000FF */
#define ADC_TR2_LT2 ADC_TR2_LT2_Msk /*!< ADC analog watchdog 2 threshold low */
#define ADC_TR2_HT2_Pos (16U)
#define ADC_TR2_HT2_Msk (0xFFUL << ADC_TR2_HT2_Pos) /*!< 0x00FF0000 */
#define ADC_TR2_HT2 ADC_TR2_HT2_Msk /*!< ADC analog watchdog 2 threshold high */
/******************** Bit definition for ADC_TR3 register *******************/
#define ADC_TR3_LT3_Pos (0U)
#define ADC_TR3_LT3_Msk (0xFFUL << ADC_TR3_LT3_Pos) /*!< 0x000000FF */
#define ADC_TR3_LT3 ADC_TR3_LT3_Msk /*!< ADC analog watchdog 3 threshold low */
#define ADC_TR3_HT3_Pos (16U)
#define ADC_TR3_HT3_Msk (0xFFUL << ADC_TR3_HT3_Pos) /*!< 0x00FF0000 */
#define ADC_TR3_HT3 ADC_TR3_HT3_Msk /*!< ADC analog watchdog 3 threshold high */
/******************** Bit definition for ADC_SQR1 register ******************/
#define ADC_SQR1_L_Pos (0U)
#define ADC_SQR1_L_Msk (0xFUL << ADC_SQR1_L_Pos) /*!< 0x0000000F */
#define ADC_SQR1_L ADC_SQR1_L_Msk /*!< ADC group regular sequencer scan length */
#define ADC_SQR1_L_0 (0x1UL << ADC_SQR1_L_Pos) /*!< 0x00000001 */
#define ADC_SQR1_L_1 (0x2UL << ADC_SQR1_L_Pos) /*!< 0x00000002 */
#define ADC_SQR1_L_2 (0x4UL << ADC_SQR1_L_Pos) /*!< 0x00000004 */
#define ADC_SQR1_L_3 (0x8UL << ADC_SQR1_L_Pos) /*!< 0x00000008 */
#define ADC_SQR1_SQ1_Pos (6U)
#define ADC_SQR1_SQ1_Msk (0x1FUL << ADC_SQR1_SQ1_Pos) /*!< 0x000007C0 */
#define ADC_SQR1_SQ1 ADC_SQR1_SQ1_Msk /*!< ADC group regular sequencer rank 1 */
#define ADC_SQR1_SQ1_0 (0x01UL << ADC_SQR1_SQ1_Pos) /*!< 0x00000040 */
#define ADC_SQR1_SQ1_1 (0x02UL << ADC_SQR1_SQ1_Pos) /*!< 0x00000080 */
#define ADC_SQR1_SQ1_2 (0x04UL << ADC_SQR1_SQ1_Pos) /*!< 0x00000100 */
#define ADC_SQR1_SQ1_3 (0x08UL << ADC_SQR1_SQ1_Pos) /*!< 0x00000200 */
#define ADC_SQR1_SQ1_4 (0x10UL << ADC_SQR1_SQ1_Pos) /*!< 0x00000400 */
#define ADC_SQR1_SQ2_Pos (12U)
#define ADC_SQR1_SQ2_Msk (0x1FUL << ADC_SQR1_SQ2_Pos) /*!< 0x0001F000 */
#define ADC_SQR1_SQ2 ADC_SQR1_SQ2_Msk /*!< ADC group regular sequencer rank 2 */
#define ADC_SQR1_SQ2_0 (0x01UL << ADC_SQR1_SQ2_Pos) /*!< 0x00001000 */
#define ADC_SQR1_SQ2_1 (0x02UL << ADC_SQR1_SQ2_Pos) /*!< 0x00002000 */
#define ADC_SQR1_SQ2_2 (0x04UL << ADC_SQR1_SQ2_Pos) /*!< 0x00004000 */
#define ADC_SQR1_SQ2_3 (0x08UL << ADC_SQR1_SQ2_Pos) /*!< 0x00008000 */
#define ADC_SQR1_SQ2_4 (0x10UL << ADC_SQR1_SQ2_Pos) /*!< 0x00010000 */
#define ADC_SQR1_SQ3_Pos (18U)
#define ADC_SQR1_SQ3_Msk (0x1FUL << ADC_SQR1_SQ3_Pos) /*!< 0x007C0000 */
#define ADC_SQR1_SQ3 ADC_SQR1_SQ3_Msk /*!< ADC group regular sequencer rank 3 */
#define ADC_SQR1_SQ3_0 (0x01UL << ADC_SQR1_SQ3_Pos) /*!< 0x00040000 */
#define ADC_SQR1_SQ3_1 (0x02UL << ADC_SQR1_SQ3_Pos) /*!< 0x00080000 */
#define ADC_SQR1_SQ3_2 (0x04UL << ADC_SQR1_SQ3_Pos) /*!< 0x00100000 */
#define ADC_SQR1_SQ3_3 (0x08UL << ADC_SQR1_SQ3_Pos) /*!< 0x00200000 */
#define ADC_SQR1_SQ3_4 (0x10UL<< ADC_SQR1_SQ3_Pos) /*!< 0x00400000 */
#define ADC_SQR1_SQ4_Pos (24U)
#define ADC_SQR1_SQ4_Msk (0x1FUL << ADC_SQR1_SQ4_Pos) /*!< 0x1F000000 */
#define ADC_SQR1_SQ4 ADC_SQR1_SQ4_Msk /*!< ADC group regular sequencer rank 4 */
#define ADC_SQR1_SQ4_0 (0x01UL << ADC_SQR1_SQ4_Pos) /*!< 0x01000000 */
#define ADC_SQR1_SQ4_1 (0x02UL << ADC_SQR1_SQ4_Pos) /*!< 0x02000000 */
#define ADC_SQR1_SQ4_2 (0x04UL << ADC_SQR1_SQ4_Pos) /*!< 0x04000000 */
#define ADC_SQR1_SQ4_3 (0x08UL << ADC_SQR1_SQ4_Pos) /*!< 0x08000000 */
#define ADC_SQR1_SQ4_4 (0x10UL << ADC_SQR1_SQ4_Pos) /*!< 0x10000000 */
/******************** Bit definition for ADC_SQR2 register ******************/
#define ADC_SQR2_SQ5_Pos (0U)
#define ADC_SQR2_SQ5_Msk (0x1FUL << ADC_SQR2_SQ5_Pos) /*!< 0x0000001F */
#define ADC_SQR2_SQ5 ADC_SQR2_SQ5_Msk /*!< ADC group regular sequencer rank 5 */
#define ADC_SQR2_SQ5_0 (0x01UL << ADC_SQR2_SQ5_Pos) /*!< 0x00000001 */
#define ADC_SQR2_SQ5_1 (0x02UL << ADC_SQR2_SQ5_Pos) /*!< 0x00000002 */
#define ADC_SQR2_SQ5_2 (0x04UL << ADC_SQR2_SQ5_Pos) /*!< 0x00000004 */
#define ADC_SQR2_SQ5_3 (0x08UL << ADC_SQR2_SQ5_Pos) /*!< 0x00000008 */
#define ADC_SQR2_SQ5_4 (0x10UL << ADC_SQR2_SQ5_Pos) /*!< 0x00000010 */
#define ADC_SQR2_SQ6_Pos (6U)
#define ADC_SQR2_SQ6_Msk (0x1FUL << ADC_SQR2_SQ6_Pos) /*!< 0x000007C0 */
#define ADC_SQR2_SQ6 ADC_SQR2_SQ6_Msk /*!< ADC group regular sequencer rank 6 */
#define ADC_SQR2_SQ6_0 (0x01UL << ADC_SQR2_SQ6_Pos) /*!< 0x00000040 */
#define ADC_SQR2_SQ6_1 (0x02UL << ADC_SQR2_SQ6_Pos) /*!< 0x00000080 */
#define ADC_SQR2_SQ6_2 (0x04UL << ADC_SQR2_SQ6_Pos) /*!< 0x00000100 */
#define ADC_SQR2_SQ6_3 (0x08UL << ADC_SQR2_SQ6_Pos) /*!< 0x00000200 */
#define ADC_SQR2_SQ6_4 (0x10UL << ADC_SQR2_SQ6_Pos) /*!< 0x00000400 */
#define ADC_SQR2_SQ7_Pos (12U)
#define ADC_SQR2_SQ7_Msk (0x1FUL << ADC_SQR2_SQ7_Pos) /*!< 0x0001F000 */
#define ADC_SQR2_SQ7 ADC_SQR2_SQ7_Msk /*!< ADC group regular sequencer rank 7 */
#define ADC_SQR2_SQ7_0 (0x01UL << ADC_SQR2_SQ7_Pos) /*!< 0x00001000 */
#define ADC_SQR2_SQ7_1 (0x02UL << ADC_SQR2_SQ7_Pos) /*!< 0x00002000 */
#define ADC_SQR2_SQ7_2 (0x04UL << ADC_SQR2_SQ7_Pos) /*!< 0x00004000 */
#define ADC_SQR2_SQ7_3 (0x08UL << ADC_SQR2_SQ7_Pos) /*!< 0x00008000 */
#define ADC_SQR2_SQ7_4 (0x10UL << ADC_SQR2_SQ7_Pos) /*!< 0x00010000 */
#define ADC_SQR2_SQ8_Pos (18U)
#define ADC_SQR2_SQ8_Msk (0x1FUL << ADC_SQR2_SQ8_Pos) /*!< 0x007C0000 */
#define ADC_SQR2_SQ8 ADC_SQR2_SQ8_Msk /*!< ADC group regular sequencer rank 8 */
#define ADC_SQR2_SQ8_0 (0x01UL << ADC_SQR2_SQ8_Pos) /*!< 0x00040000 */
#define ADC_SQR2_SQ8_1 (0x02UL << ADC_SQR2_SQ8_Pos) /*!< 0x00080000 */
#define ADC_SQR2_SQ8_2 (0x04UL << ADC_SQR2_SQ8_Pos) /*!< 0x00100000 */
#define ADC_SQR2_SQ8_3 (0x08UL << ADC_SQR2_SQ8_Pos) /*!< 0x00200000 */
#define ADC_SQR2_SQ8_4 (0x10UL << ADC_SQR2_SQ8_Pos) /*!< 0x00400000 */
#define ADC_SQR2_SQ9_Pos (24U)
#define ADC_SQR2_SQ9_Msk (0x1FUL << ADC_SQR2_SQ9_Pos) /*!< 0x1F000000 */
#define ADC_SQR2_SQ9 ADC_SQR2_SQ9_Msk /*!< ADC group regular sequencer rank 9 */
#define ADC_SQR2_SQ9_0 (0x01UL << ADC_SQR2_SQ9_Pos) /*!< 0x01000000 */
#define ADC_SQR2_SQ9_1 (0x02UL << ADC_SQR2_SQ9_Pos) /*!< 0x02000000 */
#define ADC_SQR2_SQ9_2 (0x04UL << ADC_SQR2_SQ9_Pos) /*!< 0x04000000 */
#define ADC_SQR2_SQ9_3 (0x08UL << ADC_SQR2_SQ9_Pos) /*!< 0x08000000 */
#define ADC_SQR2_SQ9_4 (0x10UL << ADC_SQR2_SQ9_Pos) /*!< 0x10000000 */
/******************** Bit definition for ADC_SQR3 register ******************/
#define ADC_SQR3_SQ10_Pos (0U)
#define ADC_SQR3_SQ10_Msk (0x1FUL << ADC_SQR3_SQ10_Pos) /*!< 0x0000001F */
#define ADC_SQR3_SQ10 ADC_SQR3_SQ10_Msk /*!< ADC group regular sequencer rank 10 */
#define ADC_SQR3_SQ10_0 (0x01UL << ADC_SQR3_SQ10_Pos) /*!< 0x00000001 */
#define ADC_SQR3_SQ10_1 (0x02UL << ADC_SQR3_SQ10_Pos) /*!< 0x00000002 */
#define ADC_SQR3_SQ10_2 (0x04UL << ADC_SQR3_SQ10_Pos) /*!< 0x00000004 */
#define ADC_SQR3_SQ10_3 (0x08UL << ADC_SQR3_SQ10_Pos) /*!< 0x00000008 */
#define ADC_SQR3_SQ10_4 (0x10UL << ADC_SQR3_SQ10_Pos) /*!< 0x00000010 */
#define ADC_SQR3_SQ11_Pos (6U)
#define ADC_SQR3_SQ11_Msk (0x1FUL << ADC_SQR3_SQ11_Pos) /*!< 0x000007C0 */
#define ADC_SQR3_SQ11 ADC_SQR3_SQ11_Msk /*!< ADC group regular sequencer rank 11 */
#define ADC_SQR3_SQ11_0 (0x01UL << ADC_SQR3_SQ11_Pos) /*!< 0x00000040 */
#define ADC_SQR3_SQ11_1 (0x02UL << ADC_SQR3_SQ11_Pos) /*!< 0x00000080 */
#define ADC_SQR3_SQ11_2 (0x04UL << ADC_SQR3_SQ11_Pos) /*!< 0x00000100 */
#define ADC_SQR3_SQ11_3 (0x08UL << ADC_SQR3_SQ11_Pos) /*!< 0x00000200 */
#define ADC_SQR3_SQ11_4 (0x10UL << ADC_SQR3_SQ11_Pos) /*!< 0x00000400 */
#define ADC_SQR3_SQ12_Pos (12U)
#define ADC_SQR3_SQ12_Msk (0x1FUL << ADC_SQR3_SQ12_Pos) /*!< 0x0001F000 */
#define ADC_SQR3_SQ12 ADC_SQR3_SQ12_Msk /*!< ADC group regular sequencer rank 12 */
#define ADC_SQR3_SQ12_0 (0x01UL << ADC_SQR3_SQ12_Pos) /*!< 0x00001000 */
#define ADC_SQR3_SQ12_1 (0x02UL << ADC_SQR3_SQ12_Pos) /*!< 0x00002000 */
#define ADC_SQR3_SQ12_2 (0x04UL << ADC_SQR3_SQ12_Pos) /*!< 0x00004000 */
#define ADC_SQR3_SQ12_3 (0x08UL << ADC_SQR3_SQ12_Pos) /*!< 0x00008000 */
#define ADC_SQR3_SQ12_4 (0x10UL << ADC_SQR3_SQ12_Pos) /*!< 0x00010000 */
#define ADC_SQR3_SQ13_Pos (18U)
#define ADC_SQR3_SQ13_Msk (0x1FUL << ADC_SQR3_SQ13_Pos) /*!< 0x007C0000 */
#define ADC_SQR3_SQ13 ADC_SQR3_SQ13_Msk /*!< ADC group regular sequencer rank 13 */
#define ADC_SQR3_SQ13_0 (0x01UL << ADC_SQR3_SQ13_Pos) /*!< 0x00040000 */
#define ADC_SQR3_SQ13_1 (0x02UL << ADC_SQR3_SQ13_Pos) /*!< 0x00080000 */
#define ADC_SQR3_SQ13_2 (0x04UL << ADC_SQR3_SQ13_Pos) /*!< 0x00100000 */
#define ADC_SQR3_SQ13_3 (0x08UL << ADC_SQR3_SQ13_Pos) /*!< 0x00200000 */
#define ADC_SQR3_SQ13_4 (0x10UL << ADC_SQR3_SQ13_Pos) /*!< 0x00400000 */
#define ADC_SQR3_SQ14_Pos (24U)
#define ADC_SQR3_SQ14_Msk (0x1FUL << ADC_SQR3_SQ14_Pos) /*!< 0x1F000000 */
#define ADC_SQR3_SQ14 ADC_SQR3_SQ14_Msk /*!< ADC group regular sequencer rank 14 */
#define ADC_SQR3_SQ14_0 (0x01UL << ADC_SQR3_SQ14_Pos) /*!< 0x01000000 */
#define ADC_SQR3_SQ14_1 (0x02UL << ADC_SQR3_SQ14_Pos) /*!< 0x02000000 */
#define ADC_SQR3_SQ14_2 (0x04UL << ADC_SQR3_SQ14_Pos) /*!< 0x04000000 */
#define ADC_SQR3_SQ14_3 (0x08UL << ADC_SQR3_SQ14_Pos) /*!< 0x08000000 */
#define ADC_SQR3_SQ14_4 (0x10UL << ADC_SQR3_SQ14_Pos) /*!< 0x10000000 */
/******************** Bit definition for ADC_SQR4 register ******************/
#define ADC_SQR4_SQ15_Pos (0U)
#define ADC_SQR4_SQ15_Msk (0x1FUL << ADC_SQR4_SQ15_Pos) /*!< 0x0000001F */
#define ADC_SQR4_SQ15 ADC_SQR4_SQ15_Msk /*!< ADC group regular sequencer rank 15 */
#define ADC_SQR4_SQ15_0 (0x01UL << ADC_SQR4_SQ15_Pos) /*!< 0x00000001 */
#define ADC_SQR4_SQ15_1 (0x02UL << ADC_SQR4_SQ15_Pos) /*!< 0x00000002 */
#define ADC_SQR4_SQ15_2 (0x04UL << ADC_SQR4_SQ15_Pos) /*!< 0x00000004 */
#define ADC_SQR4_SQ15_3 (0x08UL << ADC_SQR4_SQ15_Pos) /*!< 0x00000008 */
#define ADC_SQR4_SQ15_4 (0x10UL << ADC_SQR4_SQ15_Pos) /*!< 0x00000010 */
#define ADC_SQR4_SQ16_Pos (6U)
#define ADC_SQR4_SQ16_Msk (0x1FUL << ADC_SQR4_SQ16_Pos) /*!< 0x000007C0 */
#define ADC_SQR4_SQ16 ADC_SQR4_SQ16_Msk /*!< ADC group regular sequencer rank 16 */
#define ADC_SQR4_SQ16_0 (0x01UL << ADC_SQR4_SQ16_Pos) /*!< 0x00000040 */
#define ADC_SQR4_SQ16_1 (0x02UL << ADC_SQR4_SQ16_Pos) /*!< 0x00000080 */
#define ADC_SQR4_SQ16_2 (0x04UL << ADC_SQR4_SQ16_Pos) /*!< 0x00000100 */
#define ADC_SQR4_SQ16_3 (0x08UL << ADC_SQR4_SQ16_Pos) /*!< 0x00000200 */
#define ADC_SQR4_SQ16_4 (0x10UL << ADC_SQR4_SQ16_Pos) /*!< 0x00000400 */
/******************** Bit definition for ADC_DR register ********************/
#define ADC_DR_RDATA_Pos (0U)
#define ADC_DR_RDATA_Msk (0xFFFFUL << ADC_DR_RDATA_Pos) /*!< 0x0000FFFF */
#define ADC_DR_RDATA ADC_DR_RDATA_Msk /*!< ADC group regular conversion data */
/******************** Bit definition for ADC_JSQR register ******************/
#define ADC_JSQR_JL_Pos (0U)
#define ADC_JSQR_JL_Msk (0x3UL << ADC_JSQR_JL_Pos) /*!< 0x00000003 */
#define ADC_JSQR_JL ADC_JSQR_JL_Msk /*!< ADC group injected sequencer scan length */
#define ADC_JSQR_JL_0 (0x1UL << ADC_JSQR_JL_Pos) /*!< 0x00000001 */
#define ADC_JSQR_JL_1 (0x2UL << ADC_JSQR_JL_Pos) /*!< 0x00000002 */
#define ADC_JSQR_JEXTSEL_Pos (2U)
#define ADC_JSQR_JEXTSEL_Msk (0x1FUL << ADC_JSQR_JEXTSEL_Pos) /*!< 0x0000007C */
#define ADC_JSQR_JEXTSEL ADC_JSQR_JEXTSEL_Msk /*!< ADC group injected external trigger source */
#define ADC_JSQR_JEXTSEL_0 (0x1UL << ADC_JSQR_JEXTSEL_Pos) /*!< 0x00000004 */
#define ADC_JSQR_JEXTSEL_1 (0x2UL << ADC_JSQR_JEXTSEL_Pos) /*!< 0x00000008 */
#define ADC_JSQR_JEXTSEL_2 (0x4UL << ADC_JSQR_JEXTSEL_Pos) /*!< 0x00000010 */
#define ADC_JSQR_JEXTSEL_3 (0x8UL << ADC_JSQR_JEXTSEL_Pos) /*!< 0x00000020 */
#define ADC_JSQR_JEXTSEL_4 (0x10UL << ADC_JSQR_JEXTSEL_Pos) /*!< 0x00000040 */
#define ADC_JSQR_JEXTEN_Pos (7U)
#define ADC_JSQR_JEXTEN_Msk (0x3UL << ADC_JSQR_JEXTEN_Pos) /*!< 0x00000180 */
#define ADC_JSQR_JEXTEN ADC_JSQR_JEXTEN_Msk /*!< ADC group injected external trigger polarity */
#define ADC_JSQR_JEXTEN_0 (0x1UL << ADC_JSQR_JEXTEN_Pos) /*!< 0x00000080 */
#define ADC_JSQR_JEXTEN_1 (0x2UL << ADC_JSQR_JEXTEN_Pos) /*!< 0x00000100 */
#define ADC_JSQR_JSQ1_Pos (9U)
#define ADC_JSQR_JSQ1_Msk (0x1FUL << ADC_JSQR_JSQ1_Pos) /*!< 0x00003E00 */
#define ADC_JSQR_JSQ1 ADC_JSQR_JSQ1_Msk /*!< ADC group injected sequencer rank 1 */
#define ADC_JSQR_JSQ1_0 (0x01UL << ADC_JSQR_JSQ1_Pos) /*!< 0x00000200 */
#define ADC_JSQR_JSQ1_1 (0x02UL << ADC_JSQR_JSQ1_Pos) /*!< 0x00000400 */
#define ADC_JSQR_JSQ1_2 (0x04UL << ADC_JSQR_JSQ1_Pos) /*!< 0x00000800 */
#define ADC_JSQR_JSQ1_3 (0x08UL << ADC_JSQR_JSQ1_Pos) /*!< 0x00001000 */
#define ADC_JSQR_JSQ1_4 (0x10UL << ADC_JSQR_JSQ1_Pos) /*!< 0x00002000 */
#define ADC_JSQR_JSQ2_Pos (15U)
#define ADC_JSQR_JSQ2_Msk (0x1FUL << ADC_JSQR_JSQ2_Pos) /*!< 0x0007C000 */
#define ADC_JSQR_JSQ2 ADC_JSQR_JSQ2_Msk /*!< ADC group injected sequencer rank 2 */
#define ADC_JSQR_JSQ2_0 (0x01UL << ADC_JSQR_JSQ2_Pos) /*!< 0x00004000 */
#define ADC_JSQR_JSQ2_1 (0x02UL << ADC_JSQR_JSQ2_Pos) /*!< 0x00008000 */
#define ADC_JSQR_JSQ2_2 (0x04UL << ADC_JSQR_JSQ2_Pos) /*!< 0x00010000 */
#define ADC_JSQR_JSQ2_3 (0x08UL << ADC_JSQR_JSQ2_Pos) /*!< 0x00020000 */
#define ADC_JSQR_JSQ2_4 (0x10UL << ADC_JSQR_JSQ2_Pos) /*!< 0x00040000 */
#define ADC_JSQR_JSQ3_Pos (21U)
#define ADC_JSQR_JSQ3_Msk (0x1FUL << ADC_JSQR_JSQ3_Pos) /*!< 0x03E00000 */
#define ADC_JSQR_JSQ3 ADC_JSQR_JSQ3_Msk /*!< ADC group injected sequencer rank 3 */
#define ADC_JSQR_JSQ3_0 (0x01UL << ADC_JSQR_JSQ3_Pos) /*!< 0x00200000 */
#define ADC_JSQR_JSQ3_1 (0x02UL << ADC_JSQR_JSQ3_Pos) /*!< 0x00400000 */
#define ADC_JSQR_JSQ3_2 (0x04UL << ADC_JSQR_JSQ3_Pos) /*!< 0x00800000 */
#define ADC_JSQR_JSQ3_3 (0x08UL << ADC_JSQR_JSQ3_Pos) /*!< 0x01000000 */
#define ADC_JSQR_JSQ3_4 (0x10UL << ADC_JSQR_JSQ3_Pos) /*!< 0x02000000 */
#define ADC_JSQR_JSQ4_Pos (27U)
#define ADC_JSQR_JSQ4_Msk (0x1FUL << ADC_JSQR_JSQ4_Pos) /*!< 0xF8000000 */
#define ADC_JSQR_JSQ4 ADC_JSQR_JSQ4_Msk /*!< ADC group injected sequencer rank 4 */
#define ADC_JSQR_JSQ4_0 (0x01UL << ADC_JSQR_JSQ4_Pos) /*!< 0x08000000 */
#define ADC_JSQR_JSQ4_1 (0x02UL << ADC_JSQR_JSQ4_Pos) /*!< 0x10000000 */
#define ADC_JSQR_JSQ4_2 (0x04UL << ADC_JSQR_JSQ4_Pos) /*!< 0x20000000 */
#define ADC_JSQR_JSQ4_3 (0x08UL << ADC_JSQR_JSQ4_Pos) /*!< 0x40000000 */
#define ADC_JSQR_JSQ4_4 (0x10UL << ADC_JSQR_JSQ4_Pos) /*!< 0x80000000 */
/******************** Bit definition for ADC_OFR1 register ******************/
#define ADC_OFR1_OFFSET1_Pos (0U)
#define ADC_OFR1_OFFSET1_Msk (0xFFFUL << ADC_OFR1_OFFSET1_Pos) /*!< 0x00000FFF */
#define ADC_OFR1_OFFSET1 ADC_OFR1_OFFSET1_Msk /*!< ADC offset number 1 offset level */
#define ADC_OFR1_OFFSETPOS_Pos (24U)
#define ADC_OFR1_OFFSETPOS_Msk (0x1UL << ADC_OFR1_OFFSETPOS_Pos) /*!< 0x01000000 */
#define ADC_OFR1_OFFSETPOS ADC_OFR1_OFFSETPOS_Msk /*!< ADC offset number 1 positive */
#define ADC_OFR1_SATEN_Pos (25U)
#define ADC_OFR1_SATEN_Msk (0x1UL << ADC_OFR1_SATEN_Pos) /*!< 0x02000000 */
#define ADC_OFR1_SATEN ADC_OFR1_SATEN_Msk /*!< ADC offset number 1 saturation enable */
#define ADC_OFR1_OFFSET1_CH_Pos (26U)
#define ADC_OFR1_OFFSET1_CH_Msk (0x1FUL << ADC_OFR1_OFFSET1_CH_Pos) /*!< 0x7C000000 */
#define ADC_OFR1_OFFSET1_CH ADC_OFR1_OFFSET1_CH_Msk /*!< ADC offset number 1 channel selection */
#define ADC_OFR1_OFFSET1_CH_0 (0x01UL << ADC_OFR1_OFFSET1_CH_Pos) /*!< 0x04000000 */
#define ADC_OFR1_OFFSET1_CH_1 (0x02UL << ADC_OFR1_OFFSET1_CH_Pos) /*!< 0x08000000 */
#define ADC_OFR1_OFFSET1_CH_2 (0x04UL << ADC_OFR1_OFFSET1_CH_Pos) /*!< 0x10000000 */
#define ADC_OFR1_OFFSET1_CH_3 (0x08UL << ADC_OFR1_OFFSET1_CH_Pos) /*!< 0x20000000 */
#define ADC_OFR1_OFFSET1_CH_4 (0x10UL << ADC_OFR1_OFFSET1_CH_Pos) /*!< 0x40000000 */
#define ADC_OFR1_OFFSET1_EN_Pos (31U)
#define ADC_OFR1_OFFSET1_EN_Msk (0x1UL << ADC_OFR1_OFFSET1_EN_Pos) /*!< 0x80000000 */
#define ADC_OFR1_OFFSET1_EN ADC_OFR1_OFFSET1_EN_Msk /*!< ADC offset number 1 enable */
/******************** Bit definition for ADC_OFR2 register ******************/
#define ADC_OFR2_OFFSET2_Pos (0U)
#define ADC_OFR2_OFFSET2_Msk (0xFFFUL << ADC_OFR2_OFFSET2_Pos) /*!< 0x00000FFF */
#define ADC_OFR2_OFFSET2 ADC_OFR2_OFFSET2_Msk /*!< ADC offset number 2 offset level */
#define ADC_OFR2_OFFSETPOS_Pos (24U)
#define ADC_OFR2_OFFSETPOS_Msk (0x1UL << ADC_OFR2_OFFSETPOS_Pos) /*!< 0x01000000 */
#define ADC_OFR2_OFFSETPOS ADC_OFR2_OFFSETPOS_Msk /*!< ADC offset number 2 positive */
#define ADC_OFR2_SATEN_Pos (25U)
#define ADC_OFR2_SATEN_Msk (0x1UL << ADC_OFR2_SATEN_Pos) /*!< 0x02000000 */
#define ADC_OFR2_SATEN ADC_OFR2_SATEN_Msk /*!< ADC offset number 2 saturation enable */
#define ADC_OFR2_OFFSET2_CH_Pos (26U)
#define ADC_OFR2_OFFSET2_CH_Msk (0x1FUL << ADC_OFR2_OFFSET2_CH_Pos) /*!< 0x7C000000 */
#define ADC_OFR2_OFFSET2_CH ADC_OFR2_OFFSET2_CH_Msk /*!< ADC offset number 2 channel selection */
#define ADC_OFR2_OFFSET2_CH_0 (0x01UL << ADC_OFR2_OFFSET2_CH_Pos) /*!< 0x04000000 */
#define ADC_OFR2_OFFSET2_CH_1 (0x02UL << ADC_OFR2_OFFSET2_CH_Pos) /*!< 0x08000000 */
#define ADC_OFR2_OFFSET2_CH_2 (0x04UL << ADC_OFR2_OFFSET2_CH_Pos) /*!< 0x10000000 */
#define ADC_OFR2_OFFSET2_CH_3 (0x08UL << ADC_OFR2_OFFSET2_CH_Pos) /*!< 0x20000000 */
#define ADC_OFR2_OFFSET2_CH_4 (0x10UL << ADC_OFR2_OFFSET2_CH_Pos) /*!< 0x40000000 */
#define ADC_OFR2_OFFSET2_EN_Pos (31U)
#define ADC_OFR2_OFFSET2_EN_Msk (0x1UL << ADC_OFR2_OFFSET2_EN_Pos) /*!< 0x80000000 */
#define ADC_OFR2_OFFSET2_EN ADC_OFR2_OFFSET2_EN_Msk /*!< ADC offset number 2 enable */
/******************** Bit definition for ADC_OFR3 register ******************/
#define ADC_OFR3_OFFSET3_Pos (0U)
#define ADC_OFR3_OFFSET3_Msk (0xFFFUL << ADC_OFR3_OFFSET3_Pos) /*!< 0x00000FFF */
#define ADC_OFR3_OFFSET3 ADC_OFR3_OFFSET3_Msk /*!< ADC offset number 3 offset level */
#define ADC_OFR3_OFFSETPOS_Pos (24U)
#define ADC_OFR3_OFFSETPOS_Msk (0x1UL << ADC_OFR3_OFFSETPOS_Pos) /*!< 0x01000000 */
#define ADC_OFR3_OFFSETPOS ADC_OFR3_OFFSETPOS_Msk /*!< ADC offset number 3 positive */
#define ADC_OFR3_SATEN_Pos (25U)
#define ADC_OFR3_SATEN_Msk (0x1UL << ADC_OFR3_SATEN_Pos) /*!< 0x02000000 */
#define ADC_OFR3_SATEN ADC_OFR3_SATEN_Msk /*!< ADC offset number 3 saturation enable */
#define ADC_OFR3_OFFSET3_CH_Pos (26U)
#define ADC_OFR3_OFFSET3_CH_Msk (0x1FUL << ADC_OFR3_OFFSET3_CH_Pos) /*!< 0x7C000000 */
#define ADC_OFR3_OFFSET3_CH ADC_OFR3_OFFSET3_CH_Msk /*!< ADC offset number 3 channel selection */
#define ADC_OFR3_OFFSET3_CH_0 (0x01UL << ADC_OFR3_OFFSET3_CH_Pos) /*!< 0x04000000 */
#define ADC_OFR3_OFFSET3_CH_1 (0x02UL << ADC_OFR3_OFFSET3_CH_Pos) /*!< 0x08000000 */
#define ADC_OFR3_OFFSET3_CH_2 (0x04UL << ADC_OFR3_OFFSET3_CH_Pos) /*!< 0x10000000 */
#define ADC_OFR3_OFFSET3_CH_3 (0x08UL << ADC_OFR3_OFFSET3_CH_Pos) /*!< 0x20000000 */
#define ADC_OFR3_OFFSET3_CH_4 (0x10UL << ADC_OFR3_OFFSET3_CH_Pos) /*!< 0x40000000 */
#define ADC_OFR3_OFFSET3_EN_Pos (31U)
#define ADC_OFR3_OFFSET3_EN_Msk (0x1UL << ADC_OFR3_OFFSET3_EN_Pos) /*!< 0x80000000 */
#define ADC_OFR3_OFFSET3_EN ADC_OFR3_OFFSET3_EN_Msk /*!< ADC offset number 3 enable */
/******************** Bit definition for ADC_OFR4 register ******************/
#define ADC_OFR4_OFFSET4_Pos (0U)
#define ADC_OFR4_OFFSET4_Msk (0xFFFUL << ADC_OFR4_OFFSET4_Pos) /*!< 0x00000FFF */
#define ADC_OFR4_OFFSET4 ADC_OFR4_OFFSET4_Msk /*!< ADC offset number 4 offset level */
#define ADC_OFR4_OFFSETPOS_Pos (24U)
#define ADC_OFR4_OFFSETPOS_Msk (0x1UL << ADC_OFR4_OFFSETPOS_Pos) /*!< 0x01000000 */
#define ADC_OFR4_OFFSETPOS ADC_OFR4_OFFSETPOS_Msk /*!< ADC offset number 4 positive */
#define ADC_OFR4_SATEN_Pos (25U)
#define ADC_OFR4_SATEN_Msk (0x1UL << ADC_OFR4_SATEN_Pos) /*!< 0x02000000 */
#define ADC_OFR4_SATEN ADC_OFR4_SATEN_Msk /*!< ADC offset number 4 saturation enable */
#define ADC_OFR4_OFFSET4_CH_Pos (26U)
#define ADC_OFR4_OFFSET4_CH_Msk (0x1FUL << ADC_OFR4_OFFSET4_CH_Pos) /*!< 0x7C000000 */
#define ADC_OFR4_OFFSET4_CH ADC_OFR4_OFFSET4_CH_Msk /*!< ADC offset number 4 channel selection */
#define ADC_OFR4_OFFSET4_CH_0 (0x01UL << ADC_OFR4_OFFSET4_CH_Pos) /*!< 0x04000000 */
#define ADC_OFR4_OFFSET4_CH_1 (0x02UL << ADC_OFR4_OFFSET4_CH_Pos) /*!< 0x08000000 */
#define ADC_OFR4_OFFSET4_CH_2 (0x04UL << ADC_OFR4_OFFSET4_CH_Pos) /*!< 0x10000000 */
#define ADC_OFR4_OFFSET4_CH_3 (0x08UL << ADC_OFR4_OFFSET4_CH_Pos) /*!< 0x20000000 */
#define ADC_OFR4_OFFSET4_CH_4 (0x10UL << ADC_OFR4_OFFSET4_CH_Pos) /*!< 0x40000000 */
#define ADC_OFR4_OFFSET4_EN_Pos (31U)
#define ADC_OFR4_OFFSET4_EN_Msk (0x1UL << ADC_OFR4_OFFSET4_EN_Pos) /*!< 0x80000000 */
#define ADC_OFR4_OFFSET4_EN ADC_OFR4_OFFSET4_EN_Msk /*!< ADC offset number 4 enable */
/******************** Bit definition for ADC_JDR1 register ******************/
#define ADC_JDR1_JDATA_Pos (0U)
#define ADC_JDR1_JDATA_Msk (0xFFFFUL << ADC_JDR1_JDATA_Pos) /*!< 0x0000FFFF */
#define ADC_JDR1_JDATA ADC_JDR1_JDATA_Msk /*!< ADC group injected sequencer rank 1 conversion data */
/******************** Bit definition for ADC_JDR2 register ******************/
#define ADC_JDR2_JDATA_Pos (0U)
#define ADC_JDR2_JDATA_Msk (0xFFFFUL << ADC_JDR2_JDATA_Pos) /*!< 0x0000FFFF */
#define ADC_JDR2_JDATA ADC_JDR2_JDATA_Msk /*!< ADC group injected sequencer rank 2 conversion data */
/******************** Bit definition for ADC_JDR3 register ******************/
#define ADC_JDR3_JDATA_Pos (0U)
#define ADC_JDR3_JDATA_Msk (0xFFFFUL << ADC_JDR3_JDATA_Pos) /*!< 0x0000FFFF */
#define ADC_JDR3_JDATA ADC_JDR3_JDATA_Msk /*!< ADC group injected sequencer rank 3 conversion data */
/******************** Bit definition for ADC_JDR4 register ******************/
#define ADC_JDR4_JDATA_Pos (0U)
#define ADC_JDR4_JDATA_Msk (0xFFFFUL << ADC_JDR4_JDATA_Pos) /*!< 0x0000FFFF */
#define ADC_JDR4_JDATA ADC_JDR4_JDATA_Msk /*!< ADC group injected sequencer rank 4 conversion data */
/******************** Bit definition for ADC_AWD2CR register ****************/
#define ADC_AWD2CR_AWD2CH_Pos (0U)
#define ADC_AWD2CR_AWD2CH_Msk (0x7FFFFUL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x0007FFFF */
#define ADC_AWD2CR_AWD2CH ADC_AWD2CR_AWD2CH_Msk /*!< ADC analog watchdog 2 monitored channel selection */
#define ADC_AWD2CR_AWD2CH_0 (0x00001UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000001 */
#define ADC_AWD2CR_AWD2CH_1 (0x00002UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000002 */
#define ADC_AWD2CR_AWD2CH_2 (0x00004UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000004 */
#define ADC_AWD2CR_AWD2CH_3 (0x00008UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000008 */
#define ADC_AWD2CR_AWD2CH_4 (0x00010UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000010 */
#define ADC_AWD2CR_AWD2CH_5 (0x00020UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000020 */
#define ADC_AWD2CR_AWD2CH_6 (0x00040UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000040 */
#define ADC_AWD2CR_AWD2CH_7 (0x00080UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000080 */
#define ADC_AWD2CR_AWD2CH_8 (0x00100UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000100 */
#define ADC_AWD2CR_AWD2CH_9 (0x00200UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000200 */
#define ADC_AWD2CR_AWD2CH_10 (0x00400UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000400 */
#define ADC_AWD2CR_AWD2CH_11 (0x00800UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00000800 */
#define ADC_AWD2CR_AWD2CH_12 (0x01000UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00001000 */
#define ADC_AWD2CR_AWD2CH_13 (0x02000UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00002000 */
#define ADC_AWD2CR_AWD2CH_14 (0x04000UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00004000 */
#define ADC_AWD2CR_AWD2CH_15 (0x08000UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00008000 */
#define ADC_AWD2CR_AWD2CH_16 (0x10000UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00010000 */
#define ADC_AWD2CR_AWD2CH_17 (0x20000UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00020000 */
#define ADC_AWD2CR_AWD2CH_18 (0x40000UL << ADC_AWD2CR_AWD2CH_Pos) /*!< 0x00040000 */
/******************** Bit definition for ADC_AWD3CR register ****************/
#define ADC_AWD3CR_AWD3CH_Pos (0U)
#define ADC_AWD3CR_AWD3CH_Msk (0x7FFFFUL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x0007FFFF */
#define ADC_AWD3CR_AWD3CH ADC_AWD3CR_AWD3CH_Msk /*!< ADC analog watchdog 3 monitored channel selection */
#define ADC_AWD3CR_AWD3CH_0 (0x00001UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000001 */
#define ADC_AWD3CR_AWD3CH_1 (0x00002UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000002 */
#define ADC_AWD3CR_AWD3CH_2 (0x00004UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000004 */
#define ADC_AWD3CR_AWD3CH_3 (0x00008UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000008 */
#define ADC_AWD3CR_AWD3CH_4 (0x00010UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000010 */
#define ADC_AWD3CR_AWD3CH_5 (0x00020UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000020 */
#define ADC_AWD3CR_AWD3CH_6 (0x00040UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000040 */
#define ADC_AWD3CR_AWD3CH_7 (0x00080UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000080 */
#define ADC_AWD3CR_AWD3CH_8 (0x00100UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000100 */
#define ADC_AWD3CR_AWD3CH_9 (0x00200UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000200 */
#define ADC_AWD3CR_AWD3CH_10 (0x00400UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000400 */
#define ADC_AWD3CR_AWD3CH_11 (0x00800UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00000800 */
#define ADC_AWD3CR_AWD3CH_12 (0x01000UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00001000 */
#define ADC_AWD3CR_AWD3CH_13 (0x02000UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00002000 */
#define ADC_AWD3CR_AWD3CH_14 (0x04000UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00004000 */
#define ADC_AWD3CR_AWD3CH_15 (0x08000UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00008000 */
#define ADC_AWD3CR_AWD3CH_16 (0x10000UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00010000 */
#define ADC_AWD3CR_AWD3CH_17 (0x20000UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00020000 */
#define ADC_AWD3CR_AWD3CH_18 (0x40000UL << ADC_AWD3CR_AWD3CH_Pos) /*!< 0x00040000 */
/******************** Bit definition for ADC_DIFSEL register ****************/
#define ADC_DIFSEL_DIFSEL_Pos (0U)
#define ADC_DIFSEL_DIFSEL_Msk (0x7FFFFUL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x0007FFFF */
#define ADC_DIFSEL_DIFSEL ADC_DIFSEL_DIFSEL_Msk /*!< ADC channel differential or single-ended mode */
#define ADC_DIFSEL_DIFSEL_0 (0x00001UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000001 */
#define ADC_DIFSEL_DIFSEL_1 (0x00002UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000002 */
#define ADC_DIFSEL_DIFSEL_2 (0x00004UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000004 */
#define ADC_DIFSEL_DIFSEL_3 (0x00008UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000008 */
#define ADC_DIFSEL_DIFSEL_4 (0x00010UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000010 */
#define ADC_DIFSEL_DIFSEL_5 (0x00020UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000020 */
#define ADC_DIFSEL_DIFSEL_6 (0x00040UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000040 */
#define ADC_DIFSEL_DIFSEL_7 (0x00080UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000080 */
#define ADC_DIFSEL_DIFSEL_8 (0x00100UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000100 */
#define ADC_DIFSEL_DIFSEL_9 (0x00200UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000200 */
#define ADC_DIFSEL_DIFSEL_10 (0x00400UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000400 */
#define ADC_DIFSEL_DIFSEL_11 (0x00800UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00000800 */
#define ADC_DIFSEL_DIFSEL_12 (0x01000UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00001000 */
#define ADC_DIFSEL_DIFSEL_13 (0x02000UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00002000 */
#define ADC_DIFSEL_DIFSEL_14 (0x04000UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00004000 */
#define ADC_DIFSEL_DIFSEL_15 (0x08000UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00008000 */
#define ADC_DIFSEL_DIFSEL_16 (0x10000UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00010000 */
#define ADC_DIFSEL_DIFSEL_17 (0x20000UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00020000 */
#define ADC_DIFSEL_DIFSEL_18 (0x40000UL << ADC_DIFSEL_DIFSEL_Pos) /*!< 0x00040000 */
/******************** Bit definition for ADC_CALFACT register ***************/
#define ADC_CALFACT_CALFACT_S_Pos (0U)
#define ADC_CALFACT_CALFACT_S_Msk (0x7FUL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x0000007F */
#define ADC_CALFACT_CALFACT_S ADC_CALFACT_CALFACT_S_Msk /*!< ADC calibration factor in single-ended mode */
#define ADC_CALFACT_CALFACT_S_0 (0x01UL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x00000001 */
#define ADC_CALFACT_CALFACT_S_1 (0x02UL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x00000002 */
#define ADC_CALFACT_CALFACT_S_2 (0x04UL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x00000004 */
#define ADC_CALFACT_CALFACT_S_3 (0x08UL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x00000008 */
#define ADC_CALFACT_CALFACT_S_4 (0x10UL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x00000010 */
#define ADC_CALFACT_CALFACT_S_5 (0x20UL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x00000020 */
#define ADC_CALFACT_CALFACT_S_6 (0x40UL << ADC_CALFACT_CALFACT_S_Pos) /*!< 0x00000030 */
#define ADC_CALFACT_CALFACT_D_Pos (16U)
#define ADC_CALFACT_CALFACT_D_Msk (0x7FUL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x007F0000 */
#define ADC_CALFACT_CALFACT_D ADC_CALFACT_CALFACT_D_Msk /*!< ADC calibration factor in differential mode */
#define ADC_CALFACT_CALFACT_D_0 (0x01UL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x00010000 */
#define ADC_CALFACT_CALFACT_D_1 (0x02UL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x00020000 */
#define ADC_CALFACT_CALFACT_D_2 (0x04UL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x00040000 */
#define ADC_CALFACT_CALFACT_D_3 (0x08UL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x00080000 */
#define ADC_CALFACT_CALFACT_D_4 (0x10UL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x00100000 */
#define ADC_CALFACT_CALFACT_D_5 (0x20UL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x00200000 */
#define ADC_CALFACT_CALFACT_D_6 (0x40UL << ADC_CALFACT_CALFACT_D_Pos) /*!< 0x00300000 */
/******************** Bit definition for ADC_GCOMP register *****************/
#define ADC_GCOMP_GCOMPCOEFF_Pos (0U)
#define ADC_GCOMP_GCOMPCOEFF_Msk (0x3FFFUL << ADC_GCOMP_GCOMPCOEFF_Pos) /*!< 0x00003FFF */
#define ADC_GCOMP_GCOMPCOEFF ADC_GCOMP_GCOMPCOEFF_Msk /*!< ADC Gain Compensation Coefficient */
/************************* ADC Common registers *****************************/
/******************** Bit definition for ADC_CSR register *******************/
#define ADC_CSR_ADRDY_MST_Pos (0U)
#define ADC_CSR_ADRDY_MST_Msk (0x1UL << ADC_CSR_ADRDY_MST_Pos) /*!< 0x00000001 */
#define ADC_CSR_ADRDY_MST ADC_CSR_ADRDY_MST_Msk /*!< ADC multimode master ready flag */
#define ADC_CSR_EOSMP_MST_Pos (1U)
#define ADC_CSR_EOSMP_MST_Msk (0x1UL << ADC_CSR_EOSMP_MST_Pos) /*!< 0x00000002 */
#define ADC_CSR_EOSMP_MST ADC_CSR_EOSMP_MST_Msk /*!< ADC multimode master group regular end of sampling flag */
#define ADC_CSR_EOC_MST_Pos (2U)
#define ADC_CSR_EOC_MST_Msk (0x1UL << ADC_CSR_EOC_MST_Pos) /*!< 0x00000004 */
#define ADC_CSR_EOC_MST ADC_CSR_EOC_MST_Msk /*!< ADC multimode master group regular end of unitary conversion flag */
#define ADC_CSR_EOS_MST_Pos (3U)
#define ADC_CSR_EOS_MST_Msk (0x1UL << ADC_CSR_EOS_MST_Pos) /*!< 0x00000008 */
#define ADC_CSR_EOS_MST ADC_CSR_EOS_MST_Msk /*!< ADC multimode master group regular end of sequence conversions flag */
#define ADC_CSR_OVR_MST_Pos (4U)
#define ADC_CSR_OVR_MST_Msk (0x1UL << ADC_CSR_OVR_MST_Pos) /*!< 0x00000010 */
#define ADC_CSR_OVR_MST ADC_CSR_OVR_MST_Msk /*!< ADC multimode master group regular overrun flag */
#define ADC_CSR_JEOC_MST_Pos (5U)
#define ADC_CSR_JEOC_MST_Msk (0x1UL << ADC_CSR_JEOC_MST_Pos) /*!< 0x00000020 */
#define ADC_CSR_JEOC_MST ADC_CSR_JEOC_MST_Msk /*!< ADC multimode master group injected end of unitary conversion flag */
#define ADC_CSR_JEOS_MST_Pos (6U)
#define ADC_CSR_JEOS_MST_Msk (0x1UL << ADC_CSR_JEOS_MST_Pos) /*!< 0x00000040 */
#define ADC_CSR_JEOS_MST ADC_CSR_JEOS_MST_Msk /*!< ADC multimode master group injected end of sequence conversions flag */
#define ADC_CSR_AWD1_MST_Pos (7U)
#define ADC_CSR_AWD1_MST_Msk (0x1UL << ADC_CSR_AWD1_MST_Pos) /*!< 0x00000080 */
#define ADC_CSR_AWD1_MST ADC_CSR_AWD1_MST_Msk /*!< ADC multimode master analog watchdog 1 flag */
#define ADC_CSR_AWD2_MST_Pos (8U)
#define ADC_CSR_AWD2_MST_Msk (0x1UL << ADC_CSR_AWD2_MST_Pos) /*!< 0x00000100 */
#define ADC_CSR_AWD2_MST ADC_CSR_AWD2_MST_Msk /*!< ADC multimode master analog watchdog 2 flag */
#define ADC_CSR_AWD3_MST_Pos (9U)
#define ADC_CSR_AWD3_MST_Msk (0x1UL << ADC_CSR_AWD3_MST_Pos) /*!< 0x00000200 */
#define ADC_CSR_AWD3_MST ADC_CSR_AWD3_MST_Msk /*!< ADC multimode master analog watchdog 3 flag */
#define ADC_CSR_JQOVF_MST_Pos (10U)
#define ADC_CSR_JQOVF_MST_Msk (0x1UL << ADC_CSR_JQOVF_MST_Pos) /*!< 0x00000400 */
#define ADC_CSR_JQOVF_MST ADC_CSR_JQOVF_MST_Msk /*!< ADC multimode master group injected contexts queue overflow flag */
#define ADC_CSR_ADRDY_SLV_Pos (16U)
#define ADC_CSR_ADRDY_SLV_Msk (0x1UL << ADC_CSR_ADRDY_SLV_Pos) /*!< 0x00010000 */
#define ADC_CSR_ADRDY_SLV ADC_CSR_ADRDY_SLV_Msk /*!< ADC multimode slave ready flag */
#define ADC_CSR_EOSMP_SLV_Pos (17U)
#define ADC_CSR_EOSMP_SLV_Msk (0x1UL << ADC_CSR_EOSMP_SLV_Pos) /*!< 0x00020000 */
#define ADC_CSR_EOSMP_SLV ADC_CSR_EOSMP_SLV_Msk /*!< ADC multimode slave group regular end of sampling flag */
#define ADC_CSR_EOC_SLV_Pos (18U)
#define ADC_CSR_EOC_SLV_Msk (0x1UL << ADC_CSR_EOC_SLV_Pos) /*!< 0x00040000 */
#define ADC_CSR_EOC_SLV ADC_CSR_EOC_SLV_Msk /*!< ADC multimode slave group regular end of unitary conversion flag */
#define ADC_CSR_EOS_SLV_Pos (19U)
#define ADC_CSR_EOS_SLV_Msk (0x1UL << ADC_CSR_EOS_SLV_Pos) /*!< 0x00080000 */
#define ADC_CSR_EOS_SLV ADC_CSR_EOS_SLV_Msk /*!< ADC multimode slave group regular end of sequence conversions flag */
#define ADC_CSR_OVR_SLV_Pos (20U)
#define ADC_CSR_OVR_SLV_Msk (0x1UL << ADC_CSR_OVR_SLV_Pos) /*!< 0x00100000 */
#define ADC_CSR_OVR_SLV ADC_CSR_OVR_SLV_Msk /*!< ADC multimode slave group regular overrun flag */
#define ADC_CSR_JEOC_SLV_Pos (21U)
#define ADC_CSR_JEOC_SLV_Msk (0x1UL << ADC_CSR_JEOC_SLV_Pos) /*!< 0x00200000 */
#define ADC_CSR_JEOC_SLV ADC_CSR_JEOC_SLV_Msk /*!< ADC multimode slave group injected end of unitary conversion flag */
#define ADC_CSR_JEOS_SLV_Pos (22U)
#define ADC_CSR_JEOS_SLV_Msk (0x1UL << ADC_CSR_JEOS_SLV_Pos) /*!< 0x00400000 */
#define ADC_CSR_JEOS_SLV ADC_CSR_JEOS_SLV_Msk /*!< ADC multimode slave group injected end of sequence conversions flag */
#define ADC_CSR_AWD1_SLV_Pos (23U)
#define ADC_CSR_AWD1_SLV_Msk (0x1UL << ADC_CSR_AWD1_SLV_Pos) /*!< 0x00800000 */
#define ADC_CSR_AWD1_SLV ADC_CSR_AWD1_SLV_Msk /*!< ADC multimode slave analog watchdog 1 flag */
#define ADC_CSR_AWD2_SLV_Pos (24U)
#define ADC_CSR_AWD2_SLV_Msk (0x1UL << ADC_CSR_AWD2_SLV_Pos) /*!< 0x01000000 */
#define ADC_CSR_AWD2_SLV ADC_CSR_AWD2_SLV_Msk /*!< ADC multimode slave analog watchdog 2 flag */
#define ADC_CSR_AWD3_SLV_Pos (25U)
#define ADC_CSR_AWD3_SLV_Msk (0x1UL << ADC_CSR_AWD3_SLV_Pos) /*!< 0x02000000 */
#define ADC_CSR_AWD3_SLV ADC_CSR_AWD3_SLV_Msk /*!< ADC multimode slave analog watchdog 3 flag */
#define ADC_CSR_JQOVF_SLV_Pos (26U)
#define ADC_CSR_JQOVF_SLV_Msk (0x1UL << ADC_CSR_JQOVF_SLV_Pos) /*!< 0x04000000 */
#define ADC_CSR_JQOVF_SLV ADC_CSR_JQOVF_SLV_Msk /*!< ADC multimode slave group injected contexts queue overflow flag */
/******************** Bit definition for ADC_CCR register *******************/
#define ADC_CCR_DUAL_Pos (0U)
#define ADC_CCR_DUAL_Msk (0x1FUL << ADC_CCR_DUAL_Pos) /*!< 0x0000001F */
#define ADC_CCR_DUAL ADC_CCR_DUAL_Msk /*!< ADC multimode mode selection */
#define ADC_CCR_DUAL_0 (0x01UL << ADC_CCR_DUAL_Pos) /*!< 0x00000001 */
#define ADC_CCR_DUAL_1 (0x02UL << ADC_CCR_DUAL_Pos) /*!< 0x00000002 */
#define ADC_CCR_DUAL_2 (0x04UL << ADC_CCR_DUAL_Pos) /*!< 0x00000004 */
#define ADC_CCR_DUAL_3 (0x08UL << ADC_CCR_DUAL_Pos) /*!< 0x00000008 */
#define ADC_CCR_DUAL_4 (0x10UL << ADC_CCR_DUAL_Pos) /*!< 0x00000010 */
#define ADC_CCR_DELAY_Pos (8U)
#define ADC_CCR_DELAY_Msk (0xFUL << ADC_CCR_DELAY_Pos) /*!< 0x00000F00 */
#define ADC_CCR_DELAY ADC_CCR_DELAY_Msk /*!< ADC multimode delay between 2 sampling phases */
#define ADC_CCR_DELAY_0 (0x1UL << ADC_CCR_DELAY_Pos) /*!< 0x00000100 */
#define ADC_CCR_DELAY_1 (0x2UL << ADC_CCR_DELAY_Pos) /*!< 0x00000200 */
#define ADC_CCR_DELAY_2 (0x4UL << ADC_CCR_DELAY_Pos) /*!< 0x00000400 */
#define ADC_CCR_DELAY_3 (0x8UL << ADC_CCR_DELAY_Pos) /*!< 0x00000800 */
#define ADC_CCR_DMACFG_Pos (13U)
#define ADC_CCR_DMACFG_Msk (0x1UL << ADC_CCR_DMACFG_Pos) /*!< 0x00002000 */
#define ADC_CCR_DMACFG ADC_CCR_DMACFG_Msk /*!< ADC multimode DMA transfer configuration */
#define ADC_CCR_MDMA_Pos (14U)
#define ADC_CCR_MDMA_Msk (0x3UL << ADC_CCR_MDMA_Pos) /*!< 0x0000C000 */
#define ADC_CCR_MDMA ADC_CCR_MDMA_Msk /*!< ADC multimode DMA transfer enable */
#define ADC_CCR_MDMA_0 (0x1UL << ADC_CCR_MDMA_Pos) /*!< 0x00004000 */
#define ADC_CCR_MDMA_1 (0x2UL << ADC_CCR_MDMA_Pos) /*!< 0x00008000 */
#define ADC_CCR_CKMODE_Pos (16U)
#define ADC_CCR_CKMODE_Msk (0x3UL << ADC_CCR_CKMODE_Pos) /*!< 0x00030000 */
#define ADC_CCR_CKMODE ADC_CCR_CKMODE_Msk /*!< ADC common clock source and prescaler (prescaler only for clock source synchronous) */
#define ADC_CCR_CKMODE_0 (0x1UL << ADC_CCR_CKMODE_Pos) /*!< 0x00010000 */
#define ADC_CCR_CKMODE_1 (0x2UL << ADC_CCR_CKMODE_Pos) /*!< 0x00020000 */
#define ADC_CCR_PRESC_Pos (18U)
#define ADC_CCR_PRESC_Msk (0xFUL << ADC_CCR_PRESC_Pos) /*!< 0x003C0000 */
#define ADC_CCR_PRESC ADC_CCR_PRESC_Msk /*!< ADC common clock prescaler, only for clock source asynchronous */
#define ADC_CCR_PRESC_0 (0x1UL << ADC_CCR_PRESC_Pos) /*!< 0x00040000 */
#define ADC_CCR_PRESC_1 (0x2UL << ADC_CCR_PRESC_Pos) /*!< 0x00080000 */
#define ADC_CCR_PRESC_2 (0x4UL << ADC_CCR_PRESC_Pos) /*!< 0x00100000 */
#define ADC_CCR_PRESC_3 (0x8UL << ADC_CCR_PRESC_Pos) /*!< 0x00200000 */
#define ADC_CCR_VREFEN_Pos (22U)
#define ADC_CCR_VREFEN_Msk (0x1UL << ADC_CCR_VREFEN_Pos) /*!< 0x00400000 */
#define ADC_CCR_VREFEN ADC_CCR_VREFEN_Msk /*!< ADC internal path to VrefInt enable */
#define ADC_CCR_VSENSESEL_Pos (23U)
#define ADC_CCR_VSENSESEL_Msk (0x1UL << ADC_CCR_VSENSESEL_Pos) /*!< 0x00800000 */
#define ADC_CCR_VSENSESEL ADC_CCR_VSENSESEL_Msk /*!< ADC internal path to temperature sensor enable */
#define ADC_CCR_VBATSEL_Pos (24U)
#define ADC_CCR_VBATSEL_Msk (0x1UL << ADC_CCR_VBATSEL_Pos) /*!< 0x01000000 */
#define ADC_CCR_VBATSEL ADC_CCR_VBATSEL_Msk /*!< ADC internal path to battery voltage enable */
/******************** Bit definition for ADC_CDR register *******************/
#define ADC_CDR_RDATA_MST_Pos (0U)
#define ADC_CDR_RDATA_MST_Msk (0xFFFFUL << ADC_CDR_RDATA_MST_Pos) /*!< 0x0000FFFF */
#define ADC_CDR_RDATA_MST ADC_CDR_RDATA_MST_Msk /*!< ADC multimode master group regular conversion data */
#define ADC_CDR_RDATA_SLV_Pos (16U)
#define ADC_CDR_RDATA_SLV_Msk (0xFFFFUL << ADC_CDR_RDATA_SLV_Pos) /*!< 0xFFFF0000 */
#define ADC_CDR_RDATA_SLV ADC_CDR_RDATA_SLV_Msk /*!< ADC multimode slave group regular conversion data */
/******************************************************************************/
/* */
/* Analog Comparators (COMP) */
/* */
/******************************************************************************/
/********************** Bit definition for COMP_CSR register ****************/
#define COMP_CSR_EN_Pos (0U)
#define COMP_CSR_EN_Msk (0x1UL << COMP_CSR_EN_Pos) /*!< 0x00000001 */
#define COMP_CSR_EN COMP_CSR_EN_Msk /*!< Comparator enable */
#define COMP_CSR_INMSEL_Pos (4U)
#define COMP_CSR_INMSEL_Msk (0xFUL << COMP_CSR_INMSEL_Pos) /*!< 0x00000070 */
#define COMP_CSR_INMSEL COMP_CSR_INMSEL_Msk /*!< Comparator input minus selection */
#define COMP_CSR_INMSEL_0 (0x1UL << COMP_CSR_INMSEL_Pos) /*!< 0x00000010 */
#define COMP_CSR_INMSEL_1 (0x2UL << COMP_CSR_INMSEL_Pos) /*!< 0x00000020 */
#define COMP_CSR_INMSEL_2 (0x4UL << COMP_CSR_INMSEL_Pos) /*!< 0x00000040 */
#define COMP_CSR_INMSEL_3 (0x8UL << COMP_CSR_INMSEL_Pos) /*!< 0x00000080 */
#define COMP_CSR_INPSEL_Pos (8U)
#define COMP_CSR_INPSEL_Msk (0x1UL << COMP_CSR_INPSEL_Pos) /*!< 0x00000100 */
#define COMP_CSR_INPSEL COMP_CSR_INPSEL_Msk /*!< Comparator input plus selection */
#define COMP_CSR_POLARITY_Pos (15U)
#define COMP_CSR_POLARITY_Msk (0x1UL << COMP_CSR_POLARITY_Pos) /*!< 0x00008000 */
#define COMP_CSR_POLARITY COMP_CSR_POLARITY_Msk /*!< Comparator output polarity */
#define COMP_CSR_HYST_Pos (16U)
#define COMP_CSR_HYST_Msk (0x7UL << COMP_CSR_HYST_Pos) /*!< 0x00070000 */
#define COMP_CSR_HYST COMP_CSR_HYST_Msk /*!< Comparator hysteresis */
#define COMP_CSR_HYST_0 (0x1UL << COMP_CSR_HYST_Pos) /*!< 0x00010000 */
#define COMP_CSR_HYST_1 (0x2UL << COMP_CSR_HYST_Pos) /*!< 0x00020000 */
#define COMP_CSR_HYST_2 (0x4UL << COMP_CSR_HYST_Pos) /*!< 0x00040000 */
#define COMP_CSR_BLANKING_Pos (19U)
#define COMP_CSR_BLANKING_Msk (0x7UL << COMP_CSR_BLANKING_Pos) /*!< 0x00380000 */
#define COMP_CSR_BLANKING COMP_CSR_BLANKING_Msk /*!< Comparator blanking source */
#define COMP_CSR_BLANKING_0 (0x1UL << COMP_CSR_BLANKING_Pos) /*!< 0x00080000 */
#define COMP_CSR_BLANKING_1 (0x2UL << COMP_CSR_BLANKING_Pos) /*!< 0x00100000 */
#define COMP_CSR_BLANKING_2 (0x4UL << COMP_CSR_BLANKING_Pos) /*!< 0x00200000 */
#define COMP_CSR_BRGEN_Pos (22U)
#define COMP_CSR_BRGEN_Msk (0x1UL << COMP_CSR_BRGEN_Pos) /*!< 0x00400000 */
#define COMP_CSR_BRGEN COMP_CSR_BRGEN_Msk /*!< Comparator scaler bridge enable */
#define COMP_CSR_SCALEN_Pos (23U)
#define COMP_CSR_SCALEN_Msk (0x1UL << COMP_CSR_SCALEN_Pos) /*!< 0x00800000 */
#define COMP_CSR_SCALEN COMP_CSR_SCALEN_Msk /*!< Comparator voltage scaler enable */
#define COMP_CSR_VALUE_Pos (30U)
#define COMP_CSR_VALUE_Msk (0x1UL << COMP_CSR_VALUE_Pos) /*!< 0x40000000 */
#define COMP_CSR_VALUE COMP_CSR_VALUE_Msk /*!< Comparator output level */
#define COMP_CSR_LOCK_Pos (31U)
#define COMP_CSR_LOCK_Msk (0x1UL << COMP_CSR_LOCK_Pos) /*!< 0x80000000 */
#define COMP_CSR_LOCK COMP_CSR_LOCK_Msk /*!< Comparator lock */
/******************************************************************************/
/* */
/* CORDIC calculation unit */
/* */
/******************************************************************************/
/******************* Bit definition for CORDIC_CSR register *****************/
#define CORDIC_CSR_FUNC_Pos (0U)
#define CORDIC_CSR_FUNC_Msk (0xFUL << CORDIC_CSR_FUNC_Pos) /*!< 0x0000000F */
#define CORDIC_CSR_FUNC CORDIC_CSR_FUNC_Msk /*!< Function */
#define CORDIC_CSR_FUNC_0 (0x1UL << CORDIC_CSR_FUNC_Pos) /*!< 0x00000001 */
#define CORDIC_CSR_FUNC_1 (0x2UL << CORDIC_CSR_FUNC_Pos) /*!< 0x00000002 */
#define CORDIC_CSR_FUNC_2 (0x4UL << CORDIC_CSR_FUNC_Pos) /*!< 0x00000004 */
#define CORDIC_CSR_FUNC_3 (0x8UL << CORDIC_CSR_FUNC_Pos) /*!< 0x00000008 */
#define CORDIC_CSR_PRECISION_Pos (4U)
#define CORDIC_CSR_PRECISION_Msk (0xFUL << CORDIC_CSR_PRECISION_Pos) /*!< 0x000000F0 */
#define CORDIC_CSR_PRECISION CORDIC_CSR_PRECISION_Msk /*!< Precision */
#define CORDIC_CSR_PRECISION_0 (0x1UL << CORDIC_CSR_PRECISION_Pos) /*!< 0x00000010 */
#define CORDIC_CSR_PRECISION_1 (0x2UL << CORDIC_CSR_PRECISION_Pos) /*!< 0x00000020 */
#define CORDIC_CSR_PRECISION_2 (0x4UL << CORDIC_CSR_PRECISION_Pos) /*!< 0x00000040 */
#define CORDIC_CSR_PRECISION_3 (0x8UL << CORDIC_CSR_PRECISION_Pos) /*!< 0x00000080 */
#define CORDIC_CSR_SCALE_Pos (8U)
#define CORDIC_CSR_SCALE_Msk (0x7UL << CORDIC_CSR_SCALE_Pos) /*!< 0x00000700 */
#define CORDIC_CSR_SCALE CORDIC_CSR_SCALE_Msk /*!< Scaling factor */
#define CORDIC_CSR_SCALE_0 (0x1UL << CORDIC_CSR_SCALE_Pos) /*!< 0x00000100 */
#define CORDIC_CSR_SCALE_1 (0x2UL << CORDIC_CSR_SCALE_Pos) /*!< 0x00000200 */
#define CORDIC_CSR_SCALE_2 (0x4UL << CORDIC_CSR_SCALE_Pos) /*!< 0x00000400 */
#define CORDIC_CSR_IEN_Pos (16U)
#define CORDIC_CSR_IEN_Msk (0x1UL << CORDIC_CSR_IEN_Pos) /*!< 0x00010000 */
#define CORDIC_CSR_IEN CORDIC_CSR_IEN_Msk /*!< Interrupt Enable */
#define CORDIC_CSR_DMAREN_Pos (17U)
#define CORDIC_CSR_DMAREN_Msk (0x1UL << CORDIC_CSR_DMAREN_Pos) /*!< 0x00020000 */
#define CORDIC_CSR_DMAREN CORDIC_CSR_DMAREN_Msk /*!< DMA Read channel Enable */
#define CORDIC_CSR_DMAWEN_Pos (18U)
#define CORDIC_CSR_DMAWEN_Msk (0x1UL << CORDIC_CSR_DMAWEN_Pos) /*!< 0x00040000 */
#define CORDIC_CSR_DMAWEN CORDIC_CSR_DMAWEN_Msk /*!< DMA Write channel Enable */
#define CORDIC_CSR_NRES_Pos (19U)
#define CORDIC_CSR_NRES_Msk (0x1UL << CORDIC_CSR_NRES_Pos) /*!< 0x00080000 */
#define CORDIC_CSR_NRES CORDIC_CSR_NRES_Msk /*!< Number of results in WDATA register */
#define CORDIC_CSR_NARGS_Pos (20U)
#define CORDIC_CSR_NARGS_Msk (0x1UL << CORDIC_CSR_NARGS_Pos) /*!< 0x00100000 */
#define CORDIC_CSR_NARGS CORDIC_CSR_NARGS_Msk /*!< Number of arguments in RDATA register */
#define CORDIC_CSR_RESSIZE_Pos (21U)
#define CORDIC_CSR_RESSIZE_Msk (0x1UL << CORDIC_CSR_RESSIZE_Pos) /*!< 0x00200000 */
#define CORDIC_CSR_RESSIZE CORDIC_CSR_RESSIZE_Msk /*!< Width of output data */
#define CORDIC_CSR_ARGSIZE_Pos (22U)
#define CORDIC_CSR_ARGSIZE_Msk (0x1UL << CORDIC_CSR_ARGSIZE_Pos) /*!< 0x00400000 */
#define CORDIC_CSR_ARGSIZE CORDIC_CSR_ARGSIZE_Msk /*!< Width of input data */
#define CORDIC_CSR_RRDY_Pos (31U)
#define CORDIC_CSR_RRDY_Msk (0x1UL << CORDIC_CSR_RRDY_Pos) /*!< 0x80000000 */
#define CORDIC_CSR_RRDY CORDIC_CSR_RRDY_Msk /*!< Result Ready Flag */
/******************* Bit definition for CORDIC_WDATA register ***************/
#define CORDIC_WDATA_ARG_Pos (0U)
#define CORDIC_WDATA_ARG_Msk (0xFFFFFFFFUL << CORDIC_WDATA_ARG_Pos) /*!< 0xFFFFFFFF */
#define CORDIC_WDATA_ARG CORDIC_WDATA_ARG_Msk /*!< Input Argument */
/******************* Bit definition for CORDIC_RDATA register ***************/
#define CORDIC_RDATA_RES_Pos (0U)
#define CORDIC_RDATA_RES_Msk (0xFFFFFFFFUL << CORDIC_RDATA_RES_Pos) /*!< 0xFFFFFFFF */
#define CORDIC_RDATA_RES CORDIC_RDATA_RES_Msk /*!< Output Result */
/******************************************************************************/
/* */
/* CRC calculation unit */
/* */
/******************************************************************************/
/******************* Bit definition for CRC_DR register *********************/
#define CRC_DR_DR_Pos (0U)
#define CRC_DR_DR_Msk (0xFFFFFFFFUL << CRC_DR_DR_Pos) /*!< 0xFFFFFFFF */
#define CRC_DR_DR CRC_DR_DR_Msk /*!< Data register bits */
/******************* Bit definition for CRC_IDR register ********************/
#define CRC_IDR_IDR_Pos (0U)
#define CRC_IDR_IDR_Msk (0xFFFFFFFFUL << CRC_IDR_IDR_Pos) /*!< 0xFFFFFFFF */
#define CRC_IDR_IDR CRC_IDR_IDR_Msk /*!< General-purpose 32-bit data register bits */
/******************** Bit definition for CRC_CR register ********************/
#define CRC_CR_RESET_Pos (0U)
#define CRC_CR_RESET_Msk (0x1UL << CRC_CR_RESET_Pos) /*!< 0x00000001 */
#define CRC_CR_RESET CRC_CR_RESET_Msk /*!< RESET the CRC computation unit bit */
#define CRC_CR_POLYSIZE_Pos (3U)
#define CRC_CR_POLYSIZE_Msk (0x3UL << CRC_CR_POLYSIZE_Pos) /*!< 0x00000018 */
#define CRC_CR_POLYSIZE CRC_CR_POLYSIZE_Msk /*!< Polynomial size bits */
#define CRC_CR_POLYSIZE_0 (0x1UL << CRC_CR_POLYSIZE_Pos) /*!< 0x00000008 */
#define CRC_CR_POLYSIZE_1 (0x2UL << CRC_CR_POLYSIZE_Pos) /*!< 0x00000010 */
#define CRC_CR_REV_IN_Pos (5U)
#define CRC_CR_REV_IN_Msk (0x3UL << CRC_CR_REV_IN_Pos) /*!< 0x00000060 */
#define CRC_CR_REV_IN CRC_CR_REV_IN_Msk /*!< REV_IN Reverse Input Data bits */
#define CRC_CR_REV_IN_0 (0x1UL << CRC_CR_REV_IN_Pos) /*!< 0x00000020 */
#define CRC_CR_REV_IN_1 (0x2UL << CRC_CR_REV_IN_Pos) /*!< 0x00000040 */
#define CRC_CR_REV_OUT_Pos (7U)
#define CRC_CR_REV_OUT_Msk (0x1UL << CRC_CR_REV_OUT_Pos) /*!< 0x00000080 */
#define CRC_CR_REV_OUT CRC_CR_REV_OUT_Msk /*!< REV_OUT Reverse Output Data bits */
/******************* Bit definition for CRC_INIT register *******************/
#define CRC_INIT_INIT_Pos (0U)
#define CRC_INIT_INIT_Msk (0xFFFFFFFFUL << CRC_INIT_INIT_Pos) /*!< 0xFFFFFFFF */
#define CRC_INIT_INIT CRC_INIT_INIT_Msk /*!< Initial CRC value bits */
/******************* Bit definition for CRC_POL register ********************/
#define CRC_POL_POL_Pos (0U)
#define CRC_POL_POL_Msk (0xFFFFFFFFUL << CRC_POL_POL_Pos) /*!< 0xFFFFFFFF */
#define CRC_POL_POL CRC_POL_POL_Msk /*!< Coefficients of the polynomial */
/******************************************************************************/
/* */
/* CRS Clock Recovery System */
/******************************************************************************/
/******************* Bit definition for CRS_CR register *********************/
#define CRS_CR_SYNCOKIE_Pos (0U)
#define CRS_CR_SYNCOKIE_Msk (0x1UL << CRS_CR_SYNCOKIE_Pos) /*!< 0x00000001 */
#define CRS_CR_SYNCOKIE CRS_CR_SYNCOKIE_Msk /*!< SYNC event OK interrupt enable */
#define CRS_CR_SYNCWARNIE_Pos (1U)
#define CRS_CR_SYNCWARNIE_Msk (0x1UL << CRS_CR_SYNCWARNIE_Pos) /*!< 0x00000002 */
#define CRS_CR_SYNCWARNIE CRS_CR_SYNCWARNIE_Msk /*!< SYNC warning interrupt enable */
#define CRS_CR_ERRIE_Pos (2U)
#define CRS_CR_ERRIE_Msk (0x1UL << CRS_CR_ERRIE_Pos) /*!< 0x00000004 */
#define CRS_CR_ERRIE CRS_CR_ERRIE_Msk /*!< SYNC error or trimming error interrupt enable */
#define CRS_CR_ESYNCIE_Pos (3U)
#define CRS_CR_ESYNCIE_Msk (0x1UL << CRS_CR_ESYNCIE_Pos) /*!< 0x00000008 */
#define CRS_CR_ESYNCIE CRS_CR_ESYNCIE_Msk /*!< Expected SYNC interrupt enable */
#define CRS_CR_CEN_Pos (5U)
#define CRS_CR_CEN_Msk (0x1UL << CRS_CR_CEN_Pos) /*!< 0x00000020 */
#define CRS_CR_CEN CRS_CR_CEN_Msk /*!< Frequency error counter enable */
#define CRS_CR_AUTOTRIMEN_Pos (6U)
#define CRS_CR_AUTOTRIMEN_Msk (0x1UL << CRS_CR_AUTOTRIMEN_Pos) /*!< 0x00000040 */
#define CRS_CR_AUTOTRIMEN CRS_CR_AUTOTRIMEN_Msk /*!< Automatic trimming enable */
#define CRS_CR_SWSYNC_Pos (7U)
#define CRS_CR_SWSYNC_Msk (0x1UL << CRS_CR_SWSYNC_Pos) /*!< 0x00000080 */
#define CRS_CR_SWSYNC CRS_CR_SWSYNC_Msk /*!< Generate software SYNC event */
#define CRS_CR_TRIM_Pos (8U)
#define CRS_CR_TRIM_Msk (0x7FUL << CRS_CR_TRIM_Pos) /*!< 0x00007F00 */
#define CRS_CR_TRIM CRS_CR_TRIM_Msk /*!< HSI48 oscillator smooth trimming */
/******************* Bit definition for CRS_CFGR register *********************/
#define CRS_CFGR_RELOAD_Pos (0U)
#define CRS_CFGR_RELOAD_Msk (0xFFFFUL << CRS_CFGR_RELOAD_Pos) /*!< 0x0000FFFF */
#define CRS_CFGR_RELOAD CRS_CFGR_RELOAD_Msk /*!< Counter reload value */
#define CRS_CFGR_FELIM_Pos (16U)
#define CRS_CFGR_FELIM_Msk (0xFFUL << CRS_CFGR_FELIM_Pos) /*!< 0x00FF0000 */
#define CRS_CFGR_FELIM CRS_CFGR_FELIM_Msk /*!< Frequency error limit */
#define CRS_CFGR_SYNCDIV_Pos (24U)
#define CRS_CFGR_SYNCDIV_Msk (0x7UL << CRS_CFGR_SYNCDIV_Pos) /*!< 0x07000000 */
#define CRS_CFGR_SYNCDIV CRS_CFGR_SYNCDIV_Msk /*!< SYNC divider */
#define CRS_CFGR_SYNCDIV_0 (0x1UL << CRS_CFGR_SYNCDIV_Pos) /*!< 0x01000000 */
#define CRS_CFGR_SYNCDIV_1 (0x2UL << CRS_CFGR_SYNCDIV_Pos) /*!< 0x02000000 */
#define CRS_CFGR_SYNCDIV_2 (0x4UL << CRS_CFGR_SYNCDIV_Pos) /*!< 0x04000000 */
#define CRS_CFGR_SYNCSRC_Pos (28U)
#define CRS_CFGR_SYNCSRC_Msk (0x3UL << CRS_CFGR_SYNCSRC_Pos) /*!< 0x30000000 */
#define CRS_CFGR_SYNCSRC CRS_CFGR_SYNCSRC_Msk /*!< SYNC signal source selection */
#define CRS_CFGR_SYNCSRC_0 (0x1UL << CRS_CFGR_SYNCSRC_Pos) /*!< 0x10000000 */
#define CRS_CFGR_SYNCSRC_1 (0x2UL << CRS_CFGR_SYNCSRC_Pos) /*!< 0x20000000 */
#define CRS_CFGR_SYNCPOL_Pos (31U)
#define CRS_CFGR_SYNCPOL_Msk (0x1UL << CRS_CFGR_SYNCPOL_Pos) /*!< 0x80000000 */
#define CRS_CFGR_SYNCPOL CRS_CFGR_SYNCPOL_Msk /*!< SYNC polarity selection */
/******************* Bit definition for CRS_ISR register *********************/
#define CRS_ISR_SYNCOKF_Pos (0U)
#define CRS_ISR_SYNCOKF_Msk (0x1UL << CRS_ISR_SYNCOKF_Pos) /*!< 0x00000001 */
#define CRS_ISR_SYNCOKF CRS_ISR_SYNCOKF_Msk /*!< SYNC event OK flag */
#define CRS_ISR_SYNCWARNF_Pos (1U)
#define CRS_ISR_SYNCWARNF_Msk (0x1UL << CRS_ISR_SYNCWARNF_Pos) /*!< 0x00000002 */
#define CRS_ISR_SYNCWARNF CRS_ISR_SYNCWARNF_Msk /*!< SYNC warning flag */
#define CRS_ISR_ERRF_Pos (2U)
#define CRS_ISR_ERRF_Msk (0x1UL << CRS_ISR_ERRF_Pos) /*!< 0x00000004 */
#define CRS_ISR_ERRF CRS_ISR_ERRF_Msk /*!< Error flag */
#define CRS_ISR_ESYNCF_Pos (3U)
#define CRS_ISR_ESYNCF_Msk (0x1UL << CRS_ISR_ESYNCF_Pos) /*!< 0x00000008 */
#define CRS_ISR_ESYNCF CRS_ISR_ESYNCF_Msk /*!< Expected SYNC flag */
#define CRS_ISR_SYNCERR_Pos (8U)
#define CRS_ISR_SYNCERR_Msk (0x1UL << CRS_ISR_SYNCERR_Pos) /*!< 0x00000100 */
#define CRS_ISR_SYNCERR CRS_ISR_SYNCERR_Msk /*!< SYNC error */
#define CRS_ISR_SYNCMISS_Pos (9U)
#define CRS_ISR_SYNCMISS_Msk (0x1UL << CRS_ISR_SYNCMISS_Pos) /*!< 0x00000200 */
#define CRS_ISR_SYNCMISS CRS_ISR_SYNCMISS_Msk /*!< SYNC missed */
#define CRS_ISR_TRIMOVF_Pos (10U)
#define CRS_ISR_TRIMOVF_Msk (0x1UL << CRS_ISR_TRIMOVF_Pos) /*!< 0x00000400 */
#define CRS_ISR_TRIMOVF CRS_ISR_TRIMOVF_Msk /*!< Trimming overflow or underflow */
#define CRS_ISR_FEDIR_Pos (15U)
#define CRS_ISR_FEDIR_Msk (0x1UL << CRS_ISR_FEDIR_Pos) /*!< 0x00008000 */
#define CRS_ISR_FEDIR CRS_ISR_FEDIR_Msk /*!< Frequency error direction */
#define CRS_ISR_FECAP_Pos (16U)
#define CRS_ISR_FECAP_Msk (0xFFFFUL << CRS_ISR_FECAP_Pos) /*!< 0xFFFF0000 */
#define CRS_ISR_FECAP CRS_ISR_FECAP_Msk /*!< Frequency error capture */
/******************* Bit definition for CRS_ICR register *********************/
#define CRS_ICR_SYNCOKC_Pos (0U)
#define CRS_ICR_SYNCOKC_Msk (0x1UL << CRS_ICR_SYNCOKC_Pos) /*!< 0x00000001 */
#define CRS_ICR_SYNCOKC CRS_ICR_SYNCOKC_Msk /*!< SYNC event OK clear flag */
#define CRS_ICR_SYNCWARNC_Pos (1U)
#define CRS_ICR_SYNCWARNC_Msk (0x1UL << CRS_ICR_SYNCWARNC_Pos) /*!< 0x00000002 */
#define CRS_ICR_SYNCWARNC CRS_ICR_SYNCWARNC_Msk /*!< SYNC warning clear flag */
#define CRS_ICR_ERRC_Pos (2U)
#define CRS_ICR_ERRC_Msk (0x1UL << CRS_ICR_ERRC_Pos) /*!< 0x00000004 */
#define CRS_ICR_ERRC CRS_ICR_ERRC_Msk /*!< Error clear flag */
#define CRS_ICR_ESYNCC_Pos (3U)
#define CRS_ICR_ESYNCC_Msk (0x1UL << CRS_ICR_ESYNCC_Pos) /*!< 0x00000008 */
#define CRS_ICR_ESYNCC CRS_ICR_ESYNCC_Msk /*!< Expected SYNC clear flag */
/******************************************************************************/
/* */
/* Digital to Analog Converter */
/* */
/******************************************************************************/
/*
* @brief Specific device feature definitions (not present on all devices in the STM32G4 series)
*/
#define DAC_CHANNEL2_SUPPORT /*!< DAC feature available only on specific devices: DAC channel 2 available */
/******************** Bit definition for DAC_CR register ********************/
#define DAC_CR_EN1_Pos (0U)
#define DAC_CR_EN1_Msk (0x1UL << DAC_CR_EN1_Pos) /*!< 0x00000001 */
#define DAC_CR_EN1 DAC_CR_EN1_Msk /*!<DAC channel1 enable */
#define DAC_CR_TEN1_Pos (1U)
#define DAC_CR_TEN1_Msk (0x1UL << DAC_CR_TEN1_Pos) /*!< 0x00000002 */
#define DAC_CR_TEN1 DAC_CR_TEN1_Msk /*!<DAC channel1 Trigger enable */
#define DAC_CR_TSEL1_Pos (2U)
#define DAC_CR_TSEL1_Msk (0xFUL << DAC_CR_TSEL1_Pos) /*!< 0x0000003C */
#define DAC_CR_TSEL1 DAC_CR_TSEL1_Msk /*!<TSEL1[3:0] (DAC channel1 Trigger selection) */
#define DAC_CR_TSEL1_0 (0x1UL << DAC_CR_TSEL1_Pos) /*!< 0x00000004 */
#define DAC_CR_TSEL1_1 (0x2UL << DAC_CR_TSEL1_Pos) /*!< 0x00000008 */
#define DAC_CR_TSEL1_2 (0x4UL << DAC_CR_TSEL1_Pos) /*!< 0x00000010 */
#define DAC_CR_TSEL1_3 (0x8UL << DAC_CR_TSEL1_Pos) /*!< 0x00000020 */
#define DAC_CR_WAVE1_Pos (6U)
#define DAC_CR_WAVE1_Msk (0x3UL << DAC_CR_WAVE1_Pos) /*!< 0x000000C0 */
#define DAC_CR_WAVE1 DAC_CR_WAVE1_Msk /*!<WAVE1[1:0] (DAC channel1 noise/triangle wave generation enable) */
#define DAC_CR_WAVE1_0 (0x1UL << DAC_CR_WAVE1_Pos) /*!< 0x00000040 */
#define DAC_CR_WAVE1_1 (0x2UL << DAC_CR_WAVE1_Pos) /*!< 0x00000080 */
#define DAC_CR_MAMP1_Pos (8U)
#define DAC_CR_MAMP1_Msk (0xFUL << DAC_CR_MAMP1_Pos) /*!< 0x00000F00 */
#define DAC_CR_MAMP1 DAC_CR_MAMP1_Msk /*!<MAMP1[3:0] (DAC channel1 Mask/Amplitude selector) */
#define DAC_CR_MAMP1_0 (0x1UL << DAC_CR_MAMP1_Pos) /*!< 0x00000100 */
#define DAC_CR_MAMP1_1 (0x2UL << DAC_CR_MAMP1_Pos) /*!< 0x00000200 */
#define DAC_CR_MAMP1_2 (0x4UL << DAC_CR_MAMP1_Pos) /*!< 0x00000400 */
#define DAC_CR_MAMP1_3 (0x8UL << DAC_CR_MAMP1_Pos) /*!< 0x00000800 */
#define DAC_CR_DMAEN1_Pos (12U)
#define DAC_CR_DMAEN1_Msk (0x1UL << DAC_CR_DMAEN1_Pos) /*!< 0x00001000 */
#define DAC_CR_DMAEN1 DAC_CR_DMAEN1_Msk /*!<DAC channel1 DMA enable */
#define DAC_CR_DMAUDRIE1_Pos (13U)
#define DAC_CR_DMAUDRIE1_Msk (0x1UL << DAC_CR_DMAUDRIE1_Pos) /*!< 0x00002000 */
#define DAC_CR_DMAUDRIE1 DAC_CR_DMAUDRIE1_Msk /*!<DAC channel 1 DMA underrun interrupt enable >*/
#define DAC_CR_CEN1_Pos (14U)
#define DAC_CR_CEN1_Msk (0x1UL << DAC_CR_CEN1_Pos) /*!< 0x00004000 */
#define DAC_CR_CEN1 DAC_CR_CEN1_Msk /*!<DAC channel 1 calibration enable >*/
#define DAC_CR_HFSEL_Pos (15U)
#define DAC_CR_HFSEL_Msk (0x1UL << DAC_CR_HFSEL_Pos) /*!< 0x00008000 */
#define DAC_CR_HFSEL DAC_CR_HFSEL_Msk /*!<DAC channel 1 and 2 high frequency mode enable >*/
#define DAC_CR_EN2_Pos (16U)
#define DAC_CR_EN2_Msk (0x1UL << DAC_CR_EN2_Pos) /*!< 0x00010000 */
#define DAC_CR_EN2 DAC_CR_EN2_Msk /*!<DAC channel2 enable */
#define DAC_CR_TEN2_Pos (17U)
#define DAC_CR_TEN2_Msk (0x1UL << DAC_CR_TEN2_Pos) /*!< 0x00020000 */
#define DAC_CR_TEN2 DAC_CR_TEN2_Msk /*!<DAC channel2 Trigger enable */
#define DAC_CR_TSEL2_Pos (18U)
#define DAC_CR_TSEL2_Msk (0xFUL << DAC_CR_TSEL2_Pos) /*!< 0x003C0000 */
#define DAC_CR_TSEL2 DAC_CR_TSEL2_Msk /*!<TSEL2[3:0] (DAC channel2 Trigger selection) */
#define DAC_CR_TSEL2_0 (0x1UL << DAC_CR_TSEL2_Pos) /*!< 0x00040000 */
#define DAC_CR_TSEL2_1 (0x2UL << DAC_CR_TSEL2_Pos) /*!< 0x00080000 */
#define DAC_CR_TSEL2_2 (0x4UL << DAC_CR_TSEL2_Pos) /*!< 0x00100000 */
#define DAC_CR_TSEL2_3 (0x8UL << DAC_CR_TSEL2_Pos) /*!< 0x00200000 */
#define DAC_CR_WAVE2_Pos (22U)
#define DAC_CR_WAVE2_Msk (0x3UL << DAC_CR_WAVE2_Pos) /*!< 0x00C00000 */
#define DAC_CR_WAVE2 DAC_CR_WAVE2_Msk /*!<WAVE2[1:0] (DAC channel2 noise/triangle wave generation enable) */
#define DAC_CR_WAVE2_0 (0x1UL << DAC_CR_WAVE2_Pos) /*!< 0x00400000 */
#define DAC_CR_WAVE2_1 (0x2UL << DAC_CR_WAVE2_Pos) /*!< 0x00800000 */
#define DAC_CR_MAMP2_Pos (24U)
#define DAC_CR_MAMP2_Msk (0xFUL << DAC_CR_MAMP2_Pos) /*!< 0x0F000000 */
#define DAC_CR_MAMP2 DAC_CR_MAMP2_Msk /*!<MAMP2[3:0] (DAC channel2 Mask/Amplitude selector) */
#define DAC_CR_MAMP2_0 (0x1UL << DAC_CR_MAMP2_Pos) /*!< 0x01000000 */
#define DAC_CR_MAMP2_1 (0x2UL << DAC_CR_MAMP2_Pos) /*!< 0x02000000 */
#define DAC_CR_MAMP2_2 (0x4UL << DAC_CR_MAMP2_Pos) /*!< 0x04000000 */
#define DAC_CR_MAMP2_3 (0x8UL << DAC_CR_MAMP2_Pos) /*!< 0x08000000 */
#define DAC_CR_DMAEN2_Pos (28U)
#define DAC_CR_DMAEN2_Msk (0x1UL << DAC_CR_DMAEN2_Pos) /*!< 0x10000000 */
#define DAC_CR_DMAEN2 DAC_CR_DMAEN2_Msk /*!<DAC channel2 DMA enabled */
#define DAC_CR_DMAUDRIE2_Pos (29U)
#define DAC_CR_DMAUDRIE2_Msk (0x1UL << DAC_CR_DMAUDRIE2_Pos) /*!< 0x20000000 */
#define DAC_CR_DMAUDRIE2 DAC_CR_DMAUDRIE2_Msk /*!<DAC channel2 DMA underrun interrupt enable >*/
#define DAC_CR_CEN2_Pos (30U)
#define DAC_CR_CEN2_Msk (0x1UL << DAC_CR_CEN2_Pos) /*!< 0x40000000 */
#define DAC_CR_CEN2 DAC_CR_CEN2_Msk /*!<DAC channel2 calibration enable >*/
/***************** Bit definition for DAC_SWTRIGR register ******************/
#define DAC_SWTRIGR_SWTRIG1_Pos (0U)
#define DAC_SWTRIGR_SWTRIG1_Msk (0x1UL << DAC_SWTRIGR_SWTRIG1_Pos) /*!< 0x00000001 */
#define DAC_SWTRIGR_SWTRIG1 DAC_SWTRIGR_SWTRIG1_Msk /*!<DAC channel1 software trigger */
#define DAC_SWTRIGR_SWTRIG2_Pos (1U)
#define DAC_SWTRIGR_SWTRIG2_Msk (0x1UL << DAC_SWTRIGR_SWTRIG2_Pos) /*!< 0x00000002 */
#define DAC_SWTRIGR_SWTRIG2 DAC_SWTRIGR_SWTRIG2_Msk /*!<DAC channel2 software trigger */
#define DAC_SWTRIGR_SWTRIGB1_Pos (16U)
#define DAC_SWTRIGR_SWTRIGB1_Msk (0x1UL << DAC_SWTRIGR_SWTRIGB1_Pos) /*!< 0x00010000 */
#define DAC_SWTRIGR_SWTRIGB1 DAC_SWTRIGR_SWTRIGB1_Msk /*!<DAC channel1 software trigger B */
#define DAC_SWTRIGR_SWTRIGB2_Pos (17U)
#define DAC_SWTRIGR_SWTRIGB2_Msk (0x1UL << DAC_SWTRIGR_SWTRIGB2_Pos) /*!< 0x00020000 */
#define DAC_SWTRIGR_SWTRIGB2 DAC_SWTRIGR_SWTRIGB2_Msk /*!<DAC channel2 software trigger B */
/***************** Bit definition for DAC_DHR12R1 register ******************/
#define DAC_DHR12R1_DACC1DHR_Pos (0U)
#define DAC_DHR12R1_DACC1DHR_Msk (0xFFFUL << DAC_DHR12R1_DACC1DHR_Pos) /*!< 0x00000FFF */
#define DAC_DHR12R1_DACC1DHR DAC_DHR12R1_DACC1DHR_Msk /*!<DAC channel1 12-bit Right aligned data */
#define DAC_DHR12R1_DACC1DHRB_Pos (16U)
#define DAC_DHR12R1_DACC1DHRB_Msk (0xFFFUL << DAC_DHR12R1_DACC1DHRB_Pos) /*!< 0x0FFF0000 */
#define DAC_DHR12R1_DACC1DHRB DAC_DHR12R1_DACC1DHRB_Msk /*!<DAC channel1 12-bit Right-aligned data B */
/***************** Bit definition for DAC_DHR12L1 register ******************/
#define DAC_DHR12L1_DACC1DHR_Pos (4U)
#define DAC_DHR12L1_DACC1DHR_Msk (0xFFFUL << DAC_DHR12L1_DACC1DHR_Pos) /*!< 0x0000FFF0 */
#define DAC_DHR12L1_DACC1DHR DAC_DHR12L1_DACC1DHR_Msk /*!<DAC channel1 12-bit Left aligned data */
#define DAC_DHR12L1_DACC1DHRB_Pos (20U)
#define DAC_DHR12L1_DACC1DHRB_Msk (0xFFFUL << DAC_DHR12L1_DACC1DHRB_Pos) /*!< 0xFFF00000 */
#define DAC_DHR12L1_DACC1DHRB DAC_DHR12L1_DACC1DHRB_Msk /*!<DAC channel1 12-bit Left aligned data B */
/****************** Bit definition for DAC_DHR8R1 register ******************/
#define DAC_DHR8R1_DACC1DHR_Pos (0U)
#define DAC_DHR8R1_DACC1DHR_Msk (0xFFUL << DAC_DHR8R1_DACC1DHR_Pos) /*!< 0x000000FF */
#define DAC_DHR8R1_DACC1DHR DAC_DHR8R1_DACC1DHR_Msk /*!<DAC channel1 8-bit Right aligned data */
#define DAC_DHR8R1_DACC1DHRB_Pos (8U)
#define DAC_DHR8R1_DACC1DHRB_Msk (0xFFUL << DAC_DHR8R1_DACC1DHRB_Pos) /*!< 0x0000FF00 */
#define DAC_DHR8R1_DACC1DHRB DAC_DHR8R1_DACC1DHRB_Msk /*!<DAC channel1 8-bit Right aligned data B */
/***************** Bit definition for DAC_DHR12R2 register ******************/
#define DAC_DHR12R2_DACC2DHR_Pos (0U)
#define DAC_DHR12R2_DACC2DHR_Msk (0xFFFUL << DAC_DHR12R2_DACC2DHR_Pos) /*!< 0x00000FFF */
#define DAC_DHR12R2_DACC2DHR DAC_DHR12R2_DACC2DHR_Msk /*!<DAC channel2 12-bit Right aligned data */
#define DAC_DHR12R2_DACC2DHRB_Pos (16U)
#define DAC_DHR12R2_DACC2DHRB_Msk (0xFFFUL << DAC_DHR12R2_DACC2DHRB_Pos) /*!< 0x0FFF0000 */
#define DAC_DHR12R2_DACC2DHRB DAC_DHR12R2_DACC2DHRB_Msk /*!<DAC channel2 12-bit Right-aligned data B */
/***************** Bit definition for DAC_DHR12L2 register ******************/
#define DAC_DHR12L2_DACC2DHR_Pos (4U)
#define DAC_DHR12L2_DACC2DHR_Msk (0xFFFUL << DAC_DHR12L2_DACC2DHR_Pos) /*!< 0x0000FFF0 */
#define DAC_DHR12L2_DACC2DHR DAC_DHR12L2_DACC2DHR_Msk /*!<DAC channel2 12-bit Left aligned data */
#define DAC_DHR12L2_DACC2DHRB_Pos (20U)
#define DAC_DHR12L2_DACC2DHRB_Msk (0xFFFUL << DAC_DHR12L2_DACC2DHRB_Pos) /*!< 0xFFF00000 */
#define DAC_DHR12L2_DACC2DHRB DAC_DHR12L2_DACC2DHRB_Msk /*!<DAC channel2 12-bit Left aligned data B */
/****************** Bit definition for DAC_DHR8R2 register ******************/
#define DAC_DHR8R2_DACC2DHR_Pos (0U)
#define DAC_DHR8R2_DACC2DHR_Msk (0xFFUL << DAC_DHR8R2_DACC2DHR_Pos) /*!< 0x000000FF */
#define DAC_DHR8R2_DACC2DHR DAC_DHR8R2_DACC2DHR_Msk /*!<DAC channel2 8-bit Right aligned data */
#define DAC_DHR8R2_DACC2DHRB_Pos (8U)
#define DAC_DHR8R2_DACC2DHRB_Msk (0xFFUL << DAC_DHR8R2_DACC2DHRB_Pos) /*!< 0x0000FF00 */
#define DAC_DHR8R2_DACC2DHRB DAC_DHR8R2_DACC2DHRB_Msk /*!<DAC channel2 8-bit Right aligned data B */
/***************** Bit definition for DAC_DHR12RD register ******************/
#define DAC_DHR12RD_DACC1DHR_Pos (0U)
#define DAC_DHR12RD_DACC1DHR_Msk (0xFFFUL << DAC_DHR12RD_DACC1DHR_Pos) /*!< 0x00000FFF */
#define DAC_DHR12RD_DACC1DHR DAC_DHR12RD_DACC1DHR_Msk /*!<DAC channel1 12-bit Right aligned data */
#define DAC_DHR12RD_DACC2DHR_Pos (16U)
#define DAC_DHR12RD_DACC2DHR_Msk (0xFFFUL << DAC_DHR12RD_DACC2DHR_Pos) /*!< 0x0FFF0000 */
#define DAC_DHR12RD_DACC2DHR DAC_DHR12RD_DACC2DHR_Msk /*!<DAC channel2 12-bit Right aligned data */
/***************** Bit definition for DAC_DHR12LD register ******************/
#define DAC_DHR12LD_DACC1DHR_Pos (4U)
#define DAC_DHR12LD_DACC1DHR_Msk (0xFFFUL << DAC_DHR12LD_DACC1DHR_Pos) /*!< 0x0000FFF0 */
#define DAC_DHR12LD_DACC1DHR DAC_DHR12LD_DACC1DHR_Msk /*!<DAC channel1 12-bit Left aligned data */
#define DAC_DHR12LD_DACC2DHR_Pos (20U)
#define DAC_DHR12LD_DACC2DHR_Msk (0xFFFUL << DAC_DHR12LD_DACC2DHR_Pos) /*!< 0xFFF00000 */
#define DAC_DHR12LD_DACC2DHR DAC_DHR12LD_DACC2DHR_Msk /*!<DAC channel2 12-bit Left aligned data */
/****************** Bit definition for DAC_DHR8RD register ******************/
#define DAC_DHR8RD_DACC1DHR_Pos (0U)
#define DAC_DHR8RD_DACC1DHR_Msk (0xFFUL << DAC_DHR8RD_DACC1DHR_Pos) /*!< 0x000000FF */
#define DAC_DHR8RD_DACC1DHR DAC_DHR8RD_DACC1DHR_Msk /*!<DAC channel1 8-bit Right aligned data */
#define DAC_DHR8RD_DACC2DHR_Pos (8U)
#define DAC_DHR8RD_DACC2DHR_Msk (0xFFUL << DAC_DHR8RD_DACC2DHR_Pos) /*!< 0x0000FF00 */
#define DAC_DHR8RD_DACC2DHR DAC_DHR8RD_DACC2DHR_Msk /*!<DAC channel2 8-bit Right aligned data */
/******************* Bit definition for DAC_DOR1 register *******************/
#define DAC_DOR1_DACC1DOR_Pos (0U)
#define DAC_DOR1_DACC1DOR_Msk (0xFFFUL << DAC_DOR1_DACC1DOR_Pos) /*!< 0x00000FFF */
#define DAC_DOR1_DACC1DOR DAC_DOR1_DACC1DOR_Msk /*!<DAC channel1 data output */
#define DAC_DOR1_DACC1DORB_Pos (16U)
#define DAC_DOR1_DACC1DORB_Msk (0xFFFUL << DAC_DOR1_DACC1DORB_Pos) /*!< 0x0FFF0000 */
#define DAC_DOR1_DACC1DORB DAC_DOR1_DACC1DORB_Msk /*!<DAC channel1 data output B */
/******************* Bit definition for DAC_DOR2 register *******************/
#define DAC_DOR2_DACC2DOR_Pos (0U)
#define DAC_DOR2_DACC2DOR_Msk (0xFFFUL << DAC_DOR2_DACC2DOR_Pos) /*!< 0x00000FFF */
#define DAC_DOR2_DACC2DOR DAC_DOR2_DACC2DOR_Msk /*!<DAC channel2 data output */
#define DAC_DOR2_DACC2DORB_Pos (16U)
#define DAC_DOR2_DACC2DORB_Msk (0xFFFUL << DAC_DOR2_DACC2DORB_Pos) /*!< 0x0FFF0000 */
#define DAC_DOR2_DACC2DORB DAC_DOR2_DACC2DORB_Msk /*!<DAC channel2 data output B */
/******************** Bit definition for DAC_SR register ********************/
#define DAC_SR_DAC1RDY_Pos (11U)
#define DAC_SR_DAC1RDY_Msk (0x1UL << DAC_SR_DAC1RDY_Pos) /*!< 0x00000800 */
#define DAC_SR_DAC1RDY DAC_SR_DAC1RDY_Msk /*!<DAC channel 1 ready status bit */
#define DAC_SR_DORSTAT1_Pos (12U)
#define DAC_SR_DORSTAT1_Msk (0x1UL << DAC_SR_DORSTAT1_Pos) /*!< 0x00001000 */
#define DAC_SR_DORSTAT1 DAC_SR_DORSTAT1_Msk /*!<DAC channel 1 output register status bit */
#define DAC_SR_DMAUDR1_Pos (13U)
#define DAC_SR_DMAUDR1_Msk (0x1UL << DAC_SR_DMAUDR1_Pos) /*!< 0x00002000 */
#define DAC_SR_DMAUDR1 DAC_SR_DMAUDR1_Msk /*!<DAC channel1 DMA underrun flag */
#define DAC_SR_CAL_FLAG1_Pos (14U)
#define DAC_SR_CAL_FLAG1_Msk (0x1UL << DAC_SR_CAL_FLAG1_Pos) /*!< 0x00004000 */
#define DAC_SR_CAL_FLAG1 DAC_SR_CAL_FLAG1_Msk /*!<DAC channel1 calibration offset status */
#define DAC_SR_BWST1_Pos (15U)
#define DAC_SR_BWST1_Msk (0x1UL << DAC_SR_BWST1_Pos) /*!< 0x00008000 */
#define DAC_SR_BWST1 DAC_SR_BWST1_Msk /*!<DAC channel1 busy writing sample time flag */
#define DAC_SR_DAC2RDY_Pos (27U)
#define DAC_SR_DAC2RDY_Msk (0x1UL << DAC_SR_DAC2RDY_Pos) /*!< 0x08000000 */
#define DAC_SR_DAC2RDY DAC_SR_DAC2RDY_Msk /*!<DAC channel 2 ready status bit */
#define DAC_SR_DORSTAT2_Pos (28U)
#define DAC_SR_DORSTAT2_Msk (0x1UL << DAC_SR_DORSTAT2_Pos) /*!< 0x10000000 */
#define DAC_SR_DORSTAT2 DAC_SR_DORSTAT2_Msk /*!<DAC channel 2 output register status bit */
#define DAC_SR_DMAUDR2_Pos (29U)
#define DAC_SR_DMAUDR2_Msk (0x1UL << DAC_SR_DMAUDR2_Pos) /*!< 0x20000000 */
#define DAC_SR_DMAUDR2 DAC_SR_DMAUDR2_Msk /*!<DAC channel2 DMA underrun flag */
#define DAC_SR_CAL_FLAG2_Pos (30U)
#define DAC_SR_CAL_FLAG2_Msk (0x1UL << DAC_SR_CAL_FLAG2_Pos) /*!< 0x40000000 */
#define DAC_SR_CAL_FLAG2 DAC_SR_CAL_FLAG2_Msk /*!<DAC channel2 calibration offset status */
#define DAC_SR_BWST2_Pos (31U)
#define DAC_SR_BWST2_Msk (0x1UL << DAC_SR_BWST2_Pos) /*!< 0x80000000 */
#define DAC_SR_BWST2 DAC_SR_BWST2_Msk /*!<DAC channel2 busy writing sample time flag */
/******************* Bit definition for DAC_CCR register ********************/
#define DAC_CCR_OTRIM1_Pos (0U)
#define DAC_CCR_OTRIM1_Msk (0x1FUL << DAC_CCR_OTRIM1_Pos) /*!< 0x0000001F */
#define DAC_CCR_OTRIM1 DAC_CCR_OTRIM1_Msk /*!<DAC channel1 offset trimming value */
#define DAC_CCR_OTRIM2_Pos (16U)
#define DAC_CCR_OTRIM2_Msk (0x1FUL << DAC_CCR_OTRIM2_Pos) /*!< 0x001F0000 */
#define DAC_CCR_OTRIM2 DAC_CCR_OTRIM2_Msk /*!<DAC channel2 offset trimming value */
/******************* Bit definition for DAC_MCR register *******************/
#define DAC_MCR_MODE1_Pos (0U)
#define DAC_MCR_MODE1_Msk (0x7UL << DAC_MCR_MODE1_Pos) /*!< 0x00000007 */
#define DAC_MCR_MODE1 DAC_MCR_MODE1_Msk /*!<MODE1[2:0] (DAC channel1 mode) */
#define DAC_MCR_MODE1_0 (0x1UL << DAC_MCR_MODE1_Pos) /*!< 0x00000001 */
#define DAC_MCR_MODE1_1 (0x2UL << DAC_MCR_MODE1_Pos) /*!< 0x00000002 */
#define DAC_MCR_MODE1_2 (0x4UL << DAC_MCR_MODE1_Pos) /*!< 0x00000004 */
#define DAC_MCR_DMADOUBLE1_Pos (8U)
#define DAC_MCR_DMADOUBLE1_Msk (0x1UL << DAC_MCR_DMADOUBLE1_Pos) /*!< 0x00000100 */
#define DAC_MCR_DMADOUBLE1 DAC_MCR_DMADOUBLE1_Msk /*!<DAC Channel 1 DMA double data mode */
#define DAC_MCR_SINFORMAT1_Pos (9U)
#define DAC_MCR_SINFORMAT1_Msk (0x1UL << DAC_MCR_SINFORMAT1_Pos) /*!< 0x00000200 */
#define DAC_MCR_SINFORMAT1 DAC_MCR_SINFORMAT1_Msk /*!<DAC Channel 1 enable signed format */
#define DAC_MCR_HFSEL_Pos (14U)
#define DAC_MCR_HFSEL_Msk (0x3UL << DAC_MCR_HFSEL_Pos) /*!< 0x0000C000 */
#define DAC_MCR_HFSEL DAC_MCR_HFSEL_Msk /*!<HFSEL[1:0] (High Frequency interface mode selection) */
#define DAC_MCR_HFSEL_0 (0x1UL << DAC_MCR_HFSEL_Pos) /*!< 0x00004000 */
#define DAC_MCR_HFSEL_1 (0x2UL << DAC_MCR_HFSEL_Pos) /*!< 0x00008000 */
#define DAC_MCR_MODE2_Pos (16U)
#define DAC_MCR_MODE2_Msk (0x7UL << DAC_MCR_MODE2_Pos) /*!< 0x00070000 */
#define DAC_MCR_MODE2 DAC_MCR_MODE2_Msk /*!<MODE2[2:0] (DAC channel2 mode) */
#define DAC_MCR_MODE2_0 (0x1UL << DAC_MCR_MODE2_Pos) /*!< 0x00010000 */
#define DAC_MCR_MODE2_1 (0x2UL << DAC_MCR_MODE2_Pos) /*!< 0x00020000 */
#define DAC_MCR_MODE2_2 (0x4UL << DAC_MCR_MODE2_Pos) /*!< 0x00040000 */
#define DAC_MCR_DMADOUBLE2_Pos (24U)
#define DAC_MCR_DMADOUBLE2_Msk (0x1UL << DAC_MCR_DMADOUBLE2_Pos) /*!< 0x01000000 */
#define DAC_MCR_DMADOUBLE2 DAC_MCR_DMADOUBLE2_Msk /*!<DAC Channel 2 DMA double data mode */
#define DAC_MCR_SINFORMAT2_Pos (25U)
#define DAC_MCR_SINFORMAT2_Msk (0x1UL << DAC_MCR_SINFORMAT2_Pos) /*!< 0x02000000 */
#define DAC_MCR_SINFORMAT2 DAC_MCR_SINFORMAT2_Msk /*!<DAC Channel 2 enable signed format */
/****************** Bit definition for DAC_SHSR1 register ******************/
#define DAC_SHSR1_TSAMPLE1_Pos (0U)
#define DAC_SHSR1_TSAMPLE1_Msk (0x3FFUL << DAC_SHSR1_TSAMPLE1_Pos) /*!< 0x000003FF */
#define DAC_SHSR1_TSAMPLE1 DAC_SHSR1_TSAMPLE1_Msk /*!<DAC channel1 sample time */
/****************** Bit definition for DAC_SHSR2 register ******************/
#define DAC_SHSR2_TSAMPLE2_Pos (0U)
#define DAC_SHSR2_TSAMPLE2_Msk (0x3FFUL << DAC_SHSR2_TSAMPLE2_Pos) /*!< 0x000003FF */
#define DAC_SHSR2_TSAMPLE2 DAC_SHSR2_TSAMPLE2_Msk /*!<DAC channel2 sample time */
/****************** Bit definition for DAC_SHHR register ******************/
#define DAC_SHHR_THOLD1_Pos (0U)
#define DAC_SHHR_THOLD1_Msk (0x3FFUL << DAC_SHHR_THOLD1_Pos) /*!< 0x000003FF */
#define DAC_SHHR_THOLD1 DAC_SHHR_THOLD1_Msk /*!<DAC channel1 hold time */
#define DAC_SHHR_THOLD2_Pos (16U)
#define DAC_SHHR_THOLD2_Msk (0x3FFUL << DAC_SHHR_THOLD2_Pos) /*!< 0x03FF0000 */
#define DAC_SHHR_THOLD2 DAC_SHHR_THOLD2_Msk /*!<DAC channel2 hold time */
/****************** Bit definition for DAC_SHRR register ******************/
#define DAC_SHRR_TREFRESH1_Pos (0U)
#define DAC_SHRR_TREFRESH1_Msk (0xFFUL << DAC_SHRR_TREFRESH1_Pos) /*!< 0x000000FF */
#define DAC_SHRR_TREFRESH1 DAC_SHRR_TREFRESH1_Msk /*!<DAC channel1 refresh time */
#define DAC_SHRR_TREFRESH2_Pos (16U)
#define DAC_SHRR_TREFRESH2_Msk (0xFFUL << DAC_SHRR_TREFRESH2_Pos) /*!< 0x00FF0000 */
#define DAC_SHRR_TREFRESH2 DAC_SHRR_TREFRESH2_Msk /*!<DAC channel2 refresh time */
/****************** Bit definition for DAC_STR1 register ******************/
#define DAC_STR1_STRSTDATA1_Pos (0U)
#define DAC_STR1_STRSTDATA1_Msk (0xFFFUL << DAC_STR1_STRSTDATA1_Pos) /*!< 0x00000FFF */
#define DAC_STR1_STRSTDATA1 DAC_STR1_STRSTDATA1_Msk /*!<DAC Channel 1 Sawtooth starting value */
#define DAC_STR1_STDIR1_Pos (12U)
#define DAC_STR1_STDIR1_Msk (0x1UL << DAC_STR1_STDIR1_Pos) /*!< 0x00001000 */
#define DAC_STR1_STDIR1 DAC_STR1_STDIR1_Msk /*!<DAC Channel 1 Sawtooth direction setting */
#define DAC_STR1_STINCDATA1_Pos (16U)
#define DAC_STR1_STINCDATA1_Msk (0xFFFFUL << DAC_STR1_STINCDATA1_Pos) /*!< 0xFFFF0000 */
#define DAC_STR1_STINCDATA1 DAC_STR1_STINCDATA1_Msk /*!<DAC Channel 1 Sawtooth increment value (12.4 bit format) */
/****************** Bit definition for DAC_STR2 register ******************/
#define DAC_STR2_STRSTDATA2_Pos (0U)
#define DAC_STR2_STRSTDATA2_Msk (0xFFFUL << DAC_STR2_STRSTDATA2_Pos) /*!< 0x00000FFF */
#define DAC_STR2_STRSTDATA2 DAC_STR2_STRSTDATA2_Msk /*!<DAC Channel 2 Sawtooth starting value */
#define DAC_STR2_STDIR2_Pos (12U)
#define DAC_STR2_STDIR2_Msk (0x1UL << DAC_STR2_STDIR2_Pos) /*!< 0x00001000 */
#define DAC_STR2_STDIR2 DAC_STR2_STDIR2_Msk /*!<DAC Channel 2 Sawtooth direction setting */
#define DAC_STR2_STINCDATA2_Pos (16U)
#define DAC_STR2_STINCDATA2_Msk (0xFFFFUL << DAC_STR2_STINCDATA2_Pos) /*!< 0xFFFF0000 */
#define DAC_STR2_STINCDATA2 DAC_STR2_STINCDATA2_Msk /*!<DAC Channel 2 Sawtooth increment value (12.4 bit format) */
/****************** Bit definition for DAC_STMODR register ****************/
#define DAC_STMODR_STRSTTRIGSEL1_Pos (0U)
#define DAC_STMODR_STRSTTRIGSEL1_Msk (0xFUL << DAC_STMODR_STRSTTRIGSEL1_Pos) /*!< 0x0000000F */
#define DAC_STMODR_STRSTTRIGSEL1 DAC_STMODR_STRSTTRIGSEL1_Msk /*!<STRSTTRIGSEL1[3:0] (DAC Channel 1 Sawtooth Increment trigger selection) */
#define DAC_STMODR_STRSTTRIGSEL1_0 (0x1UL << DAC_STMODR_STRSTTRIGSEL1_Pos) /*!< 0x00000001 */
#define DAC_STMODR_STRSTTRIGSEL1_1 (0x2UL << DAC_STMODR_STRSTTRIGSEL1_Pos) /*!< 0x00000002 */
#define DAC_STMODR_STRSTTRIGSEL1_2 (0x4UL << DAC_STMODR_STRSTTRIGSEL1_Pos) /*!< 0x00000004 */
#define DAC_STMODR_STRSTTRIGSEL1_3 (0x8UL << DAC_STMODR_STRSTTRIGSEL1_Pos) /*!< 0x00000008 */
#define DAC_STMODR_STINCTRIGSEL1_Pos (8U)
#define DAC_STMODR_STINCTRIGSEL1_Msk (0xFUL << DAC_STMODR_STINCTRIGSEL1_Pos) /*!< 0x0000000F */
#define DAC_STMODR_STINCTRIGSEL1 DAC_STMODR_STINCTRIGSEL1_Msk /*!<STINCTRIGSEL1[3:0] (DAC Channel 1 Sawtooth Increment trigger selection) */
#define DAC_STMODR_STINCTRIGSEL1_0 (0x1UL << DAC_STMODR_STINCTRIGSEL1_Pos) /*!< 0x00000001 */
#define DAC_STMODR_STINCTRIGSEL1_1 (0x2UL << DAC_STMODR_STINCTRIGSEL1_Pos) /*!< 0x00000002 */
#define DAC_STMODR_STINCTRIGSEL1_2 (0x4UL << DAC_STMODR_STINCTRIGSEL1_Pos) /*!< 0x00000004 */
#define DAC_STMODR_STINCTRIGSEL1_3 (0x8UL << DAC_STMODR_STINCTRIGSEL1_Pos) /*!< 0x00000008 */
#define DAC_STMODR_STRSTTRIGSEL2_Pos (16U)
#define DAC_STMODR_STRSTTRIGSEL2_Msk (0xFUL << DAC_STMODR_STRSTTRIGSEL2_Pos) /*!< 0x0000000F */
#define DAC_STMODR_STRSTTRIGSEL2 DAC_STMODR_STRSTTRIGSEL2_Msk /*!<STRSTTRIGSEL2[3:0] (DAC Channel 2 Sawtooth Increment trigger selection) */
#define DAC_STMODR_STRSTTRIGSEL2_0 (0x1UL << DAC_STMODR_STRSTTRIGSEL2_Pos) /*!< 0x00000001 */
#define DAC_STMODR_STRSTTRIGSEL2_1 (0x2UL << DAC_STMODR_STRSTTRIGSEL2_Pos) /*!< 0x00000002 */
#define DAC_STMODR_STRSTTRIGSEL2_2 (0x4UL << DAC_STMODR_STRSTTRIGSEL2_Pos) /*!< 0x00000004 */
#define DAC_STMODR_STRSTTRIGSEL2_3 (0x8UL << DAC_STMODR_STRSTTRIGSEL2_Pos) /*!< 0x00000008 */
#define DAC_STMODR_STINCTRIGSEL2_Pos (24U)
#define DAC_STMODR_STINCTRIGSEL2_Msk (0xFUL << DAC_STMODR_STINCTRIGSEL2_Pos) /*!< 0x0000000F */
#define DAC_STMODR_STINCTRIGSEL2 DAC_STMODR_STINCTRIGSEL2_Msk /*!<STINCTRIGSEL2[3:0] (DAC Channel 2 Sawtooth Increment trigger selection) */
#define DAC_STMODR_STINCTRIGSEL2_0 (0x1UL << DAC_STMODR_STINCTRIGSEL2_Pos) /*!< 0x00000001 */
#define DAC_STMODR_STINCTRIGSEL2_1 (0x2UL << DAC_STMODR_STINCTRIGSEL2_Pos) /*!< 0x00000002 */
#define DAC_STMODR_STINCTRIGSEL2_2 (0x4UL << DAC_STMODR_STINCTRIGSEL2_Pos) /*!< 0x00000004 */
#define DAC_STMODR_STINCTRIGSEL2_3 (0x8UL << DAC_STMODR_STINCTRIGSEL2_Pos) /*!< 0x00000008 */
/******************************************************************************/
/* */
/* Debug MCU */
/* */
/******************************************************************************/
/******************** Bit definition for DBGMCU_IDCODE register *************/
#define DBGMCU_IDCODE_DEV_ID_Pos (0U)
#define DBGMCU_IDCODE_DEV_ID_Msk (0xFFFUL << DBGMCU_IDCODE_DEV_ID_Pos)/*!< 0x00000FFF */
#define DBGMCU_IDCODE_DEV_ID DBGMCU_IDCODE_DEV_ID_Msk
#define DBGMCU_IDCODE_REV_ID_Pos (16U)
#define DBGMCU_IDCODE_REV_ID_Msk (0xFFFFUL << DBGMCU_IDCODE_REV_ID_Pos)/*!< 0xFFFF0000 */
#define DBGMCU_IDCODE_REV_ID DBGMCU_IDCODE_REV_ID_Msk
/******************** Bit definition for DBGMCU_CR register *****************/
#define DBGMCU_CR_DBG_SLEEP_Pos (0U)
#define DBGMCU_CR_DBG_SLEEP_Msk (0x1UL << DBGMCU_CR_DBG_SLEEP_Pos)/*!< 0x00000001 */
#define DBGMCU_CR_DBG_SLEEP DBGMCU_CR_DBG_SLEEP_Msk
#define DBGMCU_CR_DBG_STOP_Pos (1U)
#define DBGMCU_CR_DBG_STOP_Msk (0x1UL << DBGMCU_CR_DBG_STOP_Pos)/*!< 0x00000002 */
#define DBGMCU_CR_DBG_STOP DBGMCU_CR_DBG_STOP_Msk
#define DBGMCU_CR_DBG_STANDBY_Pos (2U)
#define DBGMCU_CR_DBG_STANDBY_Msk (0x1UL << DBGMCU_CR_DBG_STANDBY_Pos)/*!< 0x00000004 */
#define DBGMCU_CR_DBG_STANDBY DBGMCU_CR_DBG_STANDBY_Msk
#define DBGMCU_CR_TRACE_IOEN_Pos (5U)
#define DBGMCU_CR_TRACE_IOEN_Msk (0x1UL << DBGMCU_CR_TRACE_IOEN_Pos)/*!< 0x00000020 */
#define DBGMCU_CR_TRACE_IOEN DBGMCU_CR_TRACE_IOEN_Msk
#define DBGMCU_CR_TRACE_MODE_Pos (6U)
#define DBGMCU_CR_TRACE_MODE_Msk (0x3UL << DBGMCU_CR_TRACE_MODE_Pos)/*!< 0x000000C0 */
#define DBGMCU_CR_TRACE_MODE DBGMCU_CR_TRACE_MODE_Msk
#define DBGMCU_CR_TRACE_MODE_0 (0x1UL << DBGMCU_CR_TRACE_MODE_Pos)/*!< 0x00000040 */
#define DBGMCU_CR_TRACE_MODE_1 (0x2UL << DBGMCU_CR_TRACE_MODE_Pos)/*!< 0x00000080 */
/******************** Bit definition for DBGMCU_APB1FZR1 register ***********/
#define DBGMCU_APB1FZR1_DBG_TIM2_STOP_Pos (0U)
#define DBGMCU_APB1FZR1_DBG_TIM2_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_TIM2_STOP_Pos)/*!< 0x00000001 */
#define DBGMCU_APB1FZR1_DBG_TIM2_STOP DBGMCU_APB1FZR1_DBG_TIM2_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_TIM3_STOP_Pos (1U)
#define DBGMCU_APB1FZR1_DBG_TIM3_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_TIM3_STOP_Pos)/*!< 0x00000002 */
#define DBGMCU_APB1FZR1_DBG_TIM3_STOP DBGMCU_APB1FZR1_DBG_TIM3_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_TIM4_STOP_Pos (2U)
#define DBGMCU_APB1FZR1_DBG_TIM4_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_TIM4_STOP_Pos)/*!< 0x00000004 */
#define DBGMCU_APB1FZR1_DBG_TIM4_STOP DBGMCU_APB1FZR1_DBG_TIM4_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_TIM6_STOP_Pos (4U)
#define DBGMCU_APB1FZR1_DBG_TIM6_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_TIM6_STOP_Pos)/*!< 0x00000010 */
#define DBGMCU_APB1FZR1_DBG_TIM6_STOP DBGMCU_APB1FZR1_DBG_TIM6_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_TIM7_STOP_Pos (5U)
#define DBGMCU_APB1FZR1_DBG_TIM7_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_TIM7_STOP_Pos)/*!< 0x00000020 */
#define DBGMCU_APB1FZR1_DBG_TIM7_STOP DBGMCU_APB1FZR1_DBG_TIM7_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_RTC_STOP_Pos (10U)
#define DBGMCU_APB1FZR1_DBG_RTC_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_RTC_STOP_Pos)/*!< 0x00000400 */
#define DBGMCU_APB1FZR1_DBG_RTC_STOP DBGMCU_APB1FZR1_DBG_RTC_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_WWDG_STOP_Pos (11U)
#define DBGMCU_APB1FZR1_DBG_WWDG_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_WWDG_STOP_Pos)/*!< 0x00000800 */
#define DBGMCU_APB1FZR1_DBG_WWDG_STOP DBGMCU_APB1FZR1_DBG_WWDG_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_IWDG_STOP_Pos (12U)
#define DBGMCU_APB1FZR1_DBG_IWDG_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_IWDG_STOP_Pos)/*!< 0x00001000 */
#define DBGMCU_APB1FZR1_DBG_IWDG_STOP DBGMCU_APB1FZR1_DBG_IWDG_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_I2C1_STOP_Pos (21U)
#define DBGMCU_APB1FZR1_DBG_I2C1_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_I2C1_STOP_Pos)/*!< 0x00200000 */
#define DBGMCU_APB1FZR1_DBG_I2C1_STOP DBGMCU_APB1FZR1_DBG_I2C1_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_I2C2_STOP_Pos (22U)
#define DBGMCU_APB1FZR1_DBG_I2C2_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_I2C2_STOP_Pos)/*!< 0x00400000 */
#define DBGMCU_APB1FZR1_DBG_I2C2_STOP DBGMCU_APB1FZR1_DBG_I2C2_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_I2C3_STOP_Pos (30U)
#define DBGMCU_APB1FZR1_DBG_I2C3_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_I2C3_STOP_Pos)/*!< 0x40000000 */
#define DBGMCU_APB1FZR1_DBG_I2C3_STOP DBGMCU_APB1FZR1_DBG_I2C3_STOP_Msk
#define DBGMCU_APB1FZR1_DBG_LPTIM1_STOP_Pos (31U)
#define DBGMCU_APB1FZR1_DBG_LPTIM1_STOP_Msk (0x1UL << DBGMCU_APB1FZR1_DBG_LPTIM1_STOP_Pos)/*!< 0x80000000 */
#define DBGMCU_APB1FZR1_DBG_LPTIM1_STOP DBGMCU_APB1FZR1_DBG_LPTIM1_STOP_Msk
/******************** Bit definition for DBGMCU_APB2FZ register ************/
#define DBGMCU_APB2FZ_DBG_TIM1_STOP_Pos (11U)
#define DBGMCU_APB2FZ_DBG_TIM1_STOP_Msk (0x1UL << DBGMCU_APB2FZ_DBG_TIM1_STOP_Pos)/*!< 0x00000800 */
#define DBGMCU_APB2FZ_DBG_TIM1_STOP DBGMCU_APB2FZ_DBG_TIM1_STOP_Msk
#define DBGMCU_APB2FZ_DBG_TIM8_STOP_Pos (13U)
#define DBGMCU_APB2FZ_DBG_TIM8_STOP_Msk (0x1UL << DBGMCU_APB2FZ_DBG_TIM8_STOP_Pos)/*!< 0x00002000 */
#define DBGMCU_APB2FZ_DBG_TIM8_STOP DBGMCU_APB2FZ_DBG_TIM8_STOP_Msk
#define DBGMCU_APB2FZ_DBG_TIM15_STOP_Pos (16U)
#define DBGMCU_APB2FZ_DBG_TIM15_STOP_Msk (0x1UL << DBGMCU_APB2FZ_DBG_TIM15_STOP_Pos)/*!< 0x00010000 */
#define DBGMCU_APB2FZ_DBG_TIM15_STOP DBGMCU_APB2FZ_DBG_TIM15_STOP_Msk
#define DBGMCU_APB2FZ_DBG_TIM16_STOP_Pos (17U)
#define DBGMCU_APB2FZ_DBG_TIM16_STOP_Msk (0x1UL << DBGMCU_APB2FZ_DBG_TIM16_STOP_Pos)/*!< 0x00020000 */
#define DBGMCU_APB2FZ_DBG_TIM16_STOP DBGMCU_APB2FZ_DBG_TIM16_STOP_Msk
#define DBGMCU_APB2FZ_DBG_TIM17_STOP_Pos (18U)
#define DBGMCU_APB2FZ_DBG_TIM17_STOP_Msk (0x1UL << DBGMCU_APB2FZ_DBG_TIM17_STOP_Pos)/*!< 0x00040000 */
#define DBGMCU_APB2FZ_DBG_TIM17_STOP DBGMCU_APB2FZ_DBG_TIM17_STOP_Msk
/******************************************************************************/
/* */
/* DMA Controller (DMA) */
/* */
/******************************************************************************/
/******************* Bit definition for DMA_ISR register ********************/
#define DMA_ISR_GIF1_Pos (0U)
#define DMA_ISR_GIF1_Msk (0x1UL << DMA_ISR_GIF1_Pos) /*!< 0x00000001 */
#define DMA_ISR_GIF1 DMA_ISR_GIF1_Msk /*!< Channel 1 Global interrupt flag */
#define DMA_ISR_TCIF1_Pos (1U)
#define DMA_ISR_TCIF1_Msk (0x1UL << DMA_ISR_TCIF1_Pos) /*!< 0x00000002 */
#define DMA_ISR_TCIF1 DMA_ISR_TCIF1_Msk /*!< Channel 1 Transfer Complete flag */
#define DMA_ISR_HTIF1_Pos (2U)
#define DMA_ISR_HTIF1_Msk (0x1UL << DMA_ISR_HTIF1_Pos) /*!< 0x00000004 */
#define DMA_ISR_HTIF1 DMA_ISR_HTIF1_Msk /*!< Channel 1 Half Transfer flag */
#define DMA_ISR_TEIF1_Pos (3U)
#define DMA_ISR_TEIF1_Msk (0x1UL << DMA_ISR_TEIF1_Pos) /*!< 0x00000008 */
#define DMA_ISR_TEIF1 DMA_ISR_TEIF1_Msk /*!< Channel 1 Transfer Error flag */
#define DMA_ISR_GIF2_Pos (4U)
#define DMA_ISR_GIF2_Msk (0x1UL << DMA_ISR_GIF2_Pos) /*!< 0x00000010 */
#define DMA_ISR_GIF2 DMA_ISR_GIF2_Msk /*!< Channel 2 Global interrupt flag */
#define DMA_ISR_TCIF2_Pos (5U)
#define DMA_ISR_TCIF2_Msk (0x1UL << DMA_ISR_TCIF2_Pos) /*!< 0x00000020 */
#define DMA_ISR_TCIF2 DMA_ISR_TCIF2_Msk /*!< Channel 2 Transfer Complete flag */
#define DMA_ISR_HTIF2_Pos (6U)
#define DMA_ISR_HTIF2_Msk (0x1UL << DMA_ISR_HTIF2_Pos) /*!< 0x00000040 */
#define DMA_ISR_HTIF2 DMA_ISR_HTIF2_Msk /*!< Channel 2 Half Transfer flag */
#define DMA_ISR_TEIF2_Pos (7U)
#define DMA_ISR_TEIF2_Msk (0x1UL << DMA_ISR_TEIF2_Pos) /*!< 0x00000080 */
#define DMA_ISR_TEIF2 DMA_ISR_TEIF2_Msk /*!< Channel 2 Transfer Error flag */
#define DMA_ISR_GIF3_Pos (8U)
#define DMA_ISR_GIF3_Msk (0x1UL << DMA_ISR_GIF3_Pos) /*!< 0x00000100 */
#define DMA_ISR_GIF3 DMA_ISR_GIF3_Msk /*!< Channel 3 Global interrupt flag */
#define DMA_ISR_TCIF3_Pos (9U)
#define DMA_ISR_TCIF3_Msk (0x1UL << DMA_ISR_TCIF3_Pos) /*!< 0x00000200 */
#define DMA_ISR_TCIF3 DMA_ISR_TCIF3_Msk /*!< Channel 3 Transfer Complete flag */
#define DMA_ISR_HTIF3_Pos (10U)
#define DMA_ISR_HTIF3_Msk (0x1UL << DMA_ISR_HTIF3_Pos) /*!< 0x00000400 */
#define DMA_ISR_HTIF3 DMA_ISR_HTIF3_Msk /*!< Channel 3 Half Transfer flag */
#define DMA_ISR_TEIF3_Pos (11U)
#define DMA_ISR_TEIF3_Msk (0x1UL << DMA_ISR_TEIF3_Pos) /*!< 0x00000800 */
#define DMA_ISR_TEIF3 DMA_ISR_TEIF3_Msk /*!< Channel 3 Transfer Error flag */
#define DMA_ISR_GIF4_Pos (12U)
#define DMA_ISR_GIF4_Msk (0x1UL << DMA_ISR_GIF4_Pos) /*!< 0x00001000 */
#define DMA_ISR_GIF4 DMA_ISR_GIF4_Msk /*!< Channel 4 Global interrupt flag */
#define DMA_ISR_TCIF4_Pos (13U)
#define DMA_ISR_TCIF4_Msk (0x1UL << DMA_ISR_TCIF4_Pos) /*!< 0x00002000 */
#define DMA_ISR_TCIF4 DMA_ISR_TCIF4_Msk /*!< Channel 4 Transfer Complete flag */
#define DMA_ISR_HTIF4_Pos (14U)
#define DMA_ISR_HTIF4_Msk (0x1UL << DMA_ISR_HTIF4_Pos) /*!< 0x00004000 */
#define DMA_ISR_HTIF4 DMA_ISR_HTIF4_Msk /*!< Channel 4 Half Transfer flag */
#define DMA_ISR_TEIF4_Pos (15U)
#define DMA_ISR_TEIF4_Msk (0x1UL << DMA_ISR_TEIF4_Pos) /*!< 0x00008000 */
#define DMA_ISR_TEIF4 DMA_ISR_TEIF4_Msk /*!< Channel 4 Transfer Error flag */
#define DMA_ISR_GIF5_Pos (16U)
#define DMA_ISR_GIF5_Msk (0x1UL << DMA_ISR_GIF5_Pos) /*!< 0x00010000 */
#define DMA_ISR_GIF5 DMA_ISR_GIF5_Msk /*!< Channel 5 Global interrupt flag */
#define DMA_ISR_TCIF5_Pos (17U)
#define DMA_ISR_TCIF5_Msk (0x1UL << DMA_ISR_TCIF5_Pos) /*!< 0x00020000 */
#define DMA_ISR_TCIF5 DMA_ISR_TCIF5_Msk /*!< Channel 5 Transfer Complete flag */
#define DMA_ISR_HTIF5_Pos (18U)
#define DMA_ISR_HTIF5_Msk (0x1UL << DMA_ISR_HTIF5_Pos) /*!< 0x00040000 */
#define DMA_ISR_HTIF5 DMA_ISR_HTIF5_Msk /*!< Channel 5 Half Transfer flag */
#define DMA_ISR_TEIF5_Pos (19U)
#define DMA_ISR_TEIF5_Msk (0x1UL << DMA_ISR_TEIF5_Pos) /*!< 0x00080000 */
#define DMA_ISR_TEIF5 DMA_ISR_TEIF5_Msk /*!< Channel 5 Transfer Error flag */
#define DMA_ISR_GIF6_Pos (20U)
#define DMA_ISR_GIF6_Msk (0x1UL << DMA_ISR_GIF6_Pos) /*!< 0x00100000 */
#define DMA_ISR_GIF6 DMA_ISR_GIF6_Msk /*!< Channel 6 Global interrupt flag */
#define DMA_ISR_TCIF6_Pos (21U)
#define DMA_ISR_TCIF6_Msk (0x1UL << DMA_ISR_TCIF6_Pos) /*!< 0x00200000 */
#define DMA_ISR_TCIF6 DMA_ISR_TCIF6_Msk /*!< Channel 6 Transfer Complete flag */
#define DMA_ISR_HTIF6_Pos (22U)
#define DMA_ISR_HTIF6_Msk (0x1UL << DMA_ISR_HTIF6_Pos) /*!< 0x00400000 */
#define DMA_ISR_HTIF6 DMA_ISR_HTIF6_Msk /*!< Channel 6 Half Transfer flag */
#define DMA_ISR_TEIF6_Pos (23U)
#define DMA_ISR_TEIF6_Msk (0x1UL << DMA_ISR_TEIF6_Pos) /*!< 0x00800000 */
#define DMA_ISR_TEIF6 DMA_ISR_TEIF6_Msk /*!< Channel 6 Transfer Error flag */
/******************* Bit definition for DMA_IFCR register *******************/
#define DMA_IFCR_CGIF1_Pos (0U)
#define DMA_IFCR_CGIF1_Msk (0x1UL << DMA_IFCR_CGIF1_Pos) /*!< 0x00000001 */
#define DMA_IFCR_CGIF1 DMA_IFCR_CGIF1_Msk /*!< Channel 1 Global interrupt clearr */
#define DMA_IFCR_CTCIF1_Pos (1U)
#define DMA_IFCR_CTCIF1_Msk (0x1UL << DMA_IFCR_CTCIF1_Pos) /*!< 0x00000002 */
#define DMA_IFCR_CTCIF1 DMA_IFCR_CTCIF1_Msk /*!< Channel 1 Transfer Complete clear */
#define DMA_IFCR_CHTIF1_Pos (2U)
#define DMA_IFCR_CHTIF1_Msk (0x1UL << DMA_IFCR_CHTIF1_Pos) /*!< 0x00000004 */
#define DMA_IFCR_CHTIF1 DMA_IFCR_CHTIF1_Msk /*!< Channel 1 Half Transfer clear */
#define DMA_IFCR_CTEIF1_Pos (3U)
#define DMA_IFCR_CTEIF1_Msk (0x1UL << DMA_IFCR_CTEIF1_Pos) /*!< 0x00000008 */
#define DMA_IFCR_CTEIF1 DMA_IFCR_CTEIF1_Msk /*!< Channel 1 Transfer Error clear */
#define DMA_IFCR_CGIF2_Pos (4U)
#define DMA_IFCR_CGIF2_Msk (0x1UL << DMA_IFCR_CGIF2_Pos) /*!< 0x00000010 */
#define DMA_IFCR_CGIF2 DMA_IFCR_CGIF2_Msk /*!< Channel 2 Global interrupt clear */
#define DMA_IFCR_CTCIF2_Pos (5U)
#define DMA_IFCR_CTCIF2_Msk (0x1UL << DMA_IFCR_CTCIF2_Pos) /*!< 0x00000020 */
#define DMA_IFCR_CTCIF2 DMA_IFCR_CTCIF2_Msk /*!< Channel 2 Transfer Complete clear */
#define DMA_IFCR_CHTIF2_Pos (6U)
#define DMA_IFCR_CHTIF2_Msk (0x1UL << DMA_IFCR_CHTIF2_Pos) /*!< 0x00000040 */
#define DMA_IFCR_CHTIF2 DMA_IFCR_CHTIF2_Msk /*!< Channel 2 Half Transfer clear */
#define DMA_IFCR_CTEIF2_Pos (7U)
#define DMA_IFCR_CTEIF2_Msk (0x1UL << DMA_IFCR_CTEIF2_Pos) /*!< 0x00000080 */
#define DMA_IFCR_CTEIF2 DMA_IFCR_CTEIF2_Msk /*!< Channel 2 Transfer Error clear */
#define DMA_IFCR_CGIF3_Pos (8U)
#define DMA_IFCR_CGIF3_Msk (0x1UL << DMA_IFCR_CGIF3_Pos) /*!< 0x00000100 */
#define DMA_IFCR_CGIF3 DMA_IFCR_CGIF3_Msk /*!< Channel 3 Global interrupt clear */
#define DMA_IFCR_CTCIF3_Pos (9U)
#define DMA_IFCR_CTCIF3_Msk (0x1UL << DMA_IFCR_CTCIF3_Pos) /*!< 0x00000200 */
#define DMA_IFCR_CTCIF3 DMA_IFCR_CTCIF3_Msk /*!< Channel 3 Transfer Complete clear */
#define DMA_IFCR_CHTIF3_Pos (10U)
#define DMA_IFCR_CHTIF3_Msk (0x1UL << DMA_IFCR_CHTIF3_Pos) /*!< 0x00000400 */
#define DMA_IFCR_CHTIF3 DMA_IFCR_CHTIF3_Msk /*!< Channel 3 Half Transfer clear */
#define DMA_IFCR_CTEIF3_Pos (11U)
#define DMA_IFCR_CTEIF3_Msk (0x1UL << DMA_IFCR_CTEIF3_Pos) /*!< 0x00000800 */
#define DMA_IFCR_CTEIF3 DMA_IFCR_CTEIF3_Msk /*!< Channel 3 Transfer Error clear */
#define DMA_IFCR_CGIF4_Pos (12U)
#define DMA_IFCR_CGIF4_Msk (0x1UL << DMA_IFCR_CGIF4_Pos) /*!< 0x00001000 */
#define DMA_IFCR_CGIF4 DMA_IFCR_CGIF4_Msk /*!< Channel 4 Global interrupt clear */
#define DMA_IFCR_CTCIF4_Pos (13U)
#define DMA_IFCR_CTCIF4_Msk (0x1UL << DMA_IFCR_CTCIF4_Pos) /*!< 0x00002000 */
#define DMA_IFCR_CTCIF4 DMA_IFCR_CTCIF4_Msk /*!< Channel 4 Transfer Complete clear */
#define DMA_IFCR_CHTIF4_Pos (14U)
#define DMA_IFCR_CHTIF4_Msk (0x1UL << DMA_IFCR_CHTIF4_Pos) /*!< 0x00004000 */
#define DMA_IFCR_CHTIF4 DMA_IFCR_CHTIF4_Msk /*!< Channel 4 Half Transfer clear */
#define DMA_IFCR_CTEIF4_Pos (15U)
#define DMA_IFCR_CTEIF4_Msk (0x1UL << DMA_IFCR_CTEIF4_Pos) /*!< 0x00008000 */
#define DMA_IFCR_CTEIF4 DMA_IFCR_CTEIF4_Msk /*!< Channel 4 Transfer Error clear */
#define DMA_IFCR_CGIF5_Pos (16U)
#define DMA_IFCR_CGIF5_Msk (0x1UL << DMA_IFCR_CGIF5_Pos) /*!< 0x00010000 */
#define DMA_IFCR_CGIF5 DMA_IFCR_CGIF5_Msk /*!< Channel 5 Global interrupt clear */
#define DMA_IFCR_CTCIF5_Pos (17U)
#define DMA_IFCR_CTCIF5_Msk (0x1UL << DMA_IFCR_CTCIF5_Pos) /*!< 0x00020000 */
#define DMA_IFCR_CTCIF5 DMA_IFCR_CTCIF5_Msk /*!< Channel 5 Transfer Complete clear */
#define DMA_IFCR_CHTIF5_Pos (18U)
#define DMA_IFCR_CHTIF5_Msk (0x1UL << DMA_IFCR_CHTIF5_Pos) /*!< 0x00040000 */
#define DMA_IFCR_CHTIF5 DMA_IFCR_CHTIF5_Msk /*!< Channel 5 Half Transfer clear */
#define DMA_IFCR_CTEIF5_Pos (19U)
#define DMA_IFCR_CTEIF5_Msk (0x1UL << DMA_IFCR_CTEIF5_Pos) /*!< 0x00080000 */
#define DMA_IFCR_CTEIF5 DMA_IFCR_CTEIF5_Msk /*!< Channel 5 Transfer Error clear */
#define DMA_IFCR_CGIF6_Pos (20U)
#define DMA_IFCR_CGIF6_Msk (0x1UL << DMA_IFCR_CGIF6_Pos) /*!< 0x00100000 */
#define DMA_IFCR_CGIF6 DMA_IFCR_CGIF6_Msk /*!< Channel 6 Global interrupt clear */
#define DMA_IFCR_CTCIF6_Pos (21U)
#define DMA_IFCR_CTCIF6_Msk (0x1UL << DMA_IFCR_CTCIF6_Pos) /*!< 0x00200000 */
#define DMA_IFCR_CTCIF6 DMA_IFCR_CTCIF6_Msk /*!< Channel 6 Transfer Complete clear */
#define DMA_IFCR_CHTIF6_Pos (22U)
#define DMA_IFCR_CHTIF6_Msk (0x1UL << DMA_IFCR_CHTIF6_Pos) /*!< 0x00400000 */
#define DMA_IFCR_CHTIF6 DMA_IFCR_CHTIF6_Msk /*!< Channel 6 Half Transfer clear */
#define DMA_IFCR_CTEIF6_Pos (23U)
#define DMA_IFCR_CTEIF6_Msk (0x1UL << DMA_IFCR_CTEIF6_Pos) /*!< 0x00800000 */
#define DMA_IFCR_CTEIF6 DMA_IFCR_CTEIF6_Msk /*!< Channel 6 Transfer Error clear */
/******************* Bit definition for DMA_CCR register ********************/
#define DMA_CCR_EN_Pos (0U)
#define DMA_CCR_EN_Msk (0x1UL << DMA_CCR_EN_Pos) /*!< 0x00000001 */
#define DMA_CCR_EN DMA_CCR_EN_Msk /*!< Channel enable */
#define DMA_CCR_TCIE_Pos (1U)
#define DMA_CCR_TCIE_Msk (0x1UL << DMA_CCR_TCIE_Pos) /*!< 0x00000002 */
#define DMA_CCR_TCIE DMA_CCR_TCIE_Msk /*!< Transfer complete interrupt enable */
#define DMA_CCR_HTIE_Pos (2U)
#define DMA_CCR_HTIE_Msk (0x1UL << DMA_CCR_HTIE_Pos) /*!< 0x00000004 */
#define DMA_CCR_HTIE DMA_CCR_HTIE_Msk /*!< Half Transfer interrupt enable */
#define DMA_CCR_TEIE_Pos (3U)
#define DMA_CCR_TEIE_Msk (0x1UL << DMA_CCR_TEIE_Pos) /*!< 0x00000008 */
#define DMA_CCR_TEIE DMA_CCR_TEIE_Msk /*!< Transfer error interrupt enable */
#define DMA_CCR_DIR_Pos (4U)
#define DMA_CCR_DIR_Msk (0x1UL << DMA_CCR_DIR_Pos) /*!< 0x00000010 */
#define DMA_CCR_DIR DMA_CCR_DIR_Msk /*!< Data transfer direction */
#define DMA_CCR_CIRC_Pos (5U)
#define DMA_CCR_CIRC_Msk (0x1UL << DMA_CCR_CIRC_Pos) /*!< 0x00000020 */
#define DMA_CCR_CIRC DMA_CCR_CIRC_Msk /*!< Circular mode */
#define DMA_CCR_PINC_Pos (6U)
#define DMA_CCR_PINC_Msk (0x1UL << DMA_CCR_PINC_Pos) /*!< 0x00000040 */
#define DMA_CCR_PINC DMA_CCR_PINC_Msk /*!< Peripheral increment mode */
#define DMA_CCR_MINC_Pos (7U)
#define DMA_CCR_MINC_Msk (0x1UL << DMA_CCR_MINC_Pos) /*!< 0x00000080 */
#define DMA_CCR_MINC DMA_CCR_MINC_Msk /*!< Memory increment mode */
#define DMA_CCR_PSIZE_Pos (8U)
#define DMA_CCR_PSIZE_Msk (0x3UL << DMA_CCR_PSIZE_Pos) /*!< 0x00000300 */
#define DMA_CCR_PSIZE DMA_CCR_PSIZE_Msk /*!< PSIZE[1:0] bits (Peripheral size) */
#define DMA_CCR_PSIZE_0 (0x1UL << DMA_CCR_PSIZE_Pos) /*!< 0x00000100 */
#define DMA_CCR_PSIZE_1 (0x2UL << DMA_CCR_PSIZE_Pos) /*!< 0x00000200 */
#define DMA_CCR_MSIZE_Pos (10U)
#define DMA_CCR_MSIZE_Msk (0x3UL << DMA_CCR_MSIZE_Pos) /*!< 0x00000C00 */
#define DMA_CCR_MSIZE DMA_CCR_MSIZE_Msk /*!< MSIZE[1:0] bits (Memory size) */
#define DMA_CCR_MSIZE_0 (0x1UL << DMA_CCR_MSIZE_Pos) /*!< 0x00000400 */
#define DMA_CCR_MSIZE_1 (0x2UL << DMA_CCR_MSIZE_Pos) /*!< 0x00000800 */
#define DMA_CCR_PL_Pos (12U)
#define DMA_CCR_PL_Msk (0x3UL << DMA_CCR_PL_Pos) /*!< 0x00003000 */
#define DMA_CCR_PL DMA_CCR_PL_Msk /*!< PL[1:0] bits(Channel Priority level)*/
#define DMA_CCR_PL_0 (0x1UL << DMA_CCR_PL_Pos) /*!< 0x00001000 */
#define DMA_CCR_PL_1 (0x2UL << DMA_CCR_PL_Pos) /*!< 0x00002000 */
#define DMA_CCR_MEM2MEM_Pos (14U)
#define DMA_CCR_MEM2MEM_Msk (0x1UL << DMA_CCR_MEM2MEM_Pos) /*!< 0x00004000 */
#define DMA_CCR_MEM2MEM DMA_CCR_MEM2MEM_Msk /*!< Memory to memory mode */
/****************** Bit definition for DMA_CNDTR register *******************/
#define DMA_CNDTR_NDT_Pos (0U)
#define DMA_CNDTR_NDT_Msk (0xFFFFUL << DMA_CNDTR_NDT_Pos) /*!< 0x0000FFFF */
#define DMA_CNDTR_NDT DMA_CNDTR_NDT_Msk /*!< Number of data to Transfer */
/****************** Bit definition for DMA_CPAR register ********************/
#define DMA_CPAR_PA_Pos (0U)
#define DMA_CPAR_PA_Msk (0xFFFFFFFFUL << DMA_CPAR_PA_Pos) /*!< 0xFFFFFFFF */
#define DMA_CPAR_PA DMA_CPAR_PA_Msk /*!< Peripheral Address */
/****************** Bit definition for DMA_CMAR register ********************/
#define DMA_CMAR_MA_Pos (0U)
#define DMA_CMAR_MA_Msk (0xFFFFFFFFUL << DMA_CMAR_MA_Pos) /*!< 0xFFFFFFFF */
#define DMA_CMAR_MA DMA_CMAR_MA_Msk /*!< Memory Address */
/******************************************************************************/
/* */
/* DMAMUX Controller */
/* */
/******************************************************************************/
/******************** Bits definition for DMAMUX_CxCR register **************/
#define DMAMUX_CxCR_DMAREQ_ID_Pos (0U)
#define DMAMUX_CxCR_DMAREQ_ID_Msk (0xFFUL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x000000FF */
#define DMAMUX_CxCR_DMAREQ_ID DMAMUX_CxCR_DMAREQ_ID_Msk
#define DMAMUX_CxCR_DMAREQ_ID_0 (0x01UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000001 */
#define DMAMUX_CxCR_DMAREQ_ID_1 (0x02UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000002 */
#define DMAMUX_CxCR_DMAREQ_ID_2 (0x04UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000004 */
#define DMAMUX_CxCR_DMAREQ_ID_3 (0x08UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000008 */
#define DMAMUX_CxCR_DMAREQ_ID_4 (0x10UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000010 */
#define DMAMUX_CxCR_DMAREQ_ID_5 (0x20UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000020 */
#define DMAMUX_CxCR_DMAREQ_ID_6 (0x40UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000040 */
#define DMAMUX_CxCR_DMAREQ_ID_7 (0x80UL << DMAMUX_CxCR_DMAREQ_ID_Pos)/*!< 0x00000080 */
#define DMAMUX_CxCR_SOIE_Pos (8U)
#define DMAMUX_CxCR_SOIE_Msk (0x1UL << DMAMUX_CxCR_SOIE_Pos)/*!< 0x00000100 */
#define DMAMUX_CxCR_SOIE DMAMUX_CxCR_SOIE_Msk
#define DMAMUX_CxCR_EGE_Pos (9U)
#define DMAMUX_CxCR_EGE_Msk (0x1UL << DMAMUX_CxCR_EGE_Pos)/*!< 0x00000200 */
#define DMAMUX_CxCR_EGE DMAMUX_CxCR_EGE_Msk
#define DMAMUX_CxCR_SE_Pos (16U)
#define DMAMUX_CxCR_SE_Msk (0x1UL << DMAMUX_CxCR_SE_Pos)/*!< 0x00010000 */
#define DMAMUX_CxCR_SE DMAMUX_CxCR_SE_Msk
#define DMAMUX_CxCR_SPOL_Pos (17U)
#define DMAMUX_CxCR_SPOL_Msk (0x3UL << DMAMUX_CxCR_SPOL_Pos)/*!< 0x00060000 */
#define DMAMUX_CxCR_SPOL DMAMUX_CxCR_SPOL_Msk
#define DMAMUX_CxCR_SPOL_0 (0x1UL << DMAMUX_CxCR_SPOL_Pos)/*!< 0x00020000 */
#define DMAMUX_CxCR_SPOL_1 (0x2UL << DMAMUX_CxCR_SPOL_Pos)/*!< 0x00040000 */
#define DMAMUX_CxCR_NBREQ_Pos (19U)
#define DMAMUX_CxCR_NBREQ_Msk (0x1FUL << DMAMUX_CxCR_NBREQ_Pos)/*!< 0x00F80000 */
#define DMAMUX_CxCR_NBREQ DMAMUX_CxCR_NBREQ_Msk
#define DMAMUX_CxCR_NBREQ_0 (0x01UL << DMAMUX_CxCR_NBREQ_Pos)/*!< 0x00080000 */
#define DMAMUX_CxCR_NBREQ_1 (0x02UL << DMAMUX_CxCR_NBREQ_Pos)/*!< 0x00100000 */
#define DMAMUX_CxCR_NBREQ_2 (0x04UL << DMAMUX_CxCR_NBREQ_Pos)/*!< 0x00200000 */
#define DMAMUX_CxCR_NBREQ_3 (0x08UL << DMAMUX_CxCR_NBREQ_Pos)/*!< 0x00400000 */
#define DMAMUX_CxCR_NBREQ_4 (0x10UL << DMAMUX_CxCR_NBREQ_Pos)/*!< 0x00800000 */
#define DMAMUX_CxCR_SYNC_ID_Pos (24U)
#define DMAMUX_CxCR_SYNC_ID_Msk (0x1FUL << DMAMUX_CxCR_SYNC_ID_Pos)/*!< 0x1F000000 */
#define DMAMUX_CxCR_SYNC_ID DMAMUX_CxCR_SYNC_ID_Msk
#define DMAMUX_CxCR_SYNC_ID_0 (0x01UL << DMAMUX_CxCR_SYNC_ID_Pos)/*!< 0x01000000 */
#define DMAMUX_CxCR_SYNC_ID_1 (0x02UL << DMAMUX_CxCR_SYNC_ID_Pos)/*!< 0x02000000 */
#define DMAMUX_CxCR_SYNC_ID_2 (0x04UL << DMAMUX_CxCR_SYNC_ID_Pos)/*!< 0x04000000 */
#define DMAMUX_CxCR_SYNC_ID_3 (0x08UL << DMAMUX_CxCR_SYNC_ID_Pos)/*!< 0x08000000 */
#define DMAMUX_CxCR_SYNC_ID_4 (0x10UL << DMAMUX_CxCR_SYNC_ID_Pos)/*!< 0x10000000 */
/******************** Bits definition for DMAMUX_CSR register ****************/
#define DMAMUX_CSR_SOF0_Pos (0U)
#define DMAMUX_CSR_SOF0_Msk (0x1UL << DMAMUX_CSR_SOF0_Pos)/*!< 0x00000001 */
#define DMAMUX_CSR_SOF0 DMAMUX_CSR_SOF0_Msk
#define DMAMUX_CSR_SOF1_Pos (1U)
#define DMAMUX_CSR_SOF1_Msk (0x1UL << DMAMUX_CSR_SOF1_Pos)/*!< 0x00000002 */
#define DMAMUX_CSR_SOF1 DMAMUX_CSR_SOF1_Msk
#define DMAMUX_CSR_SOF2_Pos (2U)
#define DMAMUX_CSR_SOF2_Msk (0x1UL << DMAMUX_CSR_SOF2_Pos)/*!< 0x00000004 */
#define DMAMUX_CSR_SOF2 DMAMUX_CSR_SOF2_Msk
#define DMAMUX_CSR_SOF3_Pos (3U)
#define DMAMUX_CSR_SOF3_Msk (0x1UL << DMAMUX_CSR_SOF3_Pos)/*!< 0x00000008 */
#define DMAMUX_CSR_SOF3 DMAMUX_CSR_SOF3_Msk
#define DMAMUX_CSR_SOF4_Pos (4U)
#define DMAMUX_CSR_SOF4_Msk (0x1UL << DMAMUX_CSR_SOF4_Pos)/*!< 0x00000010 */
#define DMAMUX_CSR_SOF4 DMAMUX_CSR_SOF4_Msk
#define DMAMUX_CSR_SOF5_Pos (5U)
#define DMAMUX_CSR_SOF5_Msk (0x1UL << DMAMUX_CSR_SOF5_Pos)/*!< 0x00000020 */
#define DMAMUX_CSR_SOF5 DMAMUX_CSR_SOF5_Msk
#define DMAMUX_CSR_SOF6_Pos (6U)
#define DMAMUX_CSR_SOF6_Msk (0x1UL << DMAMUX_CSR_SOF6_Pos)/*!< 0x00000040 */
#define DMAMUX_CSR_SOF6 DMAMUX_CSR_SOF6_Msk
#define DMAMUX_CSR_SOF7_Pos (7U)
#define DMAMUX_CSR_SOF7_Msk (0x1UL << DMAMUX_CSR_SOF7_Pos)/*!< 0x00000080 */
#define DMAMUX_CSR_SOF7 DMAMUX_CSR_SOF7_Msk
#define DMAMUX_CSR_SOF8_Pos (8U)
#define DMAMUX_CSR_SOF8_Msk (0x1UL << DMAMUX_CSR_SOF8_Pos)/*!< 0x00000100 */
#define DMAMUX_CSR_SOF8 DMAMUX_CSR_SOF8_Msk
#define DMAMUX_CSR_SOF9_Pos (9U)
#define DMAMUX_CSR_SOF9_Msk (0x1UL << DMAMUX_CSR_SOF9_Pos)/*!< 0x00000200 */
#define DMAMUX_CSR_SOF9 DMAMUX_CSR_SOF9_Msk
#define DMAMUX_CSR_SOF10_Pos (10U)
#define DMAMUX_CSR_SOF10_Msk (0x1UL << DMAMUX_CSR_SOF10_Pos)/*!< 0x00000400 */
#define DMAMUX_CSR_SOF10 DMAMUX_CSR_SOF10_Msk
#define DMAMUX_CSR_SOF11_Pos (11U)
#define DMAMUX_CSR_SOF11_Msk (0x1UL << DMAMUX_CSR_SOF11_Pos)/*!< 0x00000800 */
#define DMAMUX_CSR_SOF11 DMAMUX_CSR_SOF11_Msk
/******************** Bits definition for DMAMUX_CFR register ****************/
#define DMAMUX_CFR_CSOF0_Pos (0U)
#define DMAMUX_CFR_CSOF0_Msk (0x1UL << DMAMUX_CFR_CSOF0_Pos)/*!< 0x00000001 */
#define DMAMUX_CFR_CSOF0 DMAMUX_CFR_CSOF0_Msk
#define DMAMUX_CFR_CSOF1_Pos (1U)
#define DMAMUX_CFR_CSOF1_Msk (0x1UL << DMAMUX_CFR_CSOF1_Pos)/*!< 0x00000002 */
#define DMAMUX_CFR_CSOF1 DMAMUX_CFR_CSOF1_Msk
#define DMAMUX_CFR_CSOF2_Pos (2U)
#define DMAMUX_CFR_CSOF2_Msk (0x1UL << DMAMUX_CFR_CSOF2_Pos)/*!< 0x00000004 */
#define DMAMUX_CFR_CSOF2 DMAMUX_CFR_CSOF2_Msk
#define DMAMUX_CFR_CSOF3_Pos (3U)
#define DMAMUX_CFR_CSOF3_Msk (0x1UL << DMAMUX_CFR_CSOF3_Pos)/*!< 0x00000008 */
#define DMAMUX_CFR_CSOF3 DMAMUX_CFR_CSOF3_Msk
#define DMAMUX_CFR_CSOF4_Pos (4U)
#define DMAMUX_CFR_CSOF4_Msk (0x1UL << DMAMUX_CFR_CSOF4_Pos)/*!< 0x00000010 */
#define DMAMUX_CFR_CSOF4 DMAMUX_CFR_CSOF4_Msk
#define DMAMUX_CFR_CSOF5_Pos (5U)
#define DMAMUX_CFR_CSOF5_Msk (0x1UL << DMAMUX_CFR_CSOF5_Pos)/*!< 0x00000020 */
#define DMAMUX_CFR_CSOF5 DMAMUX_CFR_CSOF5_Msk
#define DMAMUX_CFR_CSOF6_Pos (6U)
#define DMAMUX_CFR_CSOF6_Msk (0x1UL << DMAMUX_CFR_CSOF6_Pos)/*!< 0x00000040 */
#define DMAMUX_CFR_CSOF6 DMAMUX_CFR_CSOF6_Msk
#define DMAMUX_CFR_CSOF7_Pos (7U)
#define DMAMUX_CFR_CSOF7_Msk (0x1UL << DMAMUX_CFR_CSOF7_Pos)/*!< 0x00000080 */
#define DMAMUX_CFR_CSOF7 DMAMUX_CFR_CSOF7_Msk
#define DMAMUX_CFR_CSOF8_Pos (8U)
#define DMAMUX_CFR_CSOF8_Msk (0x1UL << DMAMUX_CFR_CSOF8_Pos)/*!< 0x00000100 */
#define DMAMUX_CFR_CSOF8 DMAMUX_CFR_CSOF8_Msk
#define DMAMUX_CFR_CSOF9_Pos (9U)
#define DMAMUX_CFR_CSOF9_Msk (0x1UL << DMAMUX_CFR_CSOF9_Pos)/*!< 0x00000200 */
#define DMAMUX_CFR_CSOF9 DMAMUX_CFR_CSOF9_Msk
#define DMAMUX_CFR_CSOF10_Pos (10U)
#define DMAMUX_CFR_CSOF10_Msk (0x1UL << DMAMUX_CFR_CSOF10_Pos)/*!< 0x00000400 */
#define DMAMUX_CFR_CSOF10 DMAMUX_CFR_CSOF10_Msk
#define DMAMUX_CFR_CSOF11_Pos (11U)
#define DMAMUX_CFR_CSOF11_Msk (0x1UL << DMAMUX_CFR_CSOF11_Pos)/*!< 0x00000800 */
#define DMAMUX_CFR_CSOF11 DMAMUX_CFR_CSOF11_Msk
/******************** Bits definition for DMAMUX_RGxCR register ************/
#define DMAMUX_RGxCR_SIG_ID_Pos (0U)
#define DMAMUX_RGxCR_SIG_ID_Msk (0x1FUL << DMAMUX_RGxCR_SIG_ID_Pos)/*!< 0x0000001F */
#define DMAMUX_RGxCR_SIG_ID DMAMUX_RGxCR_SIG_ID_Msk
#define DMAMUX_RGxCR_SIG_ID_0 (0x01UL << DMAMUX_RGxCR_SIG_ID_Pos)/*!< 0x00000001 */
#define DMAMUX_RGxCR_SIG_ID_1 (0x02UL << DMAMUX_RGxCR_SIG_ID_Pos)/*!< 0x00000002 */
#define DMAMUX_RGxCR_SIG_ID_2 (0x04UL << DMAMUX_RGxCR_SIG_ID_Pos)/*!< 0x00000004 */
#define DMAMUX_RGxCR_SIG_ID_3 (0x08UL << DMAMUX_RGxCR_SIG_ID_Pos)/*!< 0x00000008 */
#define DMAMUX_RGxCR_SIG_ID_4 (0x10UL << DMAMUX_RGxCR_SIG_ID_Pos)/*!< 0x00000010 */
#define DMAMUX_RGxCR_OIE_Pos (8U)
#define DMAMUX_RGxCR_OIE_Msk (0x1UL << DMAMUX_RGxCR_OIE_Pos)/*!< 0x00000100 */
#define DMAMUX_RGxCR_OIE DMAMUX_RGxCR_OIE_Msk
#define DMAMUX_RGxCR_GE_Pos (16U)
#define DMAMUX_RGxCR_GE_Msk (0x1UL << DMAMUX_RGxCR_GE_Pos)/*!< 0x00010000 */
#define DMAMUX_RGxCR_GE DMAMUX_RGxCR_GE_Msk
#define DMAMUX_RGxCR_GPOL_Pos (17U)
#define DMAMUX_RGxCR_GPOL_Msk (0x3UL << DMAMUX_RGxCR_GPOL_Pos)/*!< 0x00060000 */
#define DMAMUX_RGxCR_GPOL DMAMUX_RGxCR_GPOL_Msk
#define DMAMUX_RGxCR_GPOL_0 (0x1UL << DMAMUX_RGxCR_GPOL_Pos)/*!< 0x00020000 */
#define DMAMUX_RGxCR_GPOL_1 (0x2UL << DMAMUX_RGxCR_GPOL_Pos)/*!< 0x00040000 */
#define DMAMUX_RGxCR_GNBREQ_Pos (19U)
#define DMAMUX_RGxCR_GNBREQ_Msk (0x1FUL << DMAMUX_RGxCR_GNBREQ_Pos)/*!< 0x00F80000 */
#define DMAMUX_RGxCR_GNBREQ DMAMUX_RGxCR_GNBREQ_Msk
#define DMAMUX_RGxCR_GNBREQ_0 (0x01UL << DMAMUX_RGxCR_GNBREQ_Pos)/*!< 0x00080000 */
#define DMAMUX_RGxCR_GNBREQ_1 (0x02UL << DMAMUX_RGxCR_GNBREQ_Pos)/*!< 0x00100000 */
#define DMAMUX_RGxCR_GNBREQ_2 (0x04UL << DMAMUX_RGxCR_GNBREQ_Pos)/*!< 0x00200000 */
#define DMAMUX_RGxCR_GNBREQ_3 (0x08UL << DMAMUX_RGxCR_GNBREQ_Pos)/*!< 0x00400000 */
#define DMAMUX_RGxCR_GNBREQ_4 (0x10UL << DMAMUX_RGxCR_GNBREQ_Pos)/*!< 0x00800000 */
/******************** Bits definition for DMAMUX_RGSR register **************/
#define DMAMUX_RGSR_OF0_Pos (0U)
#define DMAMUX_RGSR_OF0_Msk (0x1UL << DMAMUX_RGSR_OF0_Pos)/*!< 0x00000001 */
#define DMAMUX_RGSR_OF0 DMAMUX_RGSR_OF0_Msk
#define DMAMUX_RGSR_OF1_Pos (1U)
#define DMAMUX_RGSR_OF1_Msk (0x1UL << DMAMUX_RGSR_OF1_Pos)/*!< 0x00000002 */
#define DMAMUX_RGSR_OF1 DMAMUX_RGSR_OF1_Msk
#define DMAMUX_RGSR_OF2_Pos (2U)
#define DMAMUX_RGSR_OF2_Msk (0x1UL << DMAMUX_RGSR_OF2_Pos)/*!< 0x00000004 */
#define DMAMUX_RGSR_OF2 DMAMUX_RGSR_OF2_Msk
#define DMAMUX_RGSR_OF3_Pos (3U)
#define DMAMUX_RGSR_OF3_Msk (0x1UL << DMAMUX_RGSR_OF3_Pos)/*!< 0x00000008 */
#define DMAMUX_RGSR_OF3 DMAMUX_RGSR_OF3_Msk
/******************** Bits definition for DMAMUX_RGCFR register ************/
#define DMAMUX_RGCFR_COF0_Pos (0U)
#define DMAMUX_RGCFR_COF0_Msk (0x1UL << DMAMUX_RGCFR_COF0_Pos)/*!< 0x00000001 */
#define DMAMUX_RGCFR_COF0 DMAMUX_RGCFR_COF0_Msk
#define DMAMUX_RGCFR_COF1_Pos (1U)
#define DMAMUX_RGCFR_COF1_Msk (0x1UL << DMAMUX_RGCFR_COF1_Pos)/*!< 0x00000002 */
#define DMAMUX_RGCFR_COF1 DMAMUX_RGCFR_COF1_Msk
#define DMAMUX_RGCFR_COF2_Pos (2U)
#define DMAMUX_RGCFR_COF2_Msk (0x1UL << DMAMUX_RGCFR_COF2_Pos)/*!< 0x00000004 */
#define DMAMUX_RGCFR_COF2 DMAMUX_RGCFR_COF2_Msk
#define DMAMUX_RGCFR_COF3_Pos (3U)
#define DMAMUX_RGCFR_COF3_Msk (0x1UL << DMAMUX_RGCFR_COF3_Pos)/*!< 0x00000008 */
#define DMAMUX_RGCFR_COF3 DMAMUX_RGCFR_COF3_Msk
/******************** Bits definition for DMAMUX_IPHW_CFGR2 ******************/
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ0_Pos (0U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ0_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ0_Pos)/*!< 0x00000001 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ0 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ0_Msk
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ1_Pos (1U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ1_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ1_Pos)/*!< 0x00000002 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ1 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ1_Msk
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ2_Pos (2U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ2_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ2_Pos)/*!< 0x00000004 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ2 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ2_Msk
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ3_Pos (3U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ3_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ3_Pos)/*!< 0x00000008 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ3 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ3_Msk
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ4_Pos (4U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ4_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ4_Pos)/*!< 0x00000010 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ4 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ4_Msk
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ5_Pos (5U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ5_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ5_Pos)/*!< 0x00000020 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ5 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ5_Msk
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ6_Pos (6U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ6_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ6_Pos)/*!< 0x00000040 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ6 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ6_Msk
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ7_Pos (7U)
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ7_Msk (0x1UL << DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ7_Pos)/*!< 0x00000080 */
#define DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ7 DMAMUX_IPHW_CFGR2_NUM_DMA_EXT_REQ7_Msk
/******************** Bits definition for DMAMUX_IPHW_CFGR1 ******************/
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS0_Pos (0U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS0_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS0_Pos)/*!< 0x00000001 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS0 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS0_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS1_Pos (1U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS1_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS1_Pos)/*!< 0x00000002 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS1 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS1_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS2_Pos (2U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS2_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS2_Pos)/*!< 0x00000004 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS2 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS2_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS3_Pos (3U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS3_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS3_Pos)/*!< 0x00000008 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS3 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS3_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS4_Pos (4U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS4_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS4_Pos)/*!< 0x00000010 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS4 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS4_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS5_Pos (5U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS5_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS5_Pos)/*!< 0x00000020 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS5 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS5_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS6_Pos (6U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS6_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS6_Pos)/*!< 0x00000040 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS6 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS6_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS7_Pos (7U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS7_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS7_Pos)/*!< 0x00000080 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS7 DMAMUX_IPHW_CFGR1_NUM_DMA_STREAMS7_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ0_Pos (8U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ0_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ0_Pos)/*!< 0x00000100 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ0 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ0_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ1_Pos (9U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ1_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ1_Pos)/*!< 0x00000200 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ1 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ1_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ2_Pos (10U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ2_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ2_Pos)/*!< 0x00000400 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ2 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ2_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ3_Pos (11U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ3_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ3_Pos)/*!< 0x00000800 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ3 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ3_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ4_Pos (12U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ4_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ4_Pos)/*!< 0x00001000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ4 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ4_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ5_Pos (13U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ5_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ5_Pos)/*!< 0x00002000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ5 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ5_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ6_Pos (14U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ6_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ6_Pos)/*!< 0x00004000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ6 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ6_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ7_Pos (15U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ7_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ7_Pos)/*!< 0x00008000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ7 DMAMUX_IPHW_CFGR1_NUM_DMA_PERIPH_REQ7_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG0_Pos (16U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG0_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG0_Pos)/*!< 0x00010000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG0 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG0_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG1_Pos (17U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG1_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG1_Pos)/*!< 0x00020000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG1 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG1_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG2_Pos (18U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG2_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG2_Pos)/*!< 0x00040000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG2 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG2_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG3_Pos (19U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG3_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG3_Pos)/*!< 0x00080000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG3 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG3_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG4_Pos (20U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG4_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG4_Pos)/*!< 0x00100000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG4 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG4_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG5_Pos (21U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG5_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG5_Pos)/*!< 0x00200000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG5 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG5_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG6_Pos (22U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG6_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG6_Pos)/*!< 0x00400000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG6 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG6_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG7_Pos (23U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG7_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG7_Pos)/*!< 0x00800000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG7 DMAMUX_IPHW_CFGR1_NUM_DMA_TRIG7_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN0_Pos (24U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN0_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN0_Pos)/*!< 0x01000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN0 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN0_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN1_Pos (25U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN1_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN1_Pos)/*!< 0x02000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN1 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN1_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN2_Pos (26U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN2_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN2_Pos)/*!< 0x04000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN2 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN2_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN3_Pos (27U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN3_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN3_Pos)/*!< 0x08000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN3 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN3_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN4_Pos (28U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN4_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN4_Pos)/*!< 0x10000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN4 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN4_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN5_Pos (29U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN5_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN5_Pos)/*!< 0x20000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN5 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN5_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN6_Pos (30U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN6_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN6_Pos)/*!< 0x40000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN6 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN6_Msk
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN7_Pos (31U)
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN7_Msk (0x1UL << DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN7_Pos)/*!< 0x80000000 */
#define DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN7 DMAMUX_IPHW_CFGR1_NUM_DMA_REQGEN7_Msk
/******************************************************************************/
/* */
/* External Interrupt/Event Controller */
/* */
/******************************************************************************/
/******************* Bit definition for EXTI_IMR1 register ******************/
#define EXTI_IMR1_IM0_Pos (0U)
#define EXTI_IMR1_IM0_Msk (0x1UL << EXTI_IMR1_IM0_Pos) /*!< 0x00000001 */
#define EXTI_IMR1_IM0 EXTI_IMR1_IM0_Msk /*!< Interrupt Mask on line 0 */
#define EXTI_IMR1_IM1_Pos (1U)
#define EXTI_IMR1_IM1_Msk (0x1UL << EXTI_IMR1_IM1_Pos) /*!< 0x00000002 */
#define EXTI_IMR1_IM1 EXTI_IMR1_IM1_Msk /*!< Interrupt Mask on line 1 */
#define EXTI_IMR1_IM2_Pos (2U)
#define EXTI_IMR1_IM2_Msk (0x1UL << EXTI_IMR1_IM2_Pos) /*!< 0x00000004 */
#define EXTI_IMR1_IM2 EXTI_IMR1_IM2_Msk /*!< Interrupt Mask on line 2 */
#define EXTI_IMR1_IM3_Pos (3U)
#define EXTI_IMR1_IM3_Msk (0x1UL << EXTI_IMR1_IM3_Pos) /*!< 0x00000008 */
#define EXTI_IMR1_IM3 EXTI_IMR1_IM3_Msk /*!< Interrupt Mask on line 3 */
#define EXTI_IMR1_IM4_Pos (4U)
#define EXTI_IMR1_IM4_Msk (0x1UL << EXTI_IMR1_IM4_Pos) /*!< 0x00000010 */
#define EXTI_IMR1_IM4 EXTI_IMR1_IM4_Msk /*!< Interrupt Mask on line 4 */
#define EXTI_IMR1_IM5_Pos (5U)
#define EXTI_IMR1_IM5_Msk (0x1UL << EXTI_IMR1_IM5_Pos) /*!< 0x00000020 */
#define EXTI_IMR1_IM5 EXTI_IMR1_IM5_Msk /*!< Interrupt Mask on line 5 */
#define EXTI_IMR1_IM6_Pos (6U)
#define EXTI_IMR1_IM6_Msk (0x1UL << EXTI_IMR1_IM6_Pos) /*!< 0x00000040 */
#define EXTI_IMR1_IM6 EXTI_IMR1_IM6_Msk /*!< Interrupt Mask on line 6 */
#define EXTI_IMR1_IM7_Pos (7U)
#define EXTI_IMR1_IM7_Msk (0x1UL << EXTI_IMR1_IM7_Pos) /*!< 0x00000080 */
#define EXTI_IMR1_IM7 EXTI_IMR1_IM7_Msk /*!< Interrupt Mask on line 7 */
#define EXTI_IMR1_IM8_Pos (8U)
#define EXTI_IMR1_IM8_Msk (0x1UL << EXTI_IMR1_IM8_Pos) /*!< 0x00000100 */
#define EXTI_IMR1_IM8 EXTI_IMR1_IM8_Msk /*!< Interrupt Mask on line 8 */
#define EXTI_IMR1_IM9_Pos (9U)
#define EXTI_IMR1_IM9_Msk (0x1UL << EXTI_IMR1_IM9_Pos) /*!< 0x00000200 */
#define EXTI_IMR1_IM9 EXTI_IMR1_IM9_Msk /*!< Interrupt Mask on line 9 */
#define EXTI_IMR1_IM10_Pos (10U)
#define EXTI_IMR1_IM10_Msk (0x1UL << EXTI_IMR1_IM10_Pos) /*!< 0x00000400 */
#define EXTI_IMR1_IM10 EXTI_IMR1_IM10_Msk /*!< Interrupt Mask on line 10 */
#define EXTI_IMR1_IM11_Pos (11U)
#define EXTI_IMR1_IM11_Msk (0x1UL << EXTI_IMR1_IM11_Pos) /*!< 0x00000800 */
#define EXTI_IMR1_IM11 EXTI_IMR1_IM11_Msk /*!< Interrupt Mask on line 11 */
#define EXTI_IMR1_IM12_Pos (12U)
#define EXTI_IMR1_IM12_Msk (0x1UL << EXTI_IMR1_IM12_Pos) /*!< 0x00001000 */
#define EXTI_IMR1_IM12 EXTI_IMR1_IM12_Msk /*!< Interrupt Mask on line 12 */
#define EXTI_IMR1_IM13_Pos (13U)
#define EXTI_IMR1_IM13_Msk (0x1UL << EXTI_IMR1_IM13_Pos) /*!< 0x00002000 */
#define EXTI_IMR1_IM13 EXTI_IMR1_IM13_Msk /*!< Interrupt Mask on line 13 */
#define EXTI_IMR1_IM14_Pos (14U)
#define EXTI_IMR1_IM14_Msk (0x1UL << EXTI_IMR1_IM14_Pos) /*!< 0x00004000 */
#define EXTI_IMR1_IM14 EXTI_IMR1_IM14_Msk /*!< Interrupt Mask on line 14 */
#define EXTI_IMR1_IM15_Pos (15U)
#define EXTI_IMR1_IM15_Msk (0x1UL << EXTI_IMR1_IM15_Pos) /*!< 0x00008000 */
#define EXTI_IMR1_IM15 EXTI_IMR1_IM15_Msk /*!< Interrupt Mask on line 15 */
#define EXTI_IMR1_IM16_Pos (16U)
#define EXTI_IMR1_IM16_Msk (0x1UL << EXTI_IMR1_IM16_Pos) /*!< 0x00010000 */
#define EXTI_IMR1_IM16 EXTI_IMR1_IM16_Msk /*!< Interrupt Mask on line 16 */
#define EXTI_IMR1_IM17_Pos (17U)
#define EXTI_IMR1_IM17_Msk (0x1UL << EXTI_IMR1_IM17_Pos) /*!< 0x00020000 */
#define EXTI_IMR1_IM17 EXTI_IMR1_IM17_Msk /*!< Interrupt Mask on line 17 */
#define EXTI_IMR1_IM18_Pos (18U)
#define EXTI_IMR1_IM18_Msk (0x1UL << EXTI_IMR1_IM18_Pos) /*!< 0x00040000 */
#define EXTI_IMR1_IM18 EXTI_IMR1_IM18_Msk /*!< Interrupt Mask on line 18 */
#define EXTI_IMR1_IM19_Pos (19U)
#define EXTI_IMR1_IM19_Msk (0x1UL << EXTI_IMR1_IM19_Pos) /*!< 0x00080000 */
#define EXTI_IMR1_IM19 EXTI_IMR1_IM19_Msk /*!< Interrupt Mask on line 19 */
#define EXTI_IMR1_IM20_Pos (20U)
#define EXTI_IMR1_IM20_Msk (0x1UL << EXTI_IMR1_IM20_Pos) /*!< 0x00100000 */
#define EXTI_IMR1_IM20 EXTI_IMR1_IM20_Msk /*!< Interrupt Mask on line 20 */
#define EXTI_IMR1_IM21_Pos (21U)
#define EXTI_IMR1_IM21_Msk (0x1UL << EXTI_IMR1_IM21_Pos) /*!< 0x00200000 */
#define EXTI_IMR1_IM21 EXTI_IMR1_IM21_Msk /*!< Interrupt Mask on line 21 */
#define EXTI_IMR1_IM22_Pos (22U)
#define EXTI_IMR1_IM22_Msk (0x1UL << EXTI_IMR1_IM22_Pos) /*!< 0x00400000 */
#define EXTI_IMR1_IM22 EXTI_IMR1_IM22_Msk /*!< Interrupt Mask on line 22 */
#define EXTI_IMR1_IM23_Pos (23U)
#define EXTI_IMR1_IM23_Msk (0x1UL << EXTI_IMR1_IM23_Pos) /*!< 0x00800000 */
#define EXTI_IMR1_IM23 EXTI_IMR1_IM23_Msk /*!< Interrupt Mask on line 23 */
#define EXTI_IMR1_IM24_Pos (24U)
#define EXTI_IMR1_IM24_Msk (0x1UL << EXTI_IMR1_IM24_Pos) /*!< 0x01000000 */
#define EXTI_IMR1_IM24 EXTI_IMR1_IM24_Msk /*!< Interrupt Mask on line 24 */
#define EXTI_IMR1_IM25_Pos (25U)
#define EXTI_IMR1_IM25_Msk (0x1UL << EXTI_IMR1_IM25_Pos) /*!< 0x02000000 */
#define EXTI_IMR1_IM25 EXTI_IMR1_IM25_Msk /*!< Interrupt Mask on line 25 */
#define EXTI_IMR1_IM26_Pos (26U)
#define EXTI_IMR1_IM26_Msk (0x1UL << EXTI_IMR1_IM26_Pos) /*!< 0x04000000 */
#define EXTI_IMR1_IM26 EXTI_IMR1_IM26_Msk /*!< Interrupt Mask on line 26 */
#define EXTI_IMR1_IM27_Pos (27U)
#define EXTI_IMR1_IM27_Msk (0x1UL << EXTI_IMR1_IM27_Pos) /*!< 0x08000000 */
#define EXTI_IMR1_IM27 EXTI_IMR1_IM27_Msk /*!< Interrupt Mask on line 27 */
#define EXTI_IMR1_IM28_Pos (28U)
#define EXTI_IMR1_IM28_Msk (0x1UL << EXTI_IMR1_IM28_Pos) /*!< 0x10000000 */
#define EXTI_IMR1_IM28 EXTI_IMR1_IM28_Msk /*!< Interrupt Mask on line 28 */
#define EXTI_IMR1_IM29_Pos (29U)
#define EXTI_IMR1_IM29_Msk (0x1UL << EXTI_IMR1_IM29_Pos) /*!< 0x20000000 */
#define EXTI_IMR1_IM29 EXTI_IMR1_IM29_Msk /*!< Interrupt Mask on line 29 */
#define EXTI_IMR1_IM30_Pos (30U)
#define EXTI_IMR1_IM30_Msk (0x1UL << EXTI_IMR1_IM30_Pos) /*!< 0x40000000 */
#define EXTI_IMR1_IM30 EXTI_IMR1_IM30_Msk /*!< Interrupt Mask on line 30 */
#define EXTI_IMR1_IM_Pos (0U)
#define EXTI_IMR1_IM_Msk (0x7FFFFFFFUL << EXTI_IMR1_IM_Pos) /*!< 0x7FFFFFFF */
#define EXTI_IMR1_IM EXTI_IMR1_IM_Msk /*!< Interrupt Mask All */
/******************* Bit definition for EXTI_EMR1 register ******************/
#define EXTI_EMR1_EM0_Pos (0U)
#define EXTI_EMR1_EM0_Msk (0x1UL << EXTI_EMR1_EM0_Pos) /*!< 0x00000001 */
#define EXTI_EMR1_EM0 EXTI_EMR1_EM0_Msk /*!< Event Mask on line 0 */
#define EXTI_EMR1_EM1_Pos (1U)
#define EXTI_EMR1_EM1_Msk (0x1UL << EXTI_EMR1_EM1_Pos) /*!< 0x00000002 */
#define EXTI_EMR1_EM1 EXTI_EMR1_EM1_Msk /*!< Event Mask on line 1 */
#define EXTI_EMR1_EM2_Pos (2U)
#define EXTI_EMR1_EM2_Msk (0x1UL << EXTI_EMR1_EM2_Pos) /*!< 0x00000004 */
#define EXTI_EMR1_EM2 EXTI_EMR1_EM2_Msk /*!< Event Mask on line 2 */
#define EXTI_EMR1_EM3_Pos (3U)
#define EXTI_EMR1_EM3_Msk (0x1UL << EXTI_EMR1_EM3_Pos) /*!< 0x00000008 */
#define EXTI_EMR1_EM3 EXTI_EMR1_EM3_Msk /*!< Event Mask on line 3 */
#define EXTI_EMR1_EM4_Pos (4U)
#define EXTI_EMR1_EM4_Msk (0x1UL << EXTI_EMR1_EM4_Pos) /*!< 0x00000010 */
#define EXTI_EMR1_EM4 EXTI_EMR1_EM4_Msk /*!< Event Mask on line 4 */
#define EXTI_EMR1_EM5_Pos (5U)
#define EXTI_EMR1_EM5_Msk (0x1UL << EXTI_EMR1_EM5_Pos) /*!< 0x00000020 */
#define EXTI_EMR1_EM5 EXTI_EMR1_EM5_Msk /*!< Event Mask on line 5 */
#define EXTI_EMR1_EM6_Pos (6U)
#define EXTI_EMR1_EM6_Msk (0x1UL << EXTI_EMR1_EM6_Pos) /*!< 0x00000040 */
#define EXTI_EMR1_EM6 EXTI_EMR1_EM6_Msk /*!< Event Mask on line 6 */
#define EXTI_EMR1_EM7_Pos (7U)
#define EXTI_EMR1_EM7_Msk (0x1UL << EXTI_EMR1_EM7_Pos) /*!< 0x00000080 */
#define EXTI_EMR1_EM7 EXTI_EMR1_EM7_Msk /*!< Event Mask on line 7 */
#define EXTI_EMR1_EM8_Pos (8U)
#define EXTI_EMR1_EM8_Msk (0x1UL << EXTI_EMR1_EM8_Pos) /*!< 0x00000100 */
#define EXTI_EMR1_EM8 EXTI_EMR1_EM8_Msk /*!< Event Mask on line 8 */
#define EXTI_EMR1_EM9_Pos (9U)
#define EXTI_EMR1_EM9_Msk (0x1UL << EXTI_EMR1_EM9_Pos) /*!< 0x00000200 */
#define EXTI_EMR1_EM9 EXTI_EMR1_EM9_Msk /*!< Event Mask on line 9 */
#define EXTI_EMR1_EM10_Pos (10U)
#define EXTI_EMR1_EM10_Msk (0x1UL << EXTI_EMR1_EM10_Pos) /*!< 0x00000400 */
#define EXTI_EMR1_EM10 EXTI_EMR1_EM10_Msk /*!< Event Mask on line 10 */
#define EXTI_EMR1_EM11_Pos (11U)
#define EXTI_EMR1_EM11_Msk (0x1UL << EXTI_EMR1_EM11_Pos) /*!< 0x00000800 */
#define EXTI_EMR1_EM11 EXTI_EMR1_EM11_Msk /*!< Event Mask on line 11 */
#define EXTI_EMR1_EM12_Pos (12U)
#define EXTI_EMR1_EM12_Msk (0x1UL << EXTI_EMR1_EM12_Pos) /*!< 0x00001000 */
#define EXTI_EMR1_EM12 EXTI_EMR1_EM12_Msk /*!< Event Mask on line 12 */
#define EXTI_EMR1_EM13_Pos (13U)
#define EXTI_EMR1_EM13_Msk (0x1UL << EXTI_EMR1_EM13_Pos) /*!< 0x00002000 */
#define EXTI_EMR1_EM13 EXTI_EMR1_EM13_Msk /*!< Event Mask on line 13 */
#define EXTI_EMR1_EM14_Pos (14U)
#define EXTI_EMR1_EM14_Msk (0x1UL << EXTI_EMR1_EM14_Pos) /*!< 0x00004000 */
#define EXTI_EMR1_EM14 EXTI_EMR1_EM14_Msk /*!< Event Mask on line 14 */
#define EXTI_EMR1_EM15_Pos (15U)
#define EXTI_EMR1_EM15_Msk (0x1UL << EXTI_EMR1_EM15_Pos) /*!< 0x00008000 */
#define EXTI_EMR1_EM15 EXTI_EMR1_EM15_Msk /*!< Event Mask on line 15 */
#define EXTI_EMR1_EM16_Pos (16U)
#define EXTI_EMR1_EM16_Msk (0x1UL << EXTI_EMR1_EM16_Pos) /*!< 0x00010000 */
#define EXTI_EMR1_EM16 EXTI_EMR1_EM16_Msk /*!< Event Mask on line 16 */
#define EXTI_EMR1_EM17_Pos (17U)
#define EXTI_EMR1_EM17_Msk (0x1UL << EXTI_EMR1_EM17_Pos) /*!< 0x00020000 */
#define EXTI_EMR1_EM17 EXTI_EMR1_EM17_Msk /*!< Event Mask on line 17 */
#define EXTI_EMR1_EM18_Pos (18U)
#define EXTI_EMR1_EM18_Msk (0x1UL << EXTI_EMR1_EM18_Pos) /*!< 0x00040000 */
#define EXTI_EMR1_EM18 EXTI_EMR1_EM18_Msk /*!< Event Mask on line 18 */
#define EXTI_EMR1_EM19_Pos (19U)
#define EXTI_EMR1_EM19_Msk (0x1UL << EXTI_EMR1_EM19_Pos) /*!< 0x00080000 */
#define EXTI_EMR1_EM19 EXTI_EMR1_EM19_Msk /*!< Event Mask on line 19 */
#define EXTI_EMR1_EM20_Pos (20U)
#define EXTI_EMR1_EM20_Msk (0x1UL << EXTI_EMR1_EM20_Pos) /*!< 0x00100000 */
#define EXTI_EMR1_EM20 EXTI_EMR1_EM20_Msk /*!< Event Mask on line 20 */
#define EXTI_EMR1_EM21_Pos (21U)
#define EXTI_EMR1_EM21_Msk (0x1UL << EXTI_EMR1_EM21_Pos) /*!< 0x00200000 */
#define EXTI_EMR1_EM21 EXTI_EMR1_EM21_Msk /*!< Event Mask on line 21 */
#define EXTI_EMR1_EM22_Pos (22U)
#define EXTI_EMR1_EM22_Msk (0x1UL << EXTI_EMR1_EM22_Pos) /*!< 0x00400000 */
#define EXTI_EMR1_EM22 EXTI_EMR1_EM22_Msk /*!< Event Mask on line 22 */
#define EXTI_EMR1_EM23_Pos (23U)
#define EXTI_EMR1_EM23_Msk (0x1UL << EXTI_EMR1_EM23_Pos) /*!< 0x00800000 */
#define EXTI_EMR1_EM23 EXTI_EMR1_EM23_Msk /*!< Event Mask on line 23 */
#define EXTI_EMR1_EM24_Pos (24U)
#define EXTI_EMR1_EM24_Msk (0x1UL << EXTI_EMR1_EM24_Pos) /*!< 0x01000000 */
#define EXTI_EMR1_EM24 EXTI_EMR1_EM24_Msk /*!< Event Mask on line 24 */
#define EXTI_EMR1_EM25_Pos (25U)
#define EXTI_EMR1_EM25_Msk (0x1UL << EXTI_EMR1_EM25_Pos) /*!< 0x02000000 */
#define EXTI_EMR1_EM25 EXTI_EMR1_EM25_Msk /*!< Event Mask on line 25 */
#define EXTI_EMR1_EM26_Pos (26U)
#define EXTI_EMR1_EM26_Msk (0x1UL << EXTI_EMR1_EM26_Pos) /*!< 0x04000000 */
#define EXTI_EMR1_EM26 EXTI_EMR1_EM26_Msk /*!< Event Mask on line 26 */
#define EXTI_EMR1_EM27_Pos (27U)
#define EXTI_EMR1_EM27_Msk (0x1UL << EXTI_EMR1_EM27_Pos) /*!< 0x08000000 */
#define EXTI_EMR1_EM27 EXTI_EMR1_EM27_Msk /*!< Event Mask on line 27 */
#define EXTI_EMR1_EM28_Pos (28U)
#define EXTI_EMR1_EM28_Msk (0x1UL << EXTI_EMR1_EM28_Pos) /*!< 0x10000000 */
#define EXTI_EMR1_EM28 EXTI_EMR1_EM28_Msk /*!< Event Mask on line 28 */
#define EXTI_EMR1_EM29_Pos (29U)
#define EXTI_EMR1_EM29_Msk (0x1UL << EXTI_EMR1_EM29_Pos) /*!< 0x20000000 */
#define EXTI_EMR1_EM29 EXTI_EMR1_EM29_Msk /*!< Event Mask on line 29 */
#define EXTI_EMR1_EM30_Pos (30U)
#define EXTI_EMR1_EM30_Msk (0x1UL << EXTI_EMR1_EM30_Pos) /*!< 0x40000000 */
#define EXTI_EMR1_EM30 EXTI_EMR1_EM30_Msk /*!< Event Mask on line 30 */
/****************** Bit definition for EXTI_RTSR1 register ******************/
#define EXTI_RTSR1_RT0_Pos (0U)
#define EXTI_RTSR1_RT0_Msk (0x1UL << EXTI_RTSR1_RT0_Pos) /*!< 0x00000001 */
#define EXTI_RTSR1_RT0 EXTI_RTSR1_RT0_Msk /*!< Rising trigger event configuration bit of line 0 */
#define EXTI_RTSR1_RT1_Pos (1U)
#define EXTI_RTSR1_RT1_Msk (0x1UL << EXTI_RTSR1_RT1_Pos) /*!< 0x00000002 */
#define EXTI_RTSR1_RT1 EXTI_RTSR1_RT1_Msk /*!< Rising trigger event configuration bit of line 1 */
#define EXTI_RTSR1_RT2_Pos (2U)
#define EXTI_RTSR1_RT2_Msk (0x1UL << EXTI_RTSR1_RT2_Pos) /*!< 0x00000004 */
#define EXTI_RTSR1_RT2 EXTI_RTSR1_RT2_Msk /*!< Rising trigger event configuration bit of line 2 */
#define EXTI_RTSR1_RT3_Pos (3U)
#define EXTI_RTSR1_RT3_Msk (0x1UL << EXTI_RTSR1_RT3_Pos) /*!< 0x00000008 */
#define EXTI_RTSR1_RT3 EXTI_RTSR1_RT3_Msk /*!< Rising trigger event configuration bit of line 3 */
#define EXTI_RTSR1_RT4_Pos (4U)
#define EXTI_RTSR1_RT4_Msk (0x1UL << EXTI_RTSR1_RT4_Pos) /*!< 0x00000010 */
#define EXTI_RTSR1_RT4 EXTI_RTSR1_RT4_Msk /*!< Rising trigger event configuration bit of line 4 */
#define EXTI_RTSR1_RT5_Pos (5U)
#define EXTI_RTSR1_RT5_Msk (0x1UL << EXTI_RTSR1_RT5_Pos) /*!< 0x00000020 */
#define EXTI_RTSR1_RT5 EXTI_RTSR1_RT5_Msk /*!< Rising trigger event configuration bit of line 5 */
#define EXTI_RTSR1_RT6_Pos (6U)
#define EXTI_RTSR1_RT6_Msk (0x1UL << EXTI_RTSR1_RT6_Pos) /*!< 0x00000040 */
#define EXTI_RTSR1_RT6 EXTI_RTSR1_RT6_Msk /*!< Rising trigger event configuration bit of line 6 */
#define EXTI_RTSR1_RT7_Pos (7U)
#define EXTI_RTSR1_RT7_Msk (0x1UL << EXTI_RTSR1_RT7_Pos) /*!< 0x00000080 */
#define EXTI_RTSR1_RT7 EXTI_RTSR1_RT7_Msk /*!< Rising trigger event configuration bit of line 7 */
#define EXTI_RTSR1_RT8_Pos (8U)
#define EXTI_RTSR1_RT8_Msk (0x1UL << EXTI_RTSR1_RT8_Pos) /*!< 0x00000100 */
#define EXTI_RTSR1_RT8 EXTI_RTSR1_RT8_Msk /*!< Rising trigger event configuration bit of line 8 */
#define EXTI_RTSR1_RT9_Pos (9U)
#define EXTI_RTSR1_RT9_Msk (0x1UL << EXTI_RTSR1_RT9_Pos) /*!< 0x00000200 */
#define EXTI_RTSR1_RT9 EXTI_RTSR1_RT9_Msk /*!< Rising trigger event configuration bit of line 9 */
#define EXTI_RTSR1_RT10_Pos (10U)
#define EXTI_RTSR1_RT10_Msk (0x1UL << EXTI_RTSR1_RT10_Pos) /*!< 0x00000400 */
#define EXTI_RTSR1_RT10 EXTI_RTSR1_RT10_Msk /*!< Rising trigger event configuration bit of line 10 */
#define EXTI_RTSR1_RT11_Pos (11U)
#define EXTI_RTSR1_RT11_Msk (0x1UL << EXTI_RTSR1_RT11_Pos) /*!< 0x00000800 */
#define EXTI_RTSR1_RT11 EXTI_RTSR1_RT11_Msk /*!< Rising trigger event configuration bit of line 11 */
#define EXTI_RTSR1_RT12_Pos (12U)
#define EXTI_RTSR1_RT12_Msk (0x1UL << EXTI_RTSR1_RT12_Pos) /*!< 0x00001000 */
#define EXTI_RTSR1_RT12 EXTI_RTSR1_RT12_Msk /*!< Rising trigger event configuration bit of line 12 */
#define EXTI_RTSR1_RT13_Pos (13U)
#define EXTI_RTSR1_RT13_Msk (0x1UL << EXTI_RTSR1_RT13_Pos) /*!< 0x00002000 */
#define EXTI_RTSR1_RT13 EXTI_RTSR1_RT13_Msk /*!< Rising trigger event configuration bit of line 13 */
#define EXTI_RTSR1_RT14_Pos (14U)
#define EXTI_RTSR1_RT14_Msk (0x1UL << EXTI_RTSR1_RT14_Pos) /*!< 0x00004000 */
#define EXTI_RTSR1_RT14 EXTI_RTSR1_RT14_Msk /*!< Rising trigger event configuration bit of line 14 */
#define EXTI_RTSR1_RT15_Pos (15U)
#define EXTI_RTSR1_RT15_Msk (0x1UL << EXTI_RTSR1_RT15_Pos) /*!< 0x00008000 */
#define EXTI_RTSR1_RT15 EXTI_RTSR1_RT15_Msk /*!< Rising trigger event configuration bit of line 15 */
#define EXTI_RTSR1_RT16_Pos (16U)
#define EXTI_RTSR1_RT16_Msk (0x1UL << EXTI_RTSR1_RT16_Pos) /*!< 0x00010000 */
#define EXTI_RTSR1_RT16 EXTI_RTSR1_RT16_Msk /*!< Rising trigger event configuration bit of line 16 */
#define EXTI_RTSR1_RT17_Pos (17U)
#define EXTI_RTSR1_RT17_Msk (0x1UL << EXTI_RTSR1_RT17_Pos) /*!< 0x00020000 */
#define EXTI_RTSR1_RT17 EXTI_RTSR1_RT17_Msk /*!< Rising trigger event configuration bit of line 17 */
#define EXTI_RTSR1_RT19_Pos (19U)
#define EXTI_RTSR1_RT19_Msk (0x1UL << EXTI_RTSR1_RT19_Pos) /*!< 0x00080000 */
#define EXTI_RTSR1_RT19 EXTI_RTSR1_RT19_Msk /*!< Rising trigger event configuration bit of line 19 */
#define EXTI_RTSR1_RT20_Pos (20U)
#define EXTI_RTSR1_RT20_Msk (0x1UL << EXTI_RTSR1_RT20_Pos) /*!< 0x00100000 */
#define EXTI_RTSR1_RT20 EXTI_RTSR1_RT20_Msk /*!< Rising trigger event configuration bit of line 20 */
#define EXTI_RTSR1_RT21_Pos (21U)
#define EXTI_RTSR1_RT21_Msk (0x1UL << EXTI_RTSR1_RT21_Pos) /*!< 0x00200000 */
#define EXTI_RTSR1_RT21 EXTI_RTSR1_RT21_Msk /*!< Rising trigger event configuration bit of line 21 */
#define EXTI_RTSR1_RT22_Pos (22U)
#define EXTI_RTSR1_RT22_Msk (0x1UL << EXTI_RTSR1_RT22_Pos) /*!< 0x00400000 */
#define EXTI_RTSR1_RT22 EXTI_RTSR1_RT22_Msk /*!< Rising trigger event configuration bit of line 22 */
#define EXTI_RTSR1_RT29_Pos (29U)
#define EXTI_RTSR1_RT29_Msk (0x1UL << EXTI_RTSR1_RT29_Pos) /*!< 0x20000000 */
#define EXTI_RTSR1_RT29 EXTI_RTSR1_RT29_Msk /*!< Rising trigger event configuration bit of line 29 */
#define EXTI_RTSR1_RT30_Pos (30U)
#define EXTI_RTSR1_RT30_Msk (0x1UL << EXTI_RTSR1_RT30_Pos) /*!< 0x40000000 */
#define EXTI_RTSR1_RT30 EXTI_RTSR1_RT30_Msk /*!< Rising trigger event configuration bit of line 30 */
/****************** Bit definition for EXTI_FTSR1 register ******************/
#define EXTI_FTSR1_FT0_Pos (0U)
#define EXTI_FTSR1_FT0_Msk (0x1UL << EXTI_FTSR1_FT0_Pos) /*!< 0x00000001 */
#define EXTI_FTSR1_FT0 EXTI_FTSR1_FT0_Msk /*!< Falling trigger event configuration bit of line 0 */
#define EXTI_FTSR1_FT1_Pos (1U)
#define EXTI_FTSR1_FT1_Msk (0x1UL << EXTI_FTSR1_FT1_Pos) /*!< 0x00000002 */
#define EXTI_FTSR1_FT1 EXTI_FTSR1_FT1_Msk /*!< Falling trigger event configuration bit of line 1 */
#define EXTI_FTSR1_FT2_Pos (2U)
#define EXTI_FTSR1_FT2_Msk (0x1UL << EXTI_FTSR1_FT2_Pos) /*!< 0x00000004 */
#define EXTI_FTSR1_FT2 EXTI_FTSR1_FT2_Msk /*!< Falling trigger event configuration bit of line 2 */
#define EXTI_FTSR1_FT3_Pos (3U)
#define EXTI_FTSR1_FT3_Msk (0x1UL << EXTI_FTSR1_FT3_Pos) /*!< 0x00000008 */
#define EXTI_FTSR1_FT3 EXTI_FTSR1_FT3_Msk /*!< Falling trigger event configuration bit of line 3 */
#define EXTI_FTSR1_FT4_Pos (4U)
#define EXTI_FTSR1_FT4_Msk (0x1UL << EXTI_FTSR1_FT4_Pos) /*!< 0x00000010 */
#define EXTI_FTSR1_FT4 EXTI_FTSR1_FT4_Msk /*!< Falling trigger event configuration bit of line 4 */
#define EXTI_FTSR1_FT5_Pos (5U)
#define EXTI_FTSR1_FT5_Msk (0x1UL << EXTI_FTSR1_FT5_Pos) /*!< 0x00000020 */
#define EXTI_FTSR1_FT5 EXTI_FTSR1_FT5_Msk /*!< Falling trigger event configuration bit of line 5 */
#define EXTI_FTSR1_FT6_Pos (6U)
#define EXTI_FTSR1_FT6_Msk (0x1UL << EXTI_FTSR1_FT6_Pos) /*!< 0x00000040 */
#define EXTI_FTSR1_FT6 EXTI_FTSR1_FT6_Msk /*!< Falling trigger event configuration bit of line 6 */
#define EXTI_FTSR1_FT7_Pos (7U)
#define EXTI_FTSR1_FT7_Msk (0x1UL << EXTI_FTSR1_FT7_Pos) /*!< 0x00000080 */
#define EXTI_FTSR1_FT7 EXTI_FTSR1_FT7_Msk /*!< Falling trigger event configuration bit of line 7 */
#define EXTI_FTSR1_FT8_Pos (8U)
#define EXTI_FTSR1_FT8_Msk (0x1UL << EXTI_FTSR1_FT8_Pos) /*!< 0x00000100 */
#define EXTI_FTSR1_FT8 EXTI_FTSR1_FT8_Msk /*!< Falling trigger event configuration bit of line 8 */
#define EXTI_FTSR1_FT9_Pos (9U)
#define EXTI_FTSR1_FT9_Msk (0x1UL << EXTI_FTSR1_FT9_Pos) /*!< 0x00000200 */
#define EXTI_FTSR1_FT9 EXTI_FTSR1_FT9_Msk /*!< Falling trigger event configuration bit of line 9 */
#define EXTI_FTSR1_FT10_Pos (10U)
#define EXTI_FTSR1_FT10_Msk (0x1UL << EXTI_FTSR1_FT10_Pos) /*!< 0x00000400 */
#define EXTI_FTSR1_FT10 EXTI_FTSR1_FT10_Msk /*!< Falling trigger event configuration bit of line 10 */
#define EXTI_FTSR1_FT11_Pos (11U)
#define EXTI_FTSR1_FT11_Msk (0x1UL << EXTI_FTSR1_FT11_Pos) /*!< 0x00000800 */
#define EXTI_FTSR1_FT11 EXTI_FTSR1_FT11_Msk /*!< Falling trigger event configuration bit of line 11 */
#define EXTI_FTSR1_FT12_Pos (12U)
#define EXTI_FTSR1_FT12_Msk (0x1UL << EXTI_FTSR1_FT12_Pos) /*!< 0x00001000 */
#define EXTI_FTSR1_FT12 EXTI_FTSR1_FT12_Msk /*!< Falling trigger event configuration bit of line 12 */
#define EXTI_FTSR1_FT13_Pos (13U)
#define EXTI_FTSR1_FT13_Msk (0x1UL << EXTI_FTSR1_FT13_Pos) /*!< 0x00002000 */
#define EXTI_FTSR1_FT13 EXTI_FTSR1_FT13_Msk /*!< Falling trigger event configuration bit of line 13 */
#define EXTI_FTSR1_FT14_Pos (14U)
#define EXTI_FTSR1_FT14_Msk (0x1UL << EXTI_FTSR1_FT14_Pos) /*!< 0x00004000 */
#define EXTI_FTSR1_FT14 EXTI_FTSR1_FT14_Msk /*!< Falling trigger event configuration bit of line 14 */
#define EXTI_FTSR1_FT15_Pos (15U)
#define EXTI_FTSR1_FT15_Msk (0x1UL << EXTI_FTSR1_FT15_Pos) /*!< 0x00008000 */
#define EXTI_FTSR1_FT15 EXTI_FTSR1_FT15_Msk /*!< Falling trigger event configuration bit of line 15 */
#define EXTI_FTSR1_FT16_Pos (16U)
#define EXTI_FTSR1_FT16_Msk (0x1UL << EXTI_FTSR1_FT16_Pos) /*!< 0x00010000 */
#define EXTI_FTSR1_FT16 EXTI_FTSR1_FT16_Msk /*!< Falling trigger event configuration bit of line 16 */
#define EXTI_FTSR1_FT17_Pos (17U)
#define EXTI_FTSR1_FT17_Msk (0x1UL << EXTI_FTSR1_FT17_Pos) /*!< 0x00020000 */
#define EXTI_FTSR1_FT17 EXTI_FTSR1_FT17_Msk /*!< Falling trigger event configuration bit of line 17 */
#define EXTI_FTSR1_FT19_Pos (19U)
#define EXTI_FTSR1_FT19_Msk (0x1UL << EXTI_FTSR1_FT19_Pos) /*!< 0x00080000 */
#define EXTI_FTSR1_FT19 EXTI_FTSR1_FT19_Msk /*!< Falling trigger event configuration bit of line 19 */
#define EXTI_FTSR1_FT20_Pos (20U)
#define EXTI_FTSR1_FT20_Msk (0x1UL << EXTI_FTSR1_FT20_Pos) /*!< 0x00100000 */
#define EXTI_FTSR1_FT20 EXTI_FTSR1_FT20_Msk /*!< Falling trigger event configuration bit of line 20 */
#define EXTI_FTSR1_FT21_Pos (21U)
#define EXTI_FTSR1_FT21_Msk (0x1UL << EXTI_FTSR1_FT21_Pos) /*!< 0x00200000 */
#define EXTI_FTSR1_FT21 EXTI_FTSR1_FT21_Msk /*!< Falling trigger event configuration bit of line 21 */
#define EXTI_FTSR1_FT22_Pos (22U)
#define EXTI_FTSR1_FT22_Msk (0x1UL << EXTI_FTSR1_FT22_Pos) /*!< 0x00400000 */
#define EXTI_FTSR1_FT22 EXTI_FTSR1_FT22_Msk /*!< Falling trigger event configuration bit of line 22 */
#define EXTI_FTSR1_FT29_Pos (29U)
#define EXTI_FTSR1_FT29_Msk (0x1UL << EXTI_FTSR1_FT29_Pos) /*!< 0x20000000 */
#define EXTI_FTSR1_FT29 EXTI_FTSR1_FT29_Msk /*!< Falling trigger event configuration bit of line 29 */
#define EXTI_FTSR1_FT30_Pos (30U)
#define EXTI_FTSR1_FT30_Msk (0x1UL << EXTI_FTSR1_FT30_Pos) /*!< 0x40000000 */
#define EXTI_FTSR1_FT30 EXTI_FTSR1_FT30_Msk /*!< Falling trigger event configuration bit of line 30 */
/****************** Bit definition for EXTI_SWIER1 register *****************/
#define EXTI_SWIER1_SWI0_Pos (0U)
#define EXTI_SWIER1_SWI0_Msk (0x1UL << EXTI_SWIER1_SWI0_Pos) /*!< 0x00000001 */
#define EXTI_SWIER1_SWI0 EXTI_SWIER1_SWI0_Msk /*!< Software Interrupt on line 0 */
#define EXTI_SWIER1_SWI1_Pos (1U)
#define EXTI_SWIER1_SWI1_Msk (0x1UL << EXTI_SWIER1_SWI1_Pos) /*!< 0x00000002 */
#define EXTI_SWIER1_SWI1 EXTI_SWIER1_SWI1_Msk /*!< Software Interrupt on line 1 */
#define EXTI_SWIER1_SWI2_Pos (2U)
#define EXTI_SWIER1_SWI2_Msk (0x1UL << EXTI_SWIER1_SWI2_Pos) /*!< 0x00000004 */
#define EXTI_SWIER1_SWI2 EXTI_SWIER1_SWI2_Msk /*!< Software Interrupt on line 2 */
#define EXTI_SWIER1_SWI3_Pos (3U)
#define EXTI_SWIER1_SWI3_Msk (0x1UL << EXTI_SWIER1_SWI3_Pos) /*!< 0x00000008 */
#define EXTI_SWIER1_SWI3 EXTI_SWIER1_SWI3_Msk /*!< Software Interrupt on line 3 */
#define EXTI_SWIER1_SWI4_Pos (4U)
#define EXTI_SWIER1_SWI4_Msk (0x1UL << EXTI_SWIER1_SWI4_Pos) /*!< 0x00000010 */
#define EXTI_SWIER1_SWI4 EXTI_SWIER1_SWI4_Msk /*!< Software Interrupt on line 4 */
#define EXTI_SWIER1_SWI5_Pos (5U)
#define EXTI_SWIER1_SWI5_Msk (0x1UL << EXTI_SWIER1_SWI5_Pos) /*!< 0x00000020 */
#define EXTI_SWIER1_SWI5 EXTI_SWIER1_SWI5_Msk /*!< Software Interrupt on line 5 */
#define EXTI_SWIER1_SWI6_Pos (6U)
#define EXTI_SWIER1_SWI6_Msk (0x1UL << EXTI_SWIER1_SWI6_Pos) /*!< 0x00000040 */
#define EXTI_SWIER1_SWI6 EXTI_SWIER1_SWI6_Msk /*!< Software Interrupt on line 6 */
#define EXTI_SWIER1_SWI7_Pos (7U)
#define EXTI_SWIER1_SWI7_Msk (0x1UL << EXTI_SWIER1_SWI7_Pos) /*!< 0x00000080 */
#define EXTI_SWIER1_SWI7 EXTI_SWIER1_SWI7_Msk /*!< Software Interrupt on line 7 */
#define EXTI_SWIER1_SWI8_Pos (8U)
#define EXTI_SWIER1_SWI8_Msk (0x1UL << EXTI_SWIER1_SWI8_Pos) /*!< 0x00000100 */
#define EXTI_SWIER1_SWI8 EXTI_SWIER1_SWI8_Msk /*!< Software Interrupt on line 8 */
#define EXTI_SWIER1_SWI9_Pos (9U)
#define EXTI_SWIER1_SWI9_Msk (0x1UL << EXTI_SWIER1_SWI9_Pos) /*!< 0x00000200 */
#define EXTI_SWIER1_SWI9 EXTI_SWIER1_SWI9_Msk /*!< Software Interrupt on line 9 */
#define EXTI_SWIER1_SWI10_Pos (10U)
#define EXTI_SWIER1_SWI10_Msk (0x1UL << EXTI_SWIER1_SWI10_Pos) /*!< 0x00000400 */
#define EXTI_SWIER1_SWI10 EXTI_SWIER1_SWI10_Msk /*!< Software Interrupt on line 10 */
#define EXTI_SWIER1_SWI11_Pos (11U)
#define EXTI_SWIER1_SWI11_Msk (0x1UL << EXTI_SWIER1_SWI11_Pos) /*!< 0x00000800 */
#define EXTI_SWIER1_SWI11 EXTI_SWIER1_SWI11_Msk /*!< Software Interrupt on line 11 */
#define EXTI_SWIER1_SWI12_Pos (12U)
#define EXTI_SWIER1_SWI12_Msk (0x1UL << EXTI_SWIER1_SWI12_Pos) /*!< 0x00001000 */
#define EXTI_SWIER1_SWI12 EXTI_SWIER1_SWI12_Msk /*!< Software Interrupt on line 12 */
#define EXTI_SWIER1_SWI13_Pos (13U)
#define EXTI_SWIER1_SWI13_Msk (0x1UL << EXTI_SWIER1_SWI13_Pos) /*!< 0x00002000 */
#define EXTI_SWIER1_SWI13 EXTI_SWIER1_SWI13_Msk /*!< Software Interrupt on line 13 */
#define EXTI_SWIER1_SWI14_Pos (14U)
#define EXTI_SWIER1_SWI14_Msk (0x1UL << EXTI_SWIER1_SWI14_Pos) /*!< 0x00004000 */
#define EXTI_SWIER1_SWI14 EXTI_SWIER1_SWI14_Msk /*!< Software Interrupt on line 14 */
#define EXTI_SWIER1_SWI15_Pos (15U)
#define EXTI_SWIER1_SWI15_Msk (0x1UL << EXTI_SWIER1_SWI15_Pos) /*!< 0x00008000 */
#define EXTI_SWIER1_SWI15 EXTI_SWIER1_SWI15_Msk /*!< Software Interrupt on line 15 */
#define EXTI_SWIER1_SWI16_Pos (16U)
#define EXTI_SWIER1_SWI16_Msk (0x1UL << EXTI_SWIER1_SWI16_Pos) /*!< 0x00010000 */
#define EXTI_SWIER1_SWI16 EXTI_SWIER1_SWI16_Msk /*!< Software Interrupt on line 16 */
#define EXTI_SWIER1_SWI17_Pos (17U)
#define EXTI_SWIER1_SWI17_Msk (0x1UL << EXTI_SWIER1_SWI17_Pos) /*!< 0x00020000 */
#define EXTI_SWIER1_SWI17 EXTI_SWIER1_SWI17_Msk /*!< Software Interrupt on line 17 */
#define EXTI_SWIER1_SWI19_Pos (19U)
#define EXTI_SWIER1_SWI19_Msk (0x1UL << EXTI_SWIER1_SWI19_Pos) /*!< 0x00080000 */
#define EXTI_SWIER1_SWI19 EXTI_SWIER1_SWI19_Msk /*!< Software Interrupt on line 19 */
#define EXTI_SWIER1_SWI20_Pos (20U)
#define EXTI_SWIER1_SWI20_Msk (0x1UL << EXTI_SWIER1_SWI20_Pos) /*!< 0x00100000 */
#define EXTI_SWIER1_SWI20 EXTI_SWIER1_SWI20_Msk /*!< Software Interrupt on line 20 */
#define EXTI_SWIER1_SWI21_Pos (21U)
#define EXTI_SWIER1_SWI21_Msk (0x1UL << EXTI_SWIER1_SWI21_Pos) /*!< 0x00200000 */
#define EXTI_SWIER1_SWI21 EXTI_SWIER1_SWI21_Msk /*!< Software Interrupt on line 21 */
#define EXTI_SWIER1_SWI22_Pos (22U)
#define EXTI_SWIER1_SWI22_Msk (0x1UL << EXTI_SWIER1_SWI22_Pos) /*!< 0x00400000 */
#define EXTI_SWIER1_SWI22 EXTI_SWIER1_SWI22_Msk /*!< Software Interrupt on line 22 */
#define EXTI_SWIER1_SWI29_Pos (29U)
#define EXTI_SWIER1_SWI29_Msk (0x1UL << EXTI_SWIER1_SWI29_Pos) /*!< 0x20000000 */
#define EXTI_SWIER1_SWI29 EXTI_SWIER1_SWI29_Msk /*!< Software Interrupt on line 29 */
#define EXTI_SWIER1_SWI30_Pos (30U)
#define EXTI_SWIER1_SWI30_Msk (0x1UL << EXTI_SWIER1_SWI30_Pos) /*!< 0x40000000 */
#define EXTI_SWIER1_SWI30 EXTI_SWIER1_SWI30_Msk /*!< Software Interrupt on line 30 */
/******************* Bit definition for EXTI_PR1 register *******************/
#define EXTI_PR1_PIF0_Pos (0U)
#define EXTI_PR1_PIF0_Msk (0x1UL << EXTI_PR1_PIF0_Pos) /*!< 0x00000001 */
#define EXTI_PR1_PIF0 EXTI_PR1_PIF0_Msk /*!< Pending bit for line 0 */
#define EXTI_PR1_PIF1_Pos (1U)
#define EXTI_PR1_PIF1_Msk (0x1UL << EXTI_PR1_PIF1_Pos) /*!< 0x00000002 */
#define EXTI_PR1_PIF1 EXTI_PR1_PIF1_Msk /*!< Pending bit for line 1 */
#define EXTI_PR1_PIF2_Pos (2U)
#define EXTI_PR1_PIF2_Msk (0x1UL << EXTI_PR1_PIF2_Pos) /*!< 0x00000004 */
#define EXTI_PR1_PIF2 EXTI_PR1_PIF2_Msk /*!< Pending bit for line 2 */
#define EXTI_PR1_PIF3_Pos (3U)
#define EXTI_PR1_PIF3_Msk (0x1UL << EXTI_PR1_PIF3_Pos) /*!< 0x00000008 */
#define EXTI_PR1_PIF3 EXTI_PR1_PIF3_Msk /*!< Pending bit for line 3 */
#define EXTI_PR1_PIF4_Pos (4U)
#define EXTI_PR1_PIF4_Msk (0x1UL << EXTI_PR1_PIF4_Pos) /*!< 0x00000010 */
#define EXTI_PR1_PIF4 EXTI_PR1_PIF4_Msk /*!< Pending bit for line 4 */
#define EXTI_PR1_PIF5_Pos (5U)
#define EXTI_PR1_PIF5_Msk (0x1UL << EXTI_PR1_PIF5_Pos) /*!< 0x00000020 */
#define EXTI_PR1_PIF5 EXTI_PR1_PIF5_Msk /*!< Pending bit for line 5 */
#define EXTI_PR1_PIF6_Pos (6U)
#define EXTI_PR1_PIF6_Msk (0x1UL << EXTI_PR1_PIF6_Pos) /*!< 0x00000040 */
#define EXTI_PR1_PIF6 EXTI_PR1_PIF6_Msk /*!< Pending bit for line 6 */
#define EXTI_PR1_PIF7_Pos (7U)
#define EXTI_PR1_PIF7_Msk (0x1UL << EXTI_PR1_PIF7_Pos) /*!< 0x00000080 */
#define EXTI_PR1_PIF7 EXTI_PR1_PIF7_Msk /*!< Pending bit for line 7 */
#define EXTI_PR1_PIF8_Pos (8U)
#define EXTI_PR1_PIF8_Msk (0x1UL << EXTI_PR1_PIF8_Pos) /*!< 0x00000100 */
#define EXTI_PR1_PIF8 EXTI_PR1_PIF8_Msk /*!< Pending bit for line 8 */
#define EXTI_PR1_PIF9_Pos (9U)
#define EXTI_PR1_PIF9_Msk (0x1UL << EXTI_PR1_PIF9_Pos) /*!< 0x00000200 */
#define EXTI_PR1_PIF9 EXTI_PR1_PIF9_Msk /*!< Pending bit for line 9 */
#define EXTI_PR1_PIF10_Pos (10U)
#define EXTI_PR1_PIF10_Msk (0x1UL << EXTI_PR1_PIF10_Pos) /*!< 0x00000400 */
#define EXTI_PR1_PIF10 EXTI_PR1_PIF10_Msk /*!< Pending bit for line 10 */
#define EXTI_PR1_PIF11_Pos (11U)
#define EXTI_PR1_PIF11_Msk (0x1UL << EXTI_PR1_PIF11_Pos) /*!< 0x00000800 */
#define EXTI_PR1_PIF11 EXTI_PR1_PIF11_Msk /*!< Pending bit for line 11 */
#define EXTI_PR1_PIF12_Pos (12U)
#define EXTI_PR1_PIF12_Msk (0x1UL << EXTI_PR1_PIF12_Pos) /*!< 0x00001000 */
#define EXTI_PR1_PIF12 EXTI_PR1_PIF12_Msk /*!< Pending bit for line 12 */
#define EXTI_PR1_PIF13_Pos (13U)
#define EXTI_PR1_PIF13_Msk (0x1UL << EXTI_PR1_PIF13_Pos) /*!< 0x00002000 */
#define EXTI_PR1_PIF13 EXTI_PR1_PIF13_Msk /*!< Pending bit for line 13 */
#define EXTI_PR1_PIF14_Pos (14U)
#define EXTI_PR1_PIF14_Msk (0x1UL << EXTI_PR1_PIF14_Pos) /*!< 0x00004000 */
#define EXTI_PR1_PIF14 EXTI_PR1_PIF14_Msk /*!< Pending bit for line 14 */
#define EXTI_PR1_PIF15_Pos (15U)
#define EXTI_PR1_PIF15_Msk (0x1UL << EXTI_PR1_PIF15_Pos) /*!< 0x00008000 */
#define EXTI_PR1_PIF15 EXTI_PR1_PIF15_Msk /*!< Pending bit for line 15 */
#define EXTI_PR1_PIF16_Pos (16U)
#define EXTI_PR1_PIF16_Msk (0x1UL << EXTI_PR1_PIF16_Pos) /*!< 0x00010000 */
#define EXTI_PR1_PIF16 EXTI_PR1_PIF16_Msk /*!< Pending bit for line 16 */
#define EXTI_PR1_PIF17_Pos (17U)
#define EXTI_PR1_PIF17_Msk (0x1UL << EXTI_PR1_PIF17_Pos) /*!< 0x00020000 */
#define EXTI_PR1_PIF17 EXTI_PR1_PIF17_Msk /*!< Pending bit for line 17 */
#define EXTI_PR1_PIF19_Pos (19U)
#define EXTI_PR1_PIF19_Msk (0x1UL << EXTI_PR1_PIF19_Pos) /*!< 0x00080000 */
#define EXTI_PR1_PIF19 EXTI_PR1_PIF19_Msk /*!< Pending bit for line 19 */
#define EXTI_PR1_PIF20_Pos (20U)
#define EXTI_PR1_PIF20_Msk (0x1UL << EXTI_PR1_PIF20_Pos) /*!< 0x00100000 */
#define EXTI_PR1_PIF20 EXTI_PR1_PIF20_Msk /*!< Pending bit for line 20 */
#define EXTI_PR1_PIF21_Pos (21U)
#define EXTI_PR1_PIF21_Msk (0x1UL << EXTI_PR1_PIF21_Pos) /*!< 0x00200000 */
#define EXTI_PR1_PIF21 EXTI_PR1_PIF21_Msk /*!< Pending bit for line 21 */
#define EXTI_PR1_PIF22_Pos (22U)
#define EXTI_PR1_PIF22_Msk (0x1UL << EXTI_PR1_PIF22_Pos) /*!< 0x00400000 */
#define EXTI_PR1_PIF22 EXTI_PR1_PIF22_Msk /*!< Pending bit for line 22 */
#define EXTI_PR1_PIF29_Pos (29U)
#define EXTI_PR1_PIF29_Msk (0x1UL << EXTI_PR1_PIF29_Pos) /*!< 0x20000000 */
#define EXTI_PR1_PIF29 EXTI_PR1_PIF29_Msk /*!< Pending bit for line 29 */
#define EXTI_PR1_PIF30_Pos (30U)
#define EXTI_PR1_PIF30_Msk (0x1UL << EXTI_PR1_PIF30_Pos) /*!< 0x40000000 */
#define EXTI_PR1_PIF30 EXTI_PR1_PIF30_Msk /*!< Pending bit for line 30 */
/******************* Bit definition for EXTI_IMR2 register ******************/
#define EXTI_IMR2_IM34_Pos (2U)
#define EXTI_IMR2_IM34_Msk (0x1UL << EXTI_IMR2_IM34_Pos) /*!< 0x00000004 */
#define EXTI_IMR2_IM34 EXTI_IMR2_IM34_Msk /*!< Interrupt Mask on line 34 */
#define EXTI_IMR2_IM36_Pos (4U)
#define EXTI_IMR2_IM36_Msk (0x1UL << EXTI_IMR2_IM36_Pos) /*!< 0x00000010 */
#define EXTI_IMR2_IM36 EXTI_IMR2_IM36_Msk /*!< Interrupt Mask on line 36 */
#define EXTI_IMR2_IM37_Pos (5U)
#define EXTI_IMR2_IM37_Msk (0x1UL << EXTI_IMR2_IM37_Pos) /*!< 0x00000020 */
#define EXTI_IMR2_IM37 EXTI_IMR2_IM37_Msk /*!< Interrupt Mask on line 37 */
#define EXTI_IMR2_IM38_Pos (6U)
#define EXTI_IMR2_IM38_Msk (0x1UL << EXTI_IMR2_IM38_Pos) /*!< 0x00000040 */
#define EXTI_IMR2_IM38 EXTI_IMR2_IM38_Msk /*!< Interrupt Mask on line 38 */
#define EXTI_IMR2_IM39_Pos (7U)
#define EXTI_IMR2_IM39_Msk (0x1UL << EXTI_IMR2_IM39_Pos) /*!< 0x00000080 */
#define EXTI_IMR2_IM39 EXTI_IMR2_IM39_Msk /*!< Interrupt Mask on line 39 */
#define EXTI_IMR2_IM40_Pos (8U)
#define EXTI_IMR2_IM40_Msk (0x1UL << EXTI_IMR2_IM40_Pos) /*!< 0x00000100 */
#define EXTI_IMR2_IM40 EXTI_IMR2_IM40_Msk /*!< Interrupt Mask on line 40 */
#define EXTI_IMR2_IM41_Pos (9U)
#define EXTI_IMR2_IM41_Msk (0x1UL << EXTI_IMR2_IM41_Pos) /*!< 0x00000200 */
#define EXTI_IMR2_IM41 EXTI_IMR2_IM41_Msk /*!< Interrupt Mask on line 41 */
#define EXTI_IMR2_IM_Pos (0U)
#define EXTI_IMR2_IM_Msk (0x3F4UL << EXTI_IMR2_IM_Pos) /*!< 0x000003F4 */
#define EXTI_IMR2_IM EXTI_IMR2_IM_Msk /*!< Interrupt Mask all */
/******************* Bit definition for EXTI_EMR2 register ******************/
#define EXTI_EMR2_EM34_Pos (2U)
#define EXTI_EMR2_EM34_Msk (0x1UL << EXTI_EMR2_EM34_Pos) /*!< 0x00000004 */
#define EXTI_EMR2_EM34 EXTI_EMR2_EM34_Msk /*!< Event Mask on line 34 */
#define EXTI_EMR2_EM36_Pos (4U)
#define EXTI_EMR2_EM36_Msk (0x1UL << EXTI_EMR2_EM36_Pos) /*!< 0x00000010 */
#define EXTI_EMR2_EM36 EXTI_EMR2_EM36_Msk /*!< Event Mask on line 36 */
#define EXTI_EMR2_EM37_Pos (5U)
#define EXTI_EMR2_EM37_Msk (0x1UL << EXTI_EMR2_EM37_Pos) /*!< 0x00000020 */
#define EXTI_EMR2_EM37 EXTI_EMR2_EM37_Msk /*!< Event Mask on line 37 */
#define EXTI_EMR2_EM38_Pos (6U)
#define EXTI_EMR2_EM38_Msk (0x1UL << EXTI_EMR2_EM38_Pos) /*!< 0x00000040 */
#define EXTI_EMR2_EM38 EXTI_EMR2_EM38_Msk /*!< Event Mask on line 38 */
#define EXTI_EMR2_EM39_Pos (7U)
#define EXTI_EMR2_EM39_Msk (0x1UL << EXTI_EMR2_EM39_Pos) /*!< 0x00000080 */
#define EXTI_EMR2_EM39 EXTI_EMR2_EM39_Msk /*!< Event Mask on line 39 */
#define EXTI_EMR2_EM40_Pos (8U)
#define EXTI_EMR2_EM40_Msk (0x1UL << EXTI_EMR2_EM40_Pos) /*!< 0x00000100 */
#define EXTI_EMR2_EM40 EXTI_EMR2_EM40_Msk /*!< Event Mask on line 40 */
#define EXTI_EMR2_EM41_Pos (9U)
#define EXTI_EMR2_EM41_Msk (0x1UL << EXTI_EMR2_EM41_Pos) /*!< 0x00000200 */
#define EXTI_EMR2_EM41 EXTI_EMR2_EM41_Msk /*!< Event Mask on line 41 */
#define EXTI_EMR2_EM_Pos (0U)
#define EXTI_EMR2_EM_Msk (0x3F4UL << EXTI_EMR2_EM_Pos) /*!< 0x000003F4 */
#define EXTI_EMR2_EM EXTI_EMR2_EM_Msk /*!< Interrupt Mask all */
/****************** Bit definition for EXTI_RTSR2 register ******************/
#define EXTI_RTSR2_RT38_Pos (6U)
#define EXTI_RTSR2_RT38_Msk (0x1UL << EXTI_RTSR2_RT38_Pos) /*!< 0x00000040 */
#define EXTI_RTSR2_RT38 EXTI_RTSR2_RT38_Msk /*!< Rising trigger event configuration bit of line 38 */
#define EXTI_RTSR2_RT39_Pos (7U)
#define EXTI_RTSR2_RT39_Msk (0x1UL << EXTI_RTSR2_RT39_Pos) /*!< 0x00000080 */
#define EXTI_RTSR2_RT39 EXTI_RTSR2_RT39_Msk /*!< Rising trigger event configuration bit of line 39 */
#define EXTI_RTSR2_RT40_Pos (8U)
#define EXTI_RTSR2_RT40_Msk (0x1UL << EXTI_RTSR2_RT40_Pos) /*!< 0x00000100 */
#define EXTI_RTSR2_RT40 EXTI_RTSR2_RT40_Msk /*!< Rising trigger event configuration bit of line 40 */
#define EXTI_RTSR2_RT41_Pos (9U)
#define EXTI_RTSR2_RT41_Msk (0x1UL << EXTI_RTSR2_RT41_Pos) /*!< 0x00000200 */
#define EXTI_RTSR2_RT41 EXTI_RTSR2_RT41_Msk /*!< Rising trigger event configuration bit of line 41 */
/****************** Bit definition for EXTI_FTSR2 register ******************/
#define EXTI_FTSR2_FT38_Pos (6U)
#define EXTI_FTSR2_FT38_Msk (0x1UL << EXTI_FTSR2_FT38_Pos) /*!< 0x00000040 */
#define EXTI_FTSR2_FT38 EXTI_FTSR2_FT38_Msk /*!< Falling trigger event configuration bit of line 37 */
#define EXTI_FTSR2_FT39_Pos (7U)
#define EXTI_FTSR2_FT39_Msk (0x1UL << EXTI_FTSR2_FT39_Pos) /*!< 0x00000080 */
#define EXTI_FTSR2_FT39 EXTI_FTSR2_FT39_Msk /*!< Falling trigger event configuration bit of line 39 */
#define EXTI_FTSR2_FT40_Pos (8U)
#define EXTI_FTSR2_FT40_Msk (0x1UL << EXTI_FTSR2_FT40_Pos) /*!< 0x00000100 */
#define EXTI_FTSR2_FT40 EXTI_FTSR2_FT40_Msk /*!< Falling trigger event configuration bit of line 40 */
#define EXTI_FTSR2_FT41_Pos (9U)
#define EXTI_FTSR2_FT41_Msk (0x1UL << EXTI_FTSR2_FT41_Pos) /*!< 0x00000200 */
#define EXTI_FTSR2_FT41 EXTI_FTSR2_FT41_Msk /*!< Falling trigger event configuration bit of line 41 */
/****************** Bit definition for EXTI_SWIER2 register *****************/
#define EXTI_SWIER2_SWI38_Pos (6U)
#define EXTI_SWIER2_SWI38_Msk (0x1UL << EXTI_SWIER2_SWI38_Pos) /*!< 0x00000040 */
#define EXTI_SWIER2_SWI38 EXTI_SWIER2_SWI38_Msk /*!< Software Interrupt on line 38 */
#define EXTI_SWIER2_SWI39_Pos (7U)
#define EXTI_SWIER2_SWI39_Msk (0x1UL << EXTI_SWIER2_SWI39_Pos) /*!< 0x00000080 */
#define EXTI_SWIER2_SWI39 EXTI_SWIER2_SWI39_Msk /*!< Software Interrupt on line 39 */
#define EXTI_SWIER2_SWI40_Pos (8U)
#define EXTI_SWIER2_SWI40_Msk (0x1UL << EXTI_SWIER2_SWI40_Pos) /*!< 0x00000100 */
#define EXTI_SWIER2_SWI40 EXTI_SWIER2_SWI40_Msk /*!< Software Interrupt on line 40 */
#define EXTI_SWIER2_SWI41_Pos (9U)
#define EXTI_SWIER2_SWI41_Msk (0x1UL << EXTI_SWIER2_SWI41_Pos) /*!< 0x00000200 */
#define EXTI_SWIER2_SWI41 EXTI_SWIER2_SWI41_Msk /*!< Software Interrupt on line 41 */
/******************* Bit definition for EXTI_PR2 register *******************/
#define EXTI_PR2_PIF38_Pos (6U)
#define EXTI_PR2_PIF38_Msk (0x1UL << EXTI_PR2_PIF38_Pos) /*!< 0x00000040 */
#define EXTI_PR2_PIF38 EXTI_PR2_PIF38_Msk /*!< Pending bit for line 38 */
#define EXTI_PR2_PIF39_Pos (7U)
#define EXTI_PR2_PIF39_Msk (0x1UL << EXTI_PR2_PIF39_Pos) /*!< 0x00000080 */
#define EXTI_PR2_PIF39 EXTI_PR2_PIF39_Msk /*!< Pending bit for line 39 */
#define EXTI_PR2_PIF40_Pos (8U)
#define EXTI_PR2_PIF40_Msk (0x1UL << EXTI_PR2_PIF40_Pos) /*!< 0x00000100 */
#define EXTI_PR2_PIF40 EXTI_PR2_PIF40_Msk /*!< Pending bit for line 40 */
#define EXTI_PR2_PIF41_Pos (9U)
#define EXTI_PR2_PIF41_Msk (0x1UL << EXTI_PR2_PIF41_Pos) /*!< 0x00000200 */
#define EXTI_PR2_PIF41 EXTI_PR2_PIF41_Msk /*!< Pending bit for line 41 */
/******************************************************************************/
/* */
/* Flexible Datarate Controller Area Network */
/* */
/******************************************************************************/
/*!<FDCAN control and status registers */
/***************** Bit definition for FDCAN_CREL register *******************/
#define FDCAN_CREL_DAY_Pos (0U)
#define FDCAN_CREL_DAY_Msk (0xFFUL << FDCAN_CREL_DAY_Pos) /*!< 0x000000FF */
#define FDCAN_CREL_DAY FDCAN_CREL_DAY_Msk /*!<Timestamp Day */
#define FDCAN_CREL_MON_Pos (8U)
#define FDCAN_CREL_MON_Msk (0xFFUL << FDCAN_CREL_MON_Pos) /*!< 0x0000FF00 */
#define FDCAN_CREL_MON FDCAN_CREL_MON_Msk /*!<Timestamp Month */
#define FDCAN_CREL_YEAR_Pos (16U)
#define FDCAN_CREL_YEAR_Msk (0xFUL << FDCAN_CREL_YEAR_Pos) /*!< 0x000F0000 */
#define FDCAN_CREL_YEAR FDCAN_CREL_YEAR_Msk /*!<Timestamp Year */
#define FDCAN_CREL_SUBSTEP_Pos (20U)
#define FDCAN_CREL_SUBSTEP_Msk (0xFUL << FDCAN_CREL_SUBSTEP_Pos) /*!< 0x00F00000 */
#define FDCAN_CREL_SUBSTEP FDCAN_CREL_SUBSTEP_Msk /*!<Sub-step of Core release */
#define FDCAN_CREL_STEP_Pos (24U)
#define FDCAN_CREL_STEP_Msk (0xFUL << FDCAN_CREL_STEP_Pos) /*!< 0x0F000000 */
#define FDCAN_CREL_STEP FDCAN_CREL_STEP_Msk /*!<Step of Core release */
#define FDCAN_CREL_REL_Pos (28U)
#define FDCAN_CREL_REL_Msk (0xFUL << FDCAN_CREL_REL_Pos) /*!< 0xF0000000 */
#define FDCAN_CREL_REL FDCAN_CREL_REL_Msk /*!<Core release */
/***************** Bit definition for FDCAN_ENDN register *******************/
#define FDCAN_ENDN_ETV_Pos (0U)
#define FDCAN_ENDN_ETV_Msk (0xFFFFFFFFUL << FDCAN_ENDN_ETV_Pos) /*!< 0xFFFFFFFF */
#define FDCAN_ENDN_ETV FDCAN_ENDN_ETV_Msk /*!<Endianness Test Value */
/***************** Bit definition for FDCAN_DBTP register *******************/
#define FDCAN_DBTP_DSJW_Pos (0U)
#define FDCAN_DBTP_DSJW_Msk (0xFUL << FDCAN_DBTP_DSJW_Pos) /*!< 0x0000000F */
#define FDCAN_DBTP_DSJW FDCAN_DBTP_DSJW_Msk /*!<Synchronization Jump Width */
#define FDCAN_DBTP_DTSEG2_Pos (4U)
#define FDCAN_DBTP_DTSEG2_Msk (0xFUL << FDCAN_DBTP_DTSEG2_Pos) /*!< 0x000000F0 */
#define FDCAN_DBTP_DTSEG2 FDCAN_DBTP_DTSEG2_Msk /*!<Data time segment after sample point */
#define FDCAN_DBTP_DTSEG1_Pos (8U)
#define FDCAN_DBTP_DTSEG1_Msk (0x1FUL << FDCAN_DBTP_DTSEG1_Pos) /*!< 0x00001F00 */
#define FDCAN_DBTP_DTSEG1 FDCAN_DBTP_DTSEG1_Msk /*!<Data time segment before sample point */
#define FDCAN_DBTP_DBRP_Pos (16U)
#define FDCAN_DBTP_DBRP_Msk (0x1FUL << FDCAN_DBTP_DBRP_Pos) /*!< 0x001F0000 */
#define FDCAN_DBTP_DBRP FDCAN_DBTP_DBRP_Msk /*!<Data BIt Rate Prescaler */
#define FDCAN_DBTP_TDC_Pos (23U)
#define FDCAN_DBTP_TDC_Msk (0x1UL << FDCAN_DBTP_TDC_Pos) /*!< 0x00800000 */
#define FDCAN_DBTP_TDC FDCAN_DBTP_TDC_Msk /*!<Transceiver Delay Compensation */
/***************** Bit definition for FDCAN_TEST register *******************/
#define FDCAN_TEST_LBCK_Pos (4U)
#define FDCAN_TEST_LBCK_Msk (0x1UL << FDCAN_TEST_LBCK_Pos) /*!< 0x00000010 */
#define FDCAN_TEST_LBCK FDCAN_TEST_LBCK_Msk /*!<Loop Back mode */
#define FDCAN_TEST_TX_Pos (5U)
#define FDCAN_TEST_TX_Msk (0x3UL << FDCAN_TEST_TX_Pos) /*!< 0x00000060 */
#define FDCAN_TEST_TX FDCAN_TEST_TX_Msk /*!<Control of Transmit Pin */
#define FDCAN_TEST_RX_Pos (7U)
#define FDCAN_TEST_RX_Msk (0x1UL << FDCAN_TEST_RX_Pos) /*!< 0x00000080 */
#define FDCAN_TEST_RX FDCAN_TEST_RX_Msk /*!<Receive Pin */
/***************** Bit definition for FDCAN_RWD register ********************/
#define FDCAN_RWD_WDC_Pos (0U)
#define FDCAN_RWD_WDC_Msk (0xFFUL << FDCAN_RWD_WDC_Pos) /*!< 0x000000FF */
#define FDCAN_RWD_WDC FDCAN_RWD_WDC_Msk /*!<Watchdog configuration */
#define FDCAN_RWD_WDV_Pos (8U)
#define FDCAN_RWD_WDV_Msk (0xFFUL << FDCAN_RWD_WDV_Pos) /*!< 0x0000FF00 */
#define FDCAN_RWD_WDV FDCAN_RWD_WDV_Msk /*!<Watchdog value */
/***************** Bit definition for FDCAN_CCCR register ********************/
#define FDCAN_CCCR_INIT_Pos (0U)
#define FDCAN_CCCR_INIT_Msk (0x1UL << FDCAN_CCCR_INIT_Pos) /*!< 0x00000001 */
#define FDCAN_CCCR_INIT FDCAN_CCCR_INIT_Msk /*!<Initialization */
#define FDCAN_CCCR_CCE_Pos (1U)
#define FDCAN_CCCR_CCE_Msk (0x1UL << FDCAN_CCCR_CCE_Pos) /*!< 0x00000002 */
#define FDCAN_CCCR_CCE FDCAN_CCCR_CCE_Msk /*!<Configuration Change Enable */
#define FDCAN_CCCR_ASM_Pos (2U)
#define FDCAN_CCCR_ASM_Msk (0x1UL << FDCAN_CCCR_ASM_Pos) /*!< 0x00000004 */
#define FDCAN_CCCR_ASM FDCAN_CCCR_ASM_Msk /*!<ASM Restricted Operation Mode */
#define FDCAN_CCCR_CSA_Pos (3U)
#define FDCAN_CCCR_CSA_Msk (0x1UL << FDCAN_CCCR_CSA_Pos) /*!< 0x00000008 */
#define FDCAN_CCCR_CSA FDCAN_CCCR_CSA_Msk /*!<Clock Stop Acknowledge */
#define FDCAN_CCCR_CSR_Pos (4U)
#define FDCAN_CCCR_CSR_Msk (0x1UL << FDCAN_CCCR_CSR_Pos) /*!< 0x00000010 */
#define FDCAN_CCCR_CSR FDCAN_CCCR_CSR_Msk /*!<Clock Stop Request */
#define FDCAN_CCCR_MON_Pos (5U)
#define FDCAN_CCCR_MON_Msk (0x1UL << FDCAN_CCCR_MON_Pos) /*!< 0x00000020 */
#define FDCAN_CCCR_MON FDCAN_CCCR_MON_Msk /*!<Bus Monitoring Mode */
#define FDCAN_CCCR_DAR_Pos (6U)
#define FDCAN_CCCR_DAR_Msk (0x1UL << FDCAN_CCCR_DAR_Pos) /*!< 0x00000040 */
#define FDCAN_CCCR_DAR FDCAN_CCCR_DAR_Msk /*!<Disable Automatic Retransmission */
#define FDCAN_CCCR_TEST_Pos (7U)
#define FDCAN_CCCR_TEST_Msk (0x1UL << FDCAN_CCCR_TEST_Pos) /*!< 0x00000080 */
#define FDCAN_CCCR_TEST FDCAN_CCCR_TEST_Msk /*!<Test Mode Enable */
#define FDCAN_CCCR_FDOE_Pos (8U)
#define FDCAN_CCCR_FDOE_Msk (0x1UL << FDCAN_CCCR_FDOE_Pos) /*!< 0x00000100 */
#define FDCAN_CCCR_FDOE FDCAN_CCCR_FDOE_Msk /*!<FD Operation Enable */
#define FDCAN_CCCR_BRSE_Pos (9U)
#define FDCAN_CCCR_BRSE_Msk (0x1UL << FDCAN_CCCR_BRSE_Pos) /*!< 0x00000200 */
#define FDCAN_CCCR_BRSE FDCAN_CCCR_BRSE_Msk /*!<FDCAN Bit Rate Switching */
#define FDCAN_CCCR_PXHD_Pos (12U)
#define FDCAN_CCCR_PXHD_Msk (0x1UL << FDCAN_CCCR_PXHD_Pos) /*!< 0x00001000 */
#define FDCAN_CCCR_PXHD FDCAN_CCCR_PXHD_Msk /*!<Protocol Exception Handling Disable */
#define FDCAN_CCCR_EFBI_Pos (13U)
#define FDCAN_CCCR_EFBI_Msk (0x1UL << FDCAN_CCCR_EFBI_Pos) /*!< 0x00002000 */
#define FDCAN_CCCR_EFBI FDCAN_CCCR_EFBI_Msk /*!<Edge Filtering during Bus Integration */
#define FDCAN_CCCR_TXP_Pos (14U)
#define FDCAN_CCCR_TXP_Msk (0x1UL << FDCAN_CCCR_TXP_Pos) /*!< 0x00004000 */
#define FDCAN_CCCR_TXP FDCAN_CCCR_TXP_Msk /*!<Two CAN bit times Pause */
#define FDCAN_CCCR_NISO_Pos (15U)
#define FDCAN_CCCR_NISO_Msk (0x1UL << FDCAN_CCCR_NISO_Pos) /*!< 0x00008000 */
#define FDCAN_CCCR_NISO FDCAN_CCCR_NISO_Msk /*!<Non ISO Operation */
/***************** Bit definition for FDCAN_NBTP register ********************/
#define FDCAN_NBTP_NTSEG2_Pos (0U)
#define FDCAN_NBTP_NTSEG2_Msk (0x7FUL << FDCAN_NBTP_NTSEG2_Pos) /*!< 0x0000007F */
#define FDCAN_NBTP_NTSEG2 FDCAN_NBTP_NTSEG2_Msk /*!<Nominal Time segment after sample point */
#define FDCAN_NBTP_NTSEG1_Pos (8U)
#define FDCAN_NBTP_NTSEG1_Msk (0xFFUL << FDCAN_NBTP_NTSEG1_Pos) /*!< 0x0000FF00 */
#define FDCAN_NBTP_NTSEG1 FDCAN_NBTP_NTSEG1_Msk /*!<Nominal Time segment before sample point */
#define FDCAN_NBTP_NBRP_Pos (16U)
#define FDCAN_NBTP_NBRP_Msk (0x1FFUL << FDCAN_NBTP_NBRP_Pos) /*!< 0x01FF0000 */
#define FDCAN_NBTP_NBRP FDCAN_NBTP_NBRP_Msk /*!<Bit Rate Prescaler */
#define FDCAN_NBTP_NSJW_Pos (25U)
#define FDCAN_NBTP_NSJW_Msk (0x7FUL << FDCAN_NBTP_NSJW_Pos) /*!< 0xFE000000 */
#define FDCAN_NBTP_NSJW FDCAN_NBTP_NSJW_Msk /*!<Nominal (Re)Synchronization Jump Width */
/***************** Bit definition for FDCAN_TSCC register ********************/
#define FDCAN_TSCC_TSS_Pos (0U)
#define FDCAN_TSCC_TSS_Msk (0x3UL << FDCAN_TSCC_TSS_Pos) /*!< 0x00000003 */
#define FDCAN_TSCC_TSS FDCAN_TSCC_TSS_Msk /*!<Timestamp Select */
#define FDCAN_TSCC_TCP_Pos (16U)
#define FDCAN_TSCC_TCP_Msk (0xFUL << FDCAN_TSCC_TCP_Pos) /*!< 0x000F0000 */
#define FDCAN_TSCC_TCP FDCAN_TSCC_TCP_Msk /*!<Timestamp Counter Prescaler */
/***************** Bit definition for FDCAN_TSCV register ********************/
#define FDCAN_TSCV_TSC_Pos (0U)
#define FDCAN_TSCV_TSC_Msk (0xFFFFUL << FDCAN_TSCV_TSC_Pos) /*!< 0x0000FFFF */
#define FDCAN_TSCV_TSC FDCAN_TSCV_TSC_Msk /*!<Timestamp Counter */
/***************** Bit definition for FDCAN_TOCC register ********************/
#define FDCAN_TOCC_ETOC_Pos (0U)
#define FDCAN_TOCC_ETOC_Msk (0x1UL << FDCAN_TOCC_ETOC_Pos) /*!< 0x00000001 */
#define FDCAN_TOCC_ETOC FDCAN_TOCC_ETOC_Msk /*!<Enable Timeout Counter */
#define FDCAN_TOCC_TOS_Pos (1U)
#define FDCAN_TOCC_TOS_Msk (0x3UL << FDCAN_TOCC_TOS_Pos) /*!< 0x00000006 */
#define FDCAN_TOCC_TOS FDCAN_TOCC_TOS_Msk /*!<Timeout Select */
#define FDCAN_TOCC_TOP_Pos (16U)
#define FDCAN_TOCC_TOP_Msk (0xFFFFUL << FDCAN_TOCC_TOP_Pos) /*!< 0xFFFF0000 */
#define FDCAN_TOCC_TOP FDCAN_TOCC_TOP_Msk /*!<Timeout Period */
/***************** Bit definition for FDCAN_TOCV register ********************/
#define FDCAN_TOCV_TOC_Pos (0U)
#define FDCAN_TOCV_TOC_Msk (0xFFFFUL << FDCAN_TOCV_TOC_Pos) /*!< 0x0000FFFF */
#define FDCAN_TOCV_TOC FDCAN_TOCV_TOC_Msk /*!<Timeout Counter */
/***************** Bit definition for FDCAN_ECR register *********************/
#define FDCAN_ECR_TEC_Pos (0U)
#define FDCAN_ECR_TEC_Msk (0xFFUL << FDCAN_ECR_TEC_Pos) /*!< 0x000000FF */
#define FDCAN_ECR_TEC FDCAN_ECR_TEC_Msk /*!<Transmit Error Counter */
#define FDCAN_ECR_REC_Pos (8U)
#define FDCAN_ECR_REC_Msk (0x7FUL << FDCAN_ECR_REC_Pos) /*!< 0x00007F00 */
#define FDCAN_ECR_REC FDCAN_ECR_REC_Msk /*!<Receive Error Counter */
#define FDCAN_ECR_RP_Pos (15U)
#define FDCAN_ECR_RP_Msk (0x1UL << FDCAN_ECR_RP_Pos) /*!< 0x00008000 */
#define FDCAN_ECR_RP FDCAN_ECR_RP_Msk /*!<Receive Error Passive */
#define FDCAN_ECR_CEL_Pos (16U)
#define FDCAN_ECR_CEL_Msk (0xFFUL << FDCAN_ECR_CEL_Pos) /*!< 0x00FF0000 */
#define FDCAN_ECR_CEL FDCAN_ECR_CEL_Msk /*!<CAN Error Logging */
/***************** Bit definition for FDCAN_PSR register *********************/
#define FDCAN_PSR_LEC_Pos (0U)
#define FDCAN_PSR_LEC_Msk (0x7UL << FDCAN_PSR_LEC_Pos) /*!< 0x00000007 */
#define FDCAN_PSR_LEC FDCAN_PSR_LEC_Msk /*!<Last Error Code */
#define FDCAN_PSR_ACT_Pos (3U)
#define FDCAN_PSR_ACT_Msk (0x3UL << FDCAN_PSR_ACT_Pos) /*!< 0x00000018 */
#define FDCAN_PSR_ACT FDCAN_PSR_ACT_Msk /*!<Activity */
#define FDCAN_PSR_EP_Pos (5U)
#define FDCAN_PSR_EP_Msk (0x1UL << FDCAN_PSR_EP_Pos) /*!< 0x00000020 */
#define FDCAN_PSR_EP FDCAN_PSR_EP_Msk /*!<Error Passive */
#define FDCAN_PSR_EW_Pos (6U)
#define FDCAN_PSR_EW_Msk (0x1UL << FDCAN_PSR_EW_Pos) /*!< 0x00000040 */
#define FDCAN_PSR_EW FDCAN_PSR_EW_Msk /*!<Warning Status */
#define FDCAN_PSR_BO_Pos (7U)
#define FDCAN_PSR_BO_Msk (0x1UL << FDCAN_PSR_BO_Pos) /*!< 0x00000080 */
#define FDCAN_PSR_BO FDCAN_PSR_BO_Msk /*!<Bus_Off Status */
#define FDCAN_PSR_DLEC_Pos (8U)
#define FDCAN_PSR_DLEC_Msk (0x7UL << FDCAN_PSR_DLEC_Pos) /*!< 0x00000700 */
#define FDCAN_PSR_DLEC FDCAN_PSR_DLEC_Msk /*!<Data Last Error Code */
#define FDCAN_PSR_RESI_Pos (11U)
#define FDCAN_PSR_RESI_Msk (0x1UL << FDCAN_PSR_RESI_Pos) /*!< 0x00000800 */
#define FDCAN_PSR_RESI FDCAN_PSR_RESI_Msk /*!<ESI flag of last received FDCAN Message */
#define FDCAN_PSR_RBRS_Pos (12U)
#define FDCAN_PSR_RBRS_Msk (0x1UL << FDCAN_PSR_RBRS_Pos) /*!< 0x00001000 */
#define FDCAN_PSR_RBRS FDCAN_PSR_RBRS_Msk /*!<BRS flag of last received FDCAN Message */
#define FDCAN_PSR_REDL_Pos (13U)
#define FDCAN_PSR_REDL_Msk (0x1UL << FDCAN_PSR_REDL_Pos) /*!< 0x00002000 */
#define FDCAN_PSR_REDL FDCAN_PSR_REDL_Msk /*!<Received FDCAN Message */
#define FDCAN_PSR_PXE_Pos (14U)
#define FDCAN_PSR_PXE_Msk (0x1UL << FDCAN_PSR_PXE_Pos) /*!< 0x00004000 */
#define FDCAN_PSR_PXE FDCAN_PSR_PXE_Msk /*!<Protocol Exception Event */
#define FDCAN_PSR_TDCV_Pos (16U)
#define FDCAN_PSR_TDCV_Msk (0x7FUL << FDCAN_PSR_TDCV_Pos) /*!< 0x007F0000 */
#define FDCAN_PSR_TDCV FDCAN_PSR_TDCV_Msk /*!<Transmitter Delay Compensation Value */
/***************** Bit definition for FDCAN_TDCR register ********************/
#define FDCAN_TDCR_TDCF_Pos (0U)
#define FDCAN_TDCR_TDCF_Msk (0x7FUL << FDCAN_TDCR_TDCF_Pos) /*!< 0x0000007F */
#define FDCAN_TDCR_TDCF FDCAN_TDCR_TDCF_Msk /*!<Transmitter Delay Compensation Filter */
#define FDCAN_TDCR_TDCO_Pos (8U)
#define FDCAN_TDCR_TDCO_Msk (0x7FUL << FDCAN_TDCR_TDCO_Pos) /*!< 0x00007F00 */
#define FDCAN_TDCR_TDCO FDCAN_TDCR_TDCO_Msk /*!<Transmitter Delay Compensation Offset */
/***************** Bit definition for FDCAN_IR register **********************/
#define FDCAN_IR_RF0N_Pos (0U)
#define FDCAN_IR_RF0N_Msk (0x1UL << FDCAN_IR_RF0N_Pos) /*!< 0x00000001 */
#define FDCAN_IR_RF0N FDCAN_IR_RF0N_Msk /*!<Rx FIFO 0 New Message */
#define FDCAN_IR_RF0F_Pos (1U)
#define FDCAN_IR_RF0F_Msk (0x1UL << FDCAN_IR_RF0F_Pos) /*!< 0x00000002 */
#define FDCAN_IR_RF0F FDCAN_IR_RF0F_Msk /*!<Rx FIFO 0 Full */
#define FDCAN_IR_RF0L_Pos (2U)
#define FDCAN_IR_RF0L_Msk (0x1UL << FDCAN_IR_RF0L_Pos) /*!< 0x00000004 */
#define FDCAN_IR_RF0L FDCAN_IR_RF0L_Msk /*!<Rx FIFO 0 Message Lost */
#define FDCAN_IR_RF1N_Pos (3U)
#define FDCAN_IR_RF1N_Msk (0x1UL << FDCAN_IR_RF1N_Pos) /*!< 0x00000008 */
#define FDCAN_IR_RF1N FDCAN_IR_RF1N_Msk /*!<Rx FIFO 1 New Message */
#define FDCAN_IR_RF1F_Pos (4U)
#define FDCAN_IR_RF1F_Msk (0x1UL << FDCAN_IR_RF1F_Pos) /*!< 0x00000010 */
#define FDCAN_IR_RF1F FDCAN_IR_RF1F_Msk /*!<Rx FIFO 1 Full */
#define FDCAN_IR_RF1L_Pos (5U)
#define FDCAN_IR_RF1L_Msk (0x1UL << FDCAN_IR_RF1L_Pos) /*!< 0x00000020 */
#define FDCAN_IR_RF1L FDCAN_IR_RF1L_Msk /*!<Rx FIFO 1 Message Lost */
#define FDCAN_IR_HPM_Pos (6U)
#define FDCAN_IR_HPM_Msk (0x1UL << FDCAN_IR_HPM_Pos) /*!< 0x00000040 */
#define FDCAN_IR_HPM FDCAN_IR_HPM_Msk /*!<High Priority Message */
#define FDCAN_IR_TC_Pos (7U)
#define FDCAN_IR_TC_Msk (0x1UL << FDCAN_IR_TC_Pos) /*!< 0x00000080 */
#define FDCAN_IR_TC FDCAN_IR_TC_Msk /*!<Transmission Completed */
#define FDCAN_IR_TCF_Pos (8U)
#define FDCAN_IR_TCF_Msk (0x1UL << FDCAN_IR_TCF_Pos) /*!< 0x00000100 */
#define FDCAN_IR_TCF FDCAN_IR_TCF_Msk /*!<Transmission Cancellation Finished */
#define FDCAN_IR_TFE_Pos (9U)
#define FDCAN_IR_TFE_Msk (0x1UL << FDCAN_IR_TFE_Pos) /*!< 0x00000200 */
#define FDCAN_IR_TFE FDCAN_IR_TFE_Msk /*!<Tx FIFO Empty */
#define FDCAN_IR_TEFN_Pos (10U)
#define FDCAN_IR_TEFN_Msk (0x1UL << FDCAN_IR_TEFN_Pos) /*!< 0x00000400 */
#define FDCAN_IR_TEFN FDCAN_IR_TEFN_Msk /*!<Tx Event FIFO New Entry */
#define FDCAN_IR_TEFF_Pos (11U)
#define FDCAN_IR_TEFF_Msk (0x1UL << FDCAN_IR_TEFF_Pos) /*!< 0x00000800 */
#define FDCAN_IR_TEFF FDCAN_IR_TEFF_Msk /*!<Tx Event FIFO Full */
#define FDCAN_IR_TEFL_Pos (12U)
#define FDCAN_IR_TEFL_Msk (0x1UL << FDCAN_IR_TEFL_Pos) /*!< 0x00001000 */
#define FDCAN_IR_TEFL FDCAN_IR_TEFL_Msk /*!<Tx Event FIFO Element Lost */
#define FDCAN_IR_TSW_Pos (13U)
#define FDCAN_IR_TSW_Msk (0x1UL << FDCAN_IR_TSW_Pos) /*!< 0x00002000 */
#define FDCAN_IR_TSW FDCAN_IR_TSW_Msk /*!<Timestamp Wraparound */
#define FDCAN_IR_MRAF_Pos (14U)
#define FDCAN_IR_MRAF_Msk (0x1UL << FDCAN_IR_MRAF_Pos) /*!< 0x00004000 */
#define FDCAN_IR_MRAF FDCAN_IR_MRAF_Msk /*!<Message RAM Access Failure */
#define FDCAN_IR_TOO_Pos (15U)
#define FDCAN_IR_TOO_Msk (0x1UL << FDCAN_IR_TOO_Pos) /*!< 0x00008000 */
#define FDCAN_IR_TOO FDCAN_IR_TOO_Msk /*!<Timeout Occurred */
#define FDCAN_IR_ELO_Pos (16U)
#define FDCAN_IR_ELO_Msk (0x1UL << FDCAN_IR_ELO_Pos) /*!< 0x00010000 */
#define FDCAN_IR_ELO FDCAN_IR_ELO_Msk /*!<Error Logging Overflow */
#define FDCAN_IR_EP_Pos (17U)
#define FDCAN_IR_EP_Msk (0x1UL << FDCAN_IR_EP_Pos) /*!< 0x00020000 */
#define FDCAN_IR_EP FDCAN_IR_EP_Msk /*!<Error Passive */
#define FDCAN_IR_EW_Pos (18U)
#define FDCAN_IR_EW_Msk (0x1UL << FDCAN_IR_EW_Pos) /*!< 0x00040000 */
#define FDCAN_IR_EW FDCAN_IR_EW_Msk /*!<Warning Status */
#define FDCAN_IR_BO_Pos (19U)
#define FDCAN_IR_BO_Msk (0x1UL << FDCAN_IR_BO_Pos) /*!< 0x00080000 */
#define FDCAN_IR_BO FDCAN_IR_BO_Msk /*!<Bus_Off Status */
#define FDCAN_IR_WDI_Pos (20U)
#define FDCAN_IR_WDI_Msk (0x1UL << FDCAN_IR_WDI_Pos) /*!< 0x00100000 */
#define FDCAN_IR_WDI FDCAN_IR_WDI_Msk /*!<Watchdog Interrupt */
#define FDCAN_IR_PEA_Pos (21U)
#define FDCAN_IR_PEA_Msk (0x1UL << FDCAN_IR_PEA_Pos) /*!< 0x00200000 */
#define FDCAN_IR_PEA FDCAN_IR_PEA_Msk /*!<Protocol Error in Arbitration Phase */
#define FDCAN_IR_PED_Pos (22U)
#define FDCAN_IR_PED_Msk (0x1UL << FDCAN_IR_PED_Pos) /*!< 0x00400000 */
#define FDCAN_IR_PED FDCAN_IR_PED_Msk /*!<Protocol Error in Data Phase */
#define FDCAN_IR_ARA_Pos (23U)
#define FDCAN_IR_ARA_Msk (0x1UL << FDCAN_IR_ARA_Pos) /*!< 0x00800000 */
#define FDCAN_IR_ARA FDCAN_IR_ARA_Msk /*!<Access to Reserved Address */
/***************** Bit definition for FDCAN_IE register **********************/
#define FDCAN_IE_RF0NE_Pos (0U)
#define FDCAN_IE_RF0NE_Msk (0x1UL << FDCAN_IE_RF0NE_Pos) /*!< 0x00000001 */
#define FDCAN_IE_RF0NE FDCAN_IE_RF0NE_Msk /*!<Rx FIFO 0 New Message Enable */
#define FDCAN_IE_RF0FE_Pos (1U)
#define FDCAN_IE_RF0FE_Msk (0x1UL << FDCAN_IE_RF0FE_Pos) /*!< 0x00000002 */
#define FDCAN_IE_RF0FE FDCAN_IE_RF0FE_Msk /*!<Rx FIFO 0 Full Enable */
#define FDCAN_IE_RF0LE_Pos (2U)
#define FDCAN_IE_RF0LE_Msk (0x1UL << FDCAN_IE_RF0LE_Pos) /*!< 0x00000004 */
#define FDCAN_IE_RF0LE FDCAN_IE_RF0LE_Msk /*!<Rx FIFO 0 Message Lost Enable */
#define FDCAN_IE_RF1NE_Pos (3U)
#define FDCAN_IE_RF1NE_Msk (0x1UL << FDCAN_IE_RF1NE_Pos) /*!< 0x00000008 */
#define FDCAN_IE_RF1NE FDCAN_IE_RF1NE_Msk /*!<Rx FIFO 1 New Message Enable */
#define FDCAN_IE_RF1FE_Pos (4U)
#define FDCAN_IE_RF1FE_Msk (0x1UL << FDCAN_IE_RF1FE_Pos) /*!< 0x00000010 */
#define FDCAN_IE_RF1FE FDCAN_IE_RF1FE_Msk /*!<Rx FIFO 1 Full Enable */
#define FDCAN_IE_RF1LE_Pos (5U)
#define FDCAN_IE_RF1LE_Msk (0x1UL << FDCAN_IE_RF1LE_Pos) /*!< 0x00000020 */
#define FDCAN_IE_RF1LE FDCAN_IE_RF1LE_Msk /*!<Rx FIFO 1 Message Lost Enable */
#define FDCAN_IE_HPME_Pos (6U)
#define FDCAN_IE_HPME_Msk (0x1UL << FDCAN_IE_HPME_Pos) /*!< 0x00000040 */
#define FDCAN_IE_HPME FDCAN_IE_HPME_Msk /*!<High Priority Message Enable */
#define FDCAN_IE_TCE_Pos (7U)
#define FDCAN_IE_TCE_Msk (0x1UL << FDCAN_IE_TCE_Pos) /*!< 0x00000080 */
#define FDCAN_IE_TCE FDCAN_IE_TCE_Msk /*!<Transmission Completed Enable */
#define FDCAN_IE_TCFE_Pos (8U)
#define FDCAN_IE_TCFE_Msk (0x1UL << FDCAN_IE_TCFE_Pos) /*!< 0x00000100 */
#define FDCAN_IE_TCFE FDCAN_IE_TCFE_Msk /*!<Transmission Cancellation Finished Enable*/
#define FDCAN_IE_TFEE_Pos (9U)
#define FDCAN_IE_TFEE_Msk (0x1UL << FDCAN_IE_TFEE_Pos) /*!< 0x00000200 */
#define FDCAN_IE_TFEE FDCAN_IE_TFEE_Msk /*!<Tx FIFO Empty Enable */
#define FDCAN_IE_TEFNE_Pos (10U)
#define FDCAN_IE_TEFNE_Msk (0x1UL << FDCAN_IE_TEFNE_Pos) /*!< 0x00000400 */
#define FDCAN_IE_TEFNE FDCAN_IE_TEFNE_Msk /*!<Tx Event FIFO New Entry Enable */
#define FDCAN_IE_TEFFE_Pos (11U)
#define FDCAN_IE_TEFFE_Msk (0x1UL << FDCAN_IE_TEFFE_Pos) /*!< 0x00000800 */
#define FDCAN_IE_TEFFE FDCAN_IE_TEFFE_Msk /*!<Tx Event FIFO Full Enable */
#define FDCAN_IE_TEFLE_Pos (12U)
#define FDCAN_IE_TEFLE_Msk (0x1UL << FDCAN_IE_TEFLE_Pos) /*!< 0x00001000 */
#define FDCAN_IE_TEFLE FDCAN_IE_TEFLE_Msk /*!<Tx Event FIFO Element Lost Enable */
#define FDCAN_IE_TSWE_Pos (13U)
#define FDCAN_IE_TSWE_Msk (0x1UL << FDCAN_IE_TSWE_Pos) /*!< 0x00002000 */
#define FDCAN_IE_TSWE FDCAN_IE_TSWE_Msk /*!<Timestamp Wraparound Enable */
#define FDCAN_IE_MRAFE_Pos (14U)
#define FDCAN_IE_MRAFE_Msk (0x1UL << FDCAN_IE_MRAFE_Pos) /*!< 0x00004000 */
#define FDCAN_IE_MRAFE FDCAN_IE_MRAFE_Msk /*!<Message RAM Access Failure Enable */
#define FDCAN_IE_TOOE_Pos (15U)
#define FDCAN_IE_TOOE_Msk (0x1UL << FDCAN_IE_TOOE_Pos) /*!< 0x00008000 */
#define FDCAN_IE_TOOE FDCAN_IE_TOOE_Msk /*!<Timeout Occurred Enable */
#define FDCAN_IE_ELOE_Pos (16U)
#define FDCAN_IE_ELOE_Msk (0x1UL << FDCAN_IE_ELOE_Pos) /*!< 0x00010000 */
#define FDCAN_IE_ELOE FDCAN_IE_ELOE_Msk /*!<Error Logging Overflow Enable */
#define FDCAN_IE_EPE_Pos (17U)
#define FDCAN_IE_EPE_Msk (0x1UL << FDCAN_IE_EPE_Pos) /*!< 0x00020000 */
#define FDCAN_IE_EPE FDCAN_IE_EPE_Msk /*!<Error Passive Enable */
#define FDCAN_IE_EWE_Pos (18U)
#define FDCAN_IE_EWE_Msk (0x1UL << FDCAN_IE_EWE_Pos) /*!< 0x00040000 */
#define FDCAN_IE_EWE FDCAN_IE_EWE_Msk /*!<Warning Status Enable */
#define FDCAN_IE_BOE_Pos (19U)
#define FDCAN_IE_BOE_Msk (0x1UL << FDCAN_IE_BOE_Pos) /*!< 0x00080000 */
#define FDCAN_IE_BOE FDCAN_IE_BOE_Msk /*!<Bus_Off Status Enable */
#define FDCAN_IE_WDIE_Pos (20U)
#define FDCAN_IE_WDIE_Msk (0x1UL << FDCAN_IE_WDIE_Pos) /*!< 0x00100000 */
#define FDCAN_IE_WDIE FDCAN_IE_WDIE_Msk /*!<Watchdog Interrupt Enable */
#define FDCAN_IE_PEAE_Pos (21U)
#define FDCAN_IE_PEAE_Msk (0x1UL << FDCAN_IE_PEAE_Pos) /*!< 0x00200000 */
#define FDCAN_IE_PEAE FDCAN_IE_PEAE_Msk /*!<Protocol Error in Arbitration Phase Enable*/
#define FDCAN_IE_PEDE_Pos (22U)
#define FDCAN_IE_PEDE_Msk (0x1UL << FDCAN_IE_PEDE_Pos) /*!< 0x00400000 */
#define FDCAN_IE_PEDE FDCAN_IE_PEDE_Msk /*!<Protocol Error in Data Phase Enable */
#define FDCAN_IE_ARAE_Pos (23U)
#define FDCAN_IE_ARAE_Msk (0x1UL << FDCAN_IE_ARAE_Pos) /*!< 0x00800000 */
#define FDCAN_IE_ARAE FDCAN_IE_ARAE_Msk /*!<Access to Reserved Address Enable */
/***************** Bit definition for FDCAN_ILS register **********************/
#define FDCAN_ILS_RXFIFO0_Pos (0U)
#define FDCAN_ILS_RXFIFO0_Msk (0x1UL << FDCAN_ILS_RXFIFO0_Pos) /*!< 0x00000001 */
#define FDCAN_ILS_RXFIFO0 FDCAN_ILS_RXFIFO0_Msk /*!<Rx FIFO 0 Message Lost
Rx FIFO 0 is Full
Rx FIFO 0 Has New Message */
#define FDCAN_ILS_RXFIFO1_Pos (1U)
#define FDCAN_ILS_RXFIFO1_Msk (0x1UL << FDCAN_ILS_RXFIFO1_Pos) /*!< 0x00000002 */
#define FDCAN_ILS_RXFIFO1 FDCAN_ILS_RXFIFO1_Msk /*!<Rx FIFO 1 Message Lost
Rx FIFO 1 is Full
Rx FIFO 1 Has New Message */
#define FDCAN_ILS_SMSG_Pos (2U)
#define FDCAN_ILS_SMSG_Msk (0x1UL << FDCAN_ILS_SMSG_Pos) /*!< 0x00000004 */
#define FDCAN_ILS_SMSG FDCAN_ILS_SMSG_Msk /*!<Transmission Cancellation Finished
Transmission Completed
High Priority Message */
#define FDCAN_ILS_TFERR_Pos (3U)
#define FDCAN_ILS_TFERR_Msk (0x1UL << FDCAN_ILS_TFERR_Pos) /*!< 0x00000008 */
#define FDCAN_ILS_TFERR FDCAN_ILS_TFERR_Msk /*!<Tx Event FIFO Element Lost
Tx Event FIFO Full
Tx Event FIFO New Entry
Tx FIFO Empty Interrupt Line */
#define FDCAN_ILS_MISC_Pos (4U)
#define FDCAN_ILS_MISC_Msk (0x1UL << FDCAN_ILS_MISC_Pos) /*!< 0x00000010 */
#define FDCAN_ILS_MISC FDCAN_ILS_MISC_Msk /*!<Timeout Occurred
Message RAM Access Failure
Timestamp Wraparound */
#define FDCAN_ILS_BERR_Pos (5U)
#define FDCAN_ILS_BERR_Msk (0x1UL << FDCAN_ILS_BERR_Pos) /*!< 0x00000020 */
#define FDCAN_ILS_BERR FDCAN_ILS_BERR_Msk /*!<Error Passive
Error Logging Overflow */
#define FDCAN_ILS_PERR_Pos (6U)
#define FDCAN_ILS_PERR_Msk (0x1UL << FDCAN_ILS_PERR_Pos) /*!< 0x00000040 */
#define FDCAN_ILS_PERR FDCAN_ILS_PERR_Msk /*!<Access to Reserved Address Line
Protocol Error in Data Phase Line
Protocol Error in Arbitration Phase Line
Watchdog Interrupt Line
Bus_Off Status
Warning Status */
/***************** Bit definition for FDCAN_ILE register **********************/
#define FDCAN_ILE_EINT0_Pos (0U)
#define FDCAN_ILE_EINT0_Msk (0x1UL << FDCAN_ILE_EINT0_Pos) /*!< 0x00000001 */
#define FDCAN_ILE_EINT0 FDCAN_ILE_EINT0_Msk /*!<Enable Interrupt Line 0 */
#define FDCAN_ILE_EINT1_Pos (1U)
#define FDCAN_ILE_EINT1_Msk (0x1UL << FDCAN_ILE_EINT1_Pos) /*!< 0x00000002 */
#define FDCAN_ILE_EINT1 FDCAN_ILE_EINT1_Msk /*!<Enable Interrupt Line 1 */
/***************** Bit definition for FDCAN_RXGFC register ********************/
#define FDCAN_RXGFC_RRFE_Pos (0U)
#define FDCAN_RXGFC_RRFE_Msk (0x1UL << FDCAN_RXGFC_RRFE_Pos) /*!< 0x00000001 */
#define FDCAN_RXGFC_RRFE FDCAN_RXGFC_RRFE_Msk /*!<Reject Remote Frames Extended */
#define FDCAN_RXGFC_RRFS_Pos (1U)
#define FDCAN_RXGFC_RRFS_Msk (0x1UL << FDCAN_RXGFC_RRFS_Pos) /*!< 0x00000002 */
#define FDCAN_RXGFC_RRFS FDCAN_RXGFC_RRFS_Msk /*!<Reject Remote Frames Standard */
#define FDCAN_RXGFC_ANFE_Pos (2U)
#define FDCAN_RXGFC_ANFE_Msk (0x3UL << FDCAN_RXGFC_ANFE_Pos) /*!< 0x0000000C */
#define FDCAN_RXGFC_ANFE FDCAN_RXGFC_ANFE_Msk /*!<Accept Non-matching Frames Extended */
#define FDCAN_RXGFC_ANFS_Pos (4U)
#define FDCAN_RXGFC_ANFS_Msk (0x3UL << FDCAN_RXGFC_ANFS_Pos) /*!< 0x00000030 */
#define FDCAN_RXGFC_ANFS FDCAN_RXGFC_ANFS_Msk /*!<Accept Non-matching Frames Standard */
#define FDCAN_RXGFC_F1OM_Pos (8U)
#define FDCAN_RXGFC_F1OM_Msk (0x1UL << FDCAN_RXGFC_F1OM_Pos) /*!< 0x00000100 */
#define FDCAN_RXGFC_F1OM FDCAN_RXGFC_F1OM_Msk /*!<FIFO 1 operation mode */
#define FDCAN_RXGFC_F0OM_Pos (9U)
#define FDCAN_RXGFC_F0OM_Msk (0x1UL << FDCAN_RXGFC_F0OM_Pos) /*!< 0x00000200 */
#define FDCAN_RXGFC_F0OM FDCAN_RXGFC_F0OM_Msk /*!<FIFO 0 operation mode */
#define FDCAN_RXGFC_LSS_Pos (16U)
#define FDCAN_RXGFC_LSS_Msk (0x1FUL << FDCAN_RXGFC_LSS_Pos) /*!< 0x001F0000 */
#define FDCAN_RXGFC_LSS FDCAN_RXGFC_LSS_Msk /*!<List Size Standard */
#define FDCAN_RXGFC_LSE_Pos (24U)
#define FDCAN_RXGFC_LSE_Msk (0xFUL << FDCAN_RXGFC_LSE_Pos) /*!< 0x0F000000 */
#define FDCAN_RXGFC_LSE FDCAN_RXGFC_LSE_Msk /*!<List Size Extended */
/***************** Bit definition for FDCAN_XIDAM register ********************/
#define FDCAN_XIDAM_EIDM_Pos (0U)
#define FDCAN_XIDAM_EIDM_Msk (0x1FFFFFFFUL << FDCAN_XIDAM_EIDM_Pos) /*!< 0x1FFFFFFF */
#define FDCAN_XIDAM_EIDM FDCAN_XIDAM_EIDM_Msk /*!<Extended ID Mask */
/***************** Bit definition for FDCAN_HPMS register *********************/
#define FDCAN_HPMS_BIDX_Pos (0U)
#define FDCAN_HPMS_BIDX_Msk (0x7UL << FDCAN_HPMS_BIDX_Pos) /*!< 0x00000007 */
#define FDCAN_HPMS_BIDX FDCAN_HPMS_BIDX_Msk /*!<Buffer Index */
#define FDCAN_HPMS_MSI_Pos (6U)
#define FDCAN_HPMS_MSI_Msk (0x3UL << FDCAN_HPMS_MSI_Pos) /*!< 0x000000C0 */
#define FDCAN_HPMS_MSI FDCAN_HPMS_MSI_Msk /*!<Message Storage Indicator */
#define FDCAN_HPMS_FIDX_Pos (8U)
#define FDCAN_HPMS_FIDX_Msk (0x1FUL << FDCAN_HPMS_FIDX_Pos) /*!< 0x00001F00 */
#define FDCAN_HPMS_FIDX FDCAN_HPMS_FIDX_Msk /*!<Filter Index */
#define FDCAN_HPMS_FLST_Pos (15U)
#define FDCAN_HPMS_FLST_Msk (0x1UL << FDCAN_HPMS_FLST_Pos) /*!< 0x00008000 */
#define FDCAN_HPMS_FLST FDCAN_HPMS_FLST_Msk /*!<Filter List */
/***************** Bit definition for FDCAN_RXF0S register ********************/
#define FDCAN_RXF0S_F0FL_Pos (0U)
#define FDCAN_RXF0S_F0FL_Msk (0xFUL << FDCAN_RXF0S_F0FL_Pos) /*!< 0x0000000F */
#define FDCAN_RXF0S_F0FL FDCAN_RXF0S_F0FL_Msk /*!<Rx FIFO 0 Fill Level */
#define FDCAN_RXF0S_F0GI_Pos (8U)
#define FDCAN_RXF0S_F0GI_Msk (0x3UL << FDCAN_RXF0S_F0GI_Pos) /*!< 0x00000300 */
#define FDCAN_RXF0S_F0GI FDCAN_RXF0S_F0GI_Msk /*!<Rx FIFO 0 Get Index */
#define FDCAN_RXF0S_F0PI_Pos (16U)
#define FDCAN_RXF0S_F0PI_Msk (0x3UL << FDCAN_RXF0S_F0PI_Pos) /*!< 0x00030000 */
#define FDCAN_RXF0S_F0PI FDCAN_RXF0S_F0PI_Msk /*!<Rx FIFO 0 Put Index */
#define FDCAN_RXF0S_F0F_Pos (24U)
#define FDCAN_RXF0S_F0F_Msk (0x1UL << FDCAN_RXF0S_F0F_Pos) /*!< 0x01000000 */
#define FDCAN_RXF0S_F0F FDCAN_RXF0S_F0F_Msk /*!<Rx FIFO 0 Full */
#define FDCAN_RXF0S_RF0L_Pos (25U)
#define FDCAN_RXF0S_RF0L_Msk (0x1UL << FDCAN_RXF0S_RF0L_Pos) /*!< 0x02000000 */
#define FDCAN_RXF0S_RF0L FDCAN_RXF0S_RF0L_Msk /*!<Rx FIFO 0 Message Lost */
/***************** Bit definition for FDCAN_RXF0A register ********************/
#define FDCAN_RXF0A_F0AI_Pos (0U)
#define FDCAN_RXF0A_F0AI_Msk (0x7UL << FDCAN_RXF0A_F0AI_Pos) /*!< 0x00000007 */
#define FDCAN_RXF0A_F0AI FDCAN_RXF0A_F0AI_Msk /*!<Rx FIFO 0 Acknowledge Index */
/***************** Bit definition for FDCAN_RXF1S register ********************/
#define FDCAN_RXF1S_F1FL_Pos (0U)
#define FDCAN_RXF1S_F1FL_Msk (0xFUL << FDCAN_RXF1S_F1FL_Pos) /*!< 0x0000000F */
#define FDCAN_RXF1S_F1FL FDCAN_RXF1S_F1FL_Msk /*!<Rx FIFO 1 Fill Level */
#define FDCAN_RXF1S_F1GI_Pos (8U)
#define FDCAN_RXF1S_F1GI_Msk (0x3UL << FDCAN_RXF1S_F1GI_Pos) /*!< 0x00000300 */
#define FDCAN_RXF1S_F1GI FDCAN_RXF1S_F1GI_Msk /*!<Rx FIFO 1 Get Index */
#define FDCAN_RXF1S_F1PI_Pos (16U)
#define FDCAN_RXF1S_F1PI_Msk (0x3UL << FDCAN_RXF1S_F1PI_Pos) /*!< 0x00030000 */
#define FDCAN_RXF1S_F1PI FDCAN_RXF1S_F1PI_Msk /*!<Rx FIFO 1 Put Index */
#define FDCAN_RXF1S_F1F_Pos (24U)
#define FDCAN_RXF1S_F1F_Msk (0x1UL << FDCAN_RXF1S_F1F_Pos) /*!< 0x01000000 */
#define FDCAN_RXF1S_F1F FDCAN_RXF1S_F1F_Msk /*!<Rx FIFO 1 Full */
#define FDCAN_RXF1S_RF1L_Pos (25U)
#define FDCAN_RXF1S_RF1L_Msk (0x1UL << FDCAN_RXF1S_RF1L_Pos) /*!< 0x02000000 */
#define FDCAN_RXF1S_RF1L FDCAN_RXF1S_RF1L_Msk /*!<Rx FIFO 1 Message Lost */
/***************** Bit definition for FDCAN_RXF1A register ********************/
#define FDCAN_RXF1A_F1AI_Pos (0U)
#define FDCAN_RXF1A_F1AI_Msk (0x7UL << FDCAN_RXF1A_F1AI_Pos) /*!< 0x00000007 */
#define FDCAN_RXF1A_F1AI FDCAN_RXF1A_F1AI_Msk /*!<Rx FIFO 1 Acknowledge Index */
/***************** Bit definition for FDCAN_TXBC register *********************/
#define FDCAN_TXBC_TFQM_Pos (24U)
#define FDCAN_TXBC_TFQM_Msk (0x1UL << FDCAN_TXBC_TFQM_Pos) /*!< 0x01000000 */
#define FDCAN_TXBC_TFQM FDCAN_TXBC_TFQM_Msk /*!<Tx FIFO/Queue Mode */
/***************** Bit definition for FDCAN_TXFQS register *********************/
#define FDCAN_TXFQS_TFFL_Pos (0U)
#define FDCAN_TXFQS_TFFL_Msk (0x7UL << FDCAN_TXFQS_TFFL_Pos) /*!< 0x00000007 */
#define FDCAN_TXFQS_TFFL FDCAN_TXFQS_TFFL_Msk /*!<Tx FIFO Free Level */
#define FDCAN_TXFQS_TFGI_Pos (8U)
#define FDCAN_TXFQS_TFGI_Msk (0x3UL << FDCAN_TXFQS_TFGI_Pos) /*!< 0x00000300 */
#define FDCAN_TXFQS_TFGI FDCAN_TXFQS_TFGI_Msk /*!<Tx FIFO Get Index */
#define FDCAN_TXFQS_TFQPI_Pos (16U)
#define FDCAN_TXFQS_TFQPI_Msk (0x3UL << FDCAN_TXFQS_TFQPI_Pos) /*!< 0x00030000 */
#define FDCAN_TXFQS_TFQPI FDCAN_TXFQS_TFQPI_Msk /*!<Tx FIFO/Queue Put Index */
#define FDCAN_TXFQS_TFQF_Pos (21U)
#define FDCAN_TXFQS_TFQF_Msk (0x1UL << FDCAN_TXFQS_TFQF_Pos) /*!< 0x00200000 */
#define FDCAN_TXFQS_TFQF FDCAN_TXFQS_TFQF_Msk /*!<Tx FIFO/Queue Full */
/***************** Bit definition for FDCAN_TXBRP register *********************/
#define FDCAN_TXBRP_TRP_Pos (0U)
#define FDCAN_TXBRP_TRP_Msk (0x7UL << FDCAN_TXBRP_TRP_Pos) /*!< 0x00000007 */
#define FDCAN_TXBRP_TRP FDCAN_TXBRP_TRP_Msk /*!<Transmission Request Pending */
/***************** Bit definition for FDCAN_TXBAR register *********************/
#define FDCAN_TXBAR_AR_Pos (0U)
#define FDCAN_TXBAR_AR_Msk (0x7UL << FDCAN_TXBAR_AR_Pos) /*!< 0x00000007 */
#define FDCAN_TXBAR_AR FDCAN_TXBAR_AR_Msk /*!<Add Request */
/***************** Bit definition for FDCAN_TXBCR register *********************/
#define FDCAN_TXBCR_CR_Pos (0U)
#define FDCAN_TXBCR_CR_Msk (0x7UL << FDCAN_TXBCR_CR_Pos) /*!< 0x00000007 */
#define FDCAN_TXBCR_CR FDCAN_TXBCR_CR_Msk /*!<Cancellation Request */
/***************** Bit definition for FDCAN_TXBTO register *********************/
#define FDCAN_TXBTO_TO_Pos (0U)
#define FDCAN_TXBTO_TO_Msk (0x7UL << FDCAN_TXBTO_TO_Pos) /*!< 0x00000007 */
#define FDCAN_TXBTO_TO FDCAN_TXBTO_TO_Msk /*!<Transmission Occurred */
/***************** Bit definition for FDCAN_TXBCF register *********************/
#define FDCAN_TXBCF_CF_Pos (0U)
#define FDCAN_TXBCF_CF_Msk (0x7UL << FDCAN_TXBCF_CF_Pos) /*!< 0x00000007 */
#define FDCAN_TXBCF_CF FDCAN_TXBCF_CF_Msk /*!<Cancellation Finished */
/***************** Bit definition for FDCAN_TXBTIE register ********************/
#define FDCAN_TXBTIE_TIE_Pos (0U)
#define FDCAN_TXBTIE_TIE_Msk (0x7UL << FDCAN_TXBTIE_TIE_Pos) /*!< 0x00000007 */
#define FDCAN_TXBTIE_TIE FDCAN_TXBTIE_TIE_Msk /*!<Transmission Interrupt Enable */
/***************** Bit definition for FDCAN_ TXBCIE register *******************/
#define FDCAN_TXBCIE_CFIE_Pos (0U)
#define FDCAN_TXBCIE_CFIE_Msk (0x7UL << FDCAN_TXBCIE_CFIE_Pos) /*!< 0x00000007 */
#define FDCAN_TXBCIE_CFIE FDCAN_TXBCIE_CFIE_Msk /*!<Cancellation Finished Interrupt Enable */
/***************** Bit definition for FDCAN_TXEFS register *********************/
#define FDCAN_TXEFS_EFFL_Pos (0U)
#define FDCAN_TXEFS_EFFL_Msk (0x7UL << FDCAN_TXEFS_EFFL_Pos) /*!< 0x00000007 */
#define FDCAN_TXEFS_EFFL FDCAN_TXEFS_EFFL_Msk /*!<Event FIFO Fill Level */
#define FDCAN_TXEFS_EFGI_Pos (8U)
#define FDCAN_TXEFS_EFGI_Msk (0x3UL << FDCAN_TXEFS_EFGI_Pos) /*!< 0x00000300 */
#define FDCAN_TXEFS_EFGI FDCAN_TXEFS_EFGI_Msk /*!<Event FIFO Get Index */
#define FDCAN_TXEFS_EFPI_Pos (16U)
#define FDCAN_TXEFS_EFPI_Msk (0x3UL << FDCAN_TXEFS_EFPI_Pos) /*!< 0x00030000 */
#define FDCAN_TXEFS_EFPI FDCAN_TXEFS_EFPI_Msk /*!<Event FIFO Put Index */
#define FDCAN_TXEFS_EFF_Pos (24U)
#define FDCAN_TXEFS_EFF_Msk (0x1UL << FDCAN_TXEFS_EFF_Pos) /*!< 0x01000000 */
#define FDCAN_TXEFS_EFF FDCAN_TXEFS_EFF_Msk /*!<Event FIFO Full */
#define FDCAN_TXEFS_TEFL_Pos (25U)
#define FDCAN_TXEFS_TEFL_Msk (0x1UL << FDCAN_TXEFS_TEFL_Pos) /*!< 0x02000000 */
#define FDCAN_TXEFS_TEFL FDCAN_TXEFS_TEFL_Msk /*!<Tx Event FIFO Element Lost */
/***************** Bit definition for FDCAN_TXEFA register *********************/
#define FDCAN_TXEFA_EFAI_Pos (0U)
#define FDCAN_TXEFA_EFAI_Msk (0x3UL << FDCAN_TXEFA_EFAI_Pos) /*!< 0x00000003 */
#define FDCAN_TXEFA_EFAI FDCAN_TXEFA_EFAI_Msk /*!<Event FIFO Acknowledge Index */
/*!<FDCAN config registers */
/***************** Bit definition for FDCAN_CKDIV register *********************/
#define FDCAN_CKDIV_PDIV_Pos (0U)
#define FDCAN_CKDIV_PDIV_Msk (0xFUL << FDCAN_CKDIV_PDIV_Pos) /*!< 0x0000000F */
#define FDCAN_CKDIV_PDIV FDCAN_CKDIV_PDIV_Msk /*!<Input Clock Divider */
/******************************************************************************/
/* */
/* FLASH */
/* */
/******************************************************************************/
/******************* Bits definition for FLASH_ACR register *****************/
#define FLASH_ACR_LATENCY_Pos (0U)
#define FLASH_ACR_LATENCY_Msk (0xFUL << FLASH_ACR_LATENCY_Pos) /*!< 0x0000000F */
#define FLASH_ACR_LATENCY FLASH_ACR_LATENCY_Msk
#define FLASH_ACR_LATENCY_0WS (0x00000000U)
#define FLASH_ACR_LATENCY_1WS (0x00000001U)
#define FLASH_ACR_LATENCY_2WS (0x00000002U)
#define FLASH_ACR_LATENCY_3WS (0x00000003U)
#define FLASH_ACR_LATENCY_4WS (0x00000004U)
#define FLASH_ACR_LATENCY_5WS (0x00000005U)
#define FLASH_ACR_LATENCY_6WS (0x00000006U)
#define FLASH_ACR_LATENCY_7WS (0x00000007U)
#define FLASH_ACR_LATENCY_8WS (0x00000008U)
#define FLASH_ACR_LATENCY_9WS (0x00000009U)
#define FLASH_ACR_LATENCY_10WS (0x0000000AU)
#define FLASH_ACR_LATENCY_11WS (0x0000000BU)
#define FLASH_ACR_LATENCY_12WS (0x0000000CU)
#define FLASH_ACR_LATENCY_13WS (0x0000000DU)
#define FLASH_ACR_LATENCY_14WS (0x0000000EU)
#define FLASH_ACR_LATENCY_15WS (0x0000000FU)
#define FLASH_ACR_PRFTEN_Pos (8U)
#define FLASH_ACR_PRFTEN_Msk (0x1UL << FLASH_ACR_PRFTEN_Pos) /*!< 0x00000100 */
#define FLASH_ACR_PRFTEN FLASH_ACR_PRFTEN_Msk
#define FLASH_ACR_ICEN_Pos (9U)
#define FLASH_ACR_ICEN_Msk (0x1UL << FLASH_ACR_ICEN_Pos) /*!< 0x00000200 */
#define FLASH_ACR_ICEN FLASH_ACR_ICEN_Msk
#define FLASH_ACR_DCEN_Pos (10U)
#define FLASH_ACR_DCEN_Msk (0x1UL << FLASH_ACR_DCEN_Pos) /*!< 0x00000400 */
#define FLASH_ACR_DCEN FLASH_ACR_DCEN_Msk
#define FLASH_ACR_ICRST_Pos (11U)
#define FLASH_ACR_ICRST_Msk (0x1UL << FLASH_ACR_ICRST_Pos) /*!< 0x00000800 */
#define FLASH_ACR_ICRST FLASH_ACR_ICRST_Msk
#define FLASH_ACR_DCRST_Pos (12U)
#define FLASH_ACR_DCRST_Msk (0x1UL << FLASH_ACR_DCRST_Pos) /*!< 0x00001000 */
#define FLASH_ACR_DCRST FLASH_ACR_DCRST_Msk
#define FLASH_ACR_RUN_PD_Pos (13U)
#define FLASH_ACR_RUN_PD_Msk (0x1UL << FLASH_ACR_RUN_PD_Pos) /*!< 0x00002000 */
#define FLASH_ACR_RUN_PD FLASH_ACR_RUN_PD_Msk /*!< Flash power down mode during run */
#define FLASH_ACR_SLEEP_PD_Pos (14U)
#define FLASH_ACR_SLEEP_PD_Msk (0x1UL << FLASH_ACR_SLEEP_PD_Pos) /*!< 0x00004000 */
#define FLASH_ACR_SLEEP_PD FLASH_ACR_SLEEP_PD_Msk /*!< Flash power down mode during sleep */
#define FLASH_ACR_DBG_SWEN_Pos (18U)
#define FLASH_ACR_DBG_SWEN_Msk (0x1UL << FLASH_ACR_DBG_SWEN_Pos) /*!< 0x00040000 */
#define FLASH_ACR_DBG_SWEN FLASH_ACR_DBG_SWEN_Msk /*!< Software disable for debugger */
/******************* Bits definition for FLASH_SR register ******************/
#define FLASH_SR_EOP_Pos (0U)
#define FLASH_SR_EOP_Msk (0x1UL << FLASH_SR_EOP_Pos) /*!< 0x00000001 */
#define FLASH_SR_EOP FLASH_SR_EOP_Msk
#define FLASH_SR_OPERR_Pos (1U)
#define FLASH_SR_OPERR_Msk (0x1UL << FLASH_SR_OPERR_Pos) /*!< 0x00000002 */
#define FLASH_SR_OPERR FLASH_SR_OPERR_Msk
#define FLASH_SR_PROGERR_Pos (3U)
#define FLASH_SR_PROGERR_Msk (0x1UL << FLASH_SR_PROGERR_Pos) /*!< 0x00000008 */
#define FLASH_SR_PROGERR FLASH_SR_PROGERR_Msk
#define FLASH_SR_WRPERR_Pos (4U)
#define FLASH_SR_WRPERR_Msk (0x1UL << FLASH_SR_WRPERR_Pos) /*!< 0x00000010 */
#define FLASH_SR_WRPERR FLASH_SR_WRPERR_Msk
#define FLASH_SR_PGAERR_Pos (5U)
#define FLASH_SR_PGAERR_Msk (0x1UL << FLASH_SR_PGAERR_Pos) /*!< 0x00000020 */
#define FLASH_SR_PGAERR FLASH_SR_PGAERR_Msk
#define FLASH_SR_SIZERR_Pos (6U)
#define FLASH_SR_SIZERR_Msk (0x1UL << FLASH_SR_SIZERR_Pos) /*!< 0x00000040 */
#define FLASH_SR_SIZERR FLASH_SR_SIZERR_Msk
#define FLASH_SR_PGSERR_Pos (7U)
#define FLASH_SR_PGSERR_Msk (0x1UL << FLASH_SR_PGSERR_Pos) /*!< 0x00000080 */
#define FLASH_SR_PGSERR FLASH_SR_PGSERR_Msk
#define FLASH_SR_MISERR_Pos (8U)
#define FLASH_SR_MISERR_Msk (0x1UL << FLASH_SR_MISERR_Pos) /*!< 0x00000100 */
#define FLASH_SR_MISERR FLASH_SR_MISERR_Msk
#define FLASH_SR_FASTERR_Pos (9U)
#define FLASH_SR_FASTERR_Msk (0x1UL << FLASH_SR_FASTERR_Pos) /*!< 0x00000200 */
#define FLASH_SR_FASTERR FLASH_SR_FASTERR_Msk
#define FLASH_SR_RDERR_Pos (14U)
#define FLASH_SR_RDERR_Msk (0x1UL << FLASH_SR_RDERR_Pos) /*!< 0x00004000 */
#define FLASH_SR_RDERR FLASH_SR_RDERR_Msk
#define FLASH_SR_OPTVERR_Pos (15U)
#define FLASH_SR_OPTVERR_Msk (0x1UL << FLASH_SR_OPTVERR_Pos) /*!< 0x00008000 */
#define FLASH_SR_OPTVERR FLASH_SR_OPTVERR_Msk
#define FLASH_SR_BSY_Pos (16U)
#define FLASH_SR_BSY_Msk (0x1UL << FLASH_SR_BSY_Pos) /*!< 0x00010000 */
#define FLASH_SR_BSY FLASH_SR_BSY_Msk
/******************* Bits definition for FLASH_CR register ******************/
#define FLASH_CR_PG_Pos (0U)
#define FLASH_CR_PG_Msk (0x1UL << FLASH_CR_PG_Pos) /*!< 0x00000001 */
#define FLASH_CR_PG FLASH_CR_PG_Msk
#define FLASH_CR_PER_Pos (1U)
#define FLASH_CR_PER_Msk (0x1UL << FLASH_CR_PER_Pos) /*!< 0x00000002 */
#define FLASH_CR_PER FLASH_CR_PER_Msk
#define FLASH_CR_MER1_Pos (2U)
#define FLASH_CR_MER1_Msk (0x1UL << FLASH_CR_MER1_Pos) /*!< 0x00000004 */
#define FLASH_CR_MER1 FLASH_CR_MER1_Msk
#define FLASH_CR_PNB_Pos (3U)
#define FLASH_CR_PNB_Msk (0x3FUL << FLASH_CR_PNB_Pos) /*!< 0x000001F8 */
#define FLASH_CR_PNB FLASH_CR_PNB_Msk
#define FLASH_CR_STRT_Pos (16U)
#define FLASH_CR_STRT_Msk (0x1UL << FLASH_CR_STRT_Pos) /*!< 0x00010000 */
#define FLASH_CR_STRT FLASH_CR_STRT_Msk
#define FLASH_CR_OPTSTRT_Pos (17U)
#define FLASH_CR_OPTSTRT_Msk (0x1UL << FLASH_CR_OPTSTRT_Pos) /*!< 0x00020000 */
#define FLASH_CR_OPTSTRT FLASH_CR_OPTSTRT_Msk
#define FLASH_CR_FSTPG_Pos (18U)
#define FLASH_CR_FSTPG_Msk (0x1UL << FLASH_CR_FSTPG_Pos) /*!< 0x00040000 */
#define FLASH_CR_FSTPG FLASH_CR_FSTPG_Msk
#define FLASH_CR_EOPIE_Pos (24U)
#define FLASH_CR_EOPIE_Msk (0x1UL << FLASH_CR_EOPIE_Pos) /*!< 0x01000000 */
#define FLASH_CR_EOPIE FLASH_CR_EOPIE_Msk
#define FLASH_CR_ERRIE_Pos (25U)
#define FLASH_CR_ERRIE_Msk (0x1UL << FLASH_CR_ERRIE_Pos) /*!< 0x02000000 */
#define FLASH_CR_ERRIE FLASH_CR_ERRIE_Msk
#define FLASH_CR_RDERRIE_Pos (26U)
#define FLASH_CR_RDERRIE_Msk (0x1UL << FLASH_CR_RDERRIE_Pos) /*!< 0x04000000 */
#define FLASH_CR_RDERRIE FLASH_CR_RDERRIE_Msk
#define FLASH_CR_OBL_LAUNCH_Pos (27U)
#define FLASH_CR_OBL_LAUNCH_Msk (0x1UL << FLASH_CR_OBL_LAUNCH_Pos) /*!< 0x08000000 */
#define FLASH_CR_OBL_LAUNCH FLASH_CR_OBL_LAUNCH_Msk
#define FLASH_CR_SEC_PROT1_Pos (28U)
#define FLASH_CR_SEC_PROT1_Msk (0x1UL << FLASH_CR_SEC_PROT1_Pos) /*!< 0x10000000 */
#define FLASH_CR_SEC_PROT1 FLASH_CR_SEC_PROT1_Msk
#define FLASH_CR_OPTLOCK_Pos (30U)
#define FLASH_CR_OPTLOCK_Msk (0x1UL << FLASH_CR_OPTLOCK_Pos) /*!< 0x40000000 */
#define FLASH_CR_OPTLOCK FLASH_CR_OPTLOCK_Msk
#define FLASH_CR_LOCK_Pos (31U)
#define FLASH_CR_LOCK_Msk (0x1UL << FLASH_CR_LOCK_Pos) /*!< 0x80000000 */
#define FLASH_CR_LOCK FLASH_CR_LOCK_Msk
/******************* Bits definition for FLASH_ECCR register ***************/
#define FLASH_ECCR_ADDR_ECC_Pos (0U)
#define FLASH_ECCR_ADDR_ECC_Msk (0x3FFFFUL << FLASH_ECCR_ADDR_ECC_Pos)/*!< 0x0003FFFF */
#define FLASH_ECCR_ADDR_ECC FLASH_ECCR_ADDR_ECC_Msk
#define FLASH_ECCR_SYSF_ECC_Pos (22U)
#define FLASH_ECCR_SYSF_ECC_Msk (0x1UL << FLASH_ECCR_SYSF_ECC_Pos) /*!< 0x00400000 */
#define FLASH_ECCR_SYSF_ECC FLASH_ECCR_SYSF_ECC_Msk
#define FLASH_ECCR_ECCIE_Pos (24U)
#define FLASH_ECCR_ECCIE_Msk (0x1UL << FLASH_ECCR_ECCIE_Pos) /*!< 0x01000000 */
#define FLASH_ECCR_ECCIE FLASH_ECCR_ECCIE_Msk
#define FLASH_ECCR_ECCC_Pos (30U)
#define FLASH_ECCR_ECCC_Msk (0x1UL << FLASH_ECCR_ECCC_Pos) /*!< 0x40000000 */
#define FLASH_ECCR_ECCC FLASH_ECCR_ECCC_Msk
#define FLASH_ECCR_ECCD_Pos (31U)
#define FLASH_ECCR_ECCD_Msk (0x1UL << FLASH_ECCR_ECCD_Pos) /*!< 0x80000000 */
#define FLASH_ECCR_ECCD FLASH_ECCR_ECCD_Msk
/******************* Bits definition for FLASH_OPTR register ***************/
#define FLASH_OPTR_RDP_Pos (0U)
#define FLASH_OPTR_RDP_Msk (0xFFUL << FLASH_OPTR_RDP_Pos) /*!< 0x000000FF */
#define FLASH_OPTR_RDP FLASH_OPTR_RDP_Msk
#define FLASH_OPTR_BOR_LEV_Pos (8U)
#define FLASH_OPTR_BOR_LEV_Msk (0x7UL << FLASH_OPTR_BOR_LEV_Pos) /*!< 0x00000700 */
#define FLASH_OPTR_BOR_LEV FLASH_OPTR_BOR_LEV_Msk
#define FLASH_OPTR_BOR_LEV_0 (0x0UL << FLASH_OPTR_BOR_LEV_Pos) /*!< 0x00000000 */
#define FLASH_OPTR_BOR_LEV_1 (0x1UL << FLASH_OPTR_BOR_LEV_Pos) /*!< 0x00000100 */
#define FLASH_OPTR_BOR_LEV_2 (0x2UL << FLASH_OPTR_BOR_LEV_Pos) /*!< 0x00000200 */
#define FLASH_OPTR_BOR_LEV_3 (0x3UL << FLASH_OPTR_BOR_LEV_Pos) /*!< 0x00000300 */
#define FLASH_OPTR_BOR_LEV_4 (0x4UL << FLASH_OPTR_BOR_LEV_Pos) /*!< 0x00000400 */
#define FLASH_OPTR_nRST_STOP_Pos (12U)
#define FLASH_OPTR_nRST_STOP_Msk (0x1UL << FLASH_OPTR_nRST_STOP_Pos) /*!< 0x00001000 */
#define FLASH_OPTR_nRST_STOP FLASH_OPTR_nRST_STOP_Msk
#define FLASH_OPTR_nRST_STDBY_Pos (13U)
#define FLASH_OPTR_nRST_STDBY_Msk (0x1UL << FLASH_OPTR_nRST_STDBY_Pos) /*!< 0x00002000 */
#define FLASH_OPTR_nRST_STDBY FLASH_OPTR_nRST_STDBY_Msk
#define FLASH_OPTR_nRST_SHDW_Pos (14U)
#define FLASH_OPTR_nRST_SHDW_Msk (0x1UL << FLASH_OPTR_nRST_SHDW_Pos) /*!< 0x00004000 */
#define FLASH_OPTR_nRST_SHDW FLASH_OPTR_nRST_SHDW_Msk
#define FLASH_OPTR_IWDG_SW_Pos (16U)
#define FLASH_OPTR_IWDG_SW_Msk (0x1UL << FLASH_OPTR_IWDG_SW_Pos) /*!< 0x00010000 */
#define FLASH_OPTR_IWDG_SW FLASH_OPTR_IWDG_SW_Msk
#define FLASH_OPTR_IWDG_STOP_Pos (17U)
#define FLASH_OPTR_IWDG_STOP_Msk (0x1UL << FLASH_OPTR_IWDG_STOP_Pos) /*!< 0x00020000 */
#define FLASH_OPTR_IWDG_STOP FLASH_OPTR_IWDG_STOP_Msk
#define FLASH_OPTR_IWDG_STDBY_Pos (18U)
#define FLASH_OPTR_IWDG_STDBY_Msk (0x1UL << FLASH_OPTR_IWDG_STDBY_Pos) /*!< 0x00040000 */
#define FLASH_OPTR_IWDG_STDBY FLASH_OPTR_IWDG_STDBY_Msk
#define FLASH_OPTR_WWDG_SW_Pos (19U)
#define FLASH_OPTR_WWDG_SW_Msk (0x1UL << FLASH_OPTR_WWDG_SW_Pos) /*!< 0x00080000 */
#define FLASH_OPTR_WWDG_SW FLASH_OPTR_WWDG_SW_Msk
#define FLASH_OPTR_nBOOT1_Pos (23U)
#define FLASH_OPTR_nBOOT1_Msk (0x1UL << FLASH_OPTR_nBOOT1_Pos) /*!< 0x00800000 */
#define FLASH_OPTR_nBOOT1 FLASH_OPTR_nBOOT1_Msk
#define FLASH_OPTR_SRAM_PE_Pos (24U)
#define FLASH_OPTR_SRAM_PE_Msk (0x1UL << FLASH_OPTR_SRAM_PE_Pos) /*!< 0x01000000 */
#define FLASH_OPTR_SRAM_PE FLASH_OPTR_SRAM_PE_Msk
#define FLASH_OPTR_CCMSRAM_RST_Pos (25U)
#define FLASH_OPTR_CCMSRAM_RST_Msk (0x1UL << FLASH_OPTR_CCMSRAM_RST_Pos)/*!< 0x02000000 */
#define FLASH_OPTR_CCMSRAM_RST FLASH_OPTR_CCMSRAM_RST_Msk
#define FLASH_OPTR_nSWBOOT0_Pos (26U)
#define FLASH_OPTR_nSWBOOT0_Msk (0x1UL << FLASH_OPTR_nSWBOOT0_Pos) /*!< 0x04000000 */
#define FLASH_OPTR_nSWBOOT0 FLASH_OPTR_nSWBOOT0_Msk
#define FLASH_OPTR_nBOOT0_Pos (27U)
#define FLASH_OPTR_nBOOT0_Msk (0x1UL << FLASH_OPTR_nBOOT0_Pos) /*!< 0x08000000 */
#define FLASH_OPTR_nBOOT0 FLASH_OPTR_nBOOT0_Msk
#define FLASH_OPTR_NRST_MODE_Pos (28U)
#define FLASH_OPTR_NRST_MODE_Msk (0x3UL << FLASH_OPTR_NRST_MODE_Pos) /*!< 0x30000000 */
#define FLASH_OPTR_NRST_MODE FLASH_OPTR_NRST_MODE_Msk
#define FLASH_OPTR_NRST_MODE_0 (0x1UL << FLASH_OPTR_NRST_MODE_Pos) /*!< 0x10000000 */
#define FLASH_OPTR_NRST_MODE_1 (0x2UL << FLASH_OPTR_NRST_MODE_Pos) /*!< 0x20000000 */
#define FLASH_OPTR_IRHEN_Pos (30U)
#define FLASH_OPTR_IRHEN_Msk (0x1UL << FLASH_OPTR_IRHEN_Pos) /*!< 0x40000000 */
#define FLASH_OPTR_IRHEN FLASH_OPTR_IRHEN_Msk
/****************** Bits definition for FLASH_PCROP1SR register **********/
#define FLASH_PCROP1SR_PCROP1_STRT_Pos (0U)
#define FLASH_PCROP1SR_PCROP1_STRT_Msk (0x3FFFUL << FLASH_PCROP1SR_PCROP1_STRT_Pos)/*!< 0x00003FFF */
#define FLASH_PCROP1SR_PCROP1_STRT FLASH_PCROP1SR_PCROP1_STRT_Msk
/****************** Bits definition for FLASH_PCROP1ER register ***********/
#define FLASH_PCROP1ER_PCROP1_END_Pos (0U)
#define FLASH_PCROP1ER_PCROP1_END_Msk (0x3FFFUL << FLASH_PCROP1ER_PCROP1_END_Pos)/*!< 0x00003FFF */
#define FLASH_PCROP1ER_PCROP1_END FLASH_PCROP1ER_PCROP1_END_Msk
#define FLASH_PCROP1ER_PCROP_RDP_Pos (31U)
#define FLASH_PCROP1ER_PCROP_RDP_Msk (0x1UL << FLASH_PCROP1ER_PCROP_RDP_Pos)/*!< 0x80000000 */
#define FLASH_PCROP1ER_PCROP_RDP FLASH_PCROP1ER_PCROP_RDP_Msk
/****************** Bits definition for FLASH_WRP1AR register ***************/
#define FLASH_WRP1AR_WRP1A_STRT_Pos (0U)
#define FLASH_WRP1AR_WRP1A_STRT_Msk (0x3FUL << FLASH_WRP1AR_WRP1A_STRT_Pos)/*!< 0x0000003F */
#define FLASH_WRP1AR_WRP1A_STRT FLASH_WRP1AR_WRP1A_STRT_Msk
#define FLASH_WRP1AR_WRP1A_END_Pos (16U)
#define FLASH_WRP1AR_WRP1A_END_Msk (0x3FUL << FLASH_WRP1AR_WRP1A_END_Pos)/*!< 0x003F0000 */
#define FLASH_WRP1AR_WRP1A_END FLASH_WRP1AR_WRP1A_END_Msk
/****************** Bits definition for FLASH_WRPB1R register ***************/
#define FLASH_WRP1BR_WRP1B_STRT_Pos (0U)
#define FLASH_WRP1BR_WRP1B_STRT_Msk (0x3FUL << FLASH_WRP1BR_WRP1B_STRT_Pos)/*!< 0x0000003F */
#define FLASH_WRP1BR_WRP1B_STRT FLASH_WRP1BR_WRP1B_STRT_Msk
#define FLASH_WRP1BR_WRP1B_END_Pos (16U)
#define FLASH_WRP1BR_WRP1B_END_Msk (0x3FUL << FLASH_WRP1BR_WRP1B_END_Pos)/*!< 0x003F0000 */
#define FLASH_WRP1BR_WRP1B_END FLASH_WRP1BR_WRP1B_END_Msk
/****************** Bits definition for FLASH_SEC1R register **************/
#define FLASH_SEC1R_SEC_SIZE1_Pos (0U)
#define FLASH_SEC1R_SEC_SIZE1_Msk (0x7FUL << FLASH_SEC1R_SEC_SIZE1_Pos)/*!< 0x0000007F */
#define FLASH_SEC1R_SEC_SIZE1 FLASH_SEC1R_SEC_SIZE1_Msk
#define FLASH_SEC1R_BOOT_LOCK_Pos (16U)
#define FLASH_SEC1R_BOOT_LOCK_Msk (0x1UL << FLASH_SEC1R_BOOT_LOCK_Pos)/*!< 0x00010000 */
#define FLASH_SEC1R_BOOT_LOCK FLASH_SEC1R_BOOT_LOCK_Msk
/******************************************************************************/
/* */
/* Filter Mathematical ACcelerator unit (FMAC) */
/* */
/******************************************************************************/
/***************** Bit definition for FMAC_X1BUFCFG register ****************/
#define FMAC_X1BUFCFG_X1_BASE_Pos (0U)
#define FMAC_X1BUFCFG_X1_BASE_Msk (0xFFUL << FMAC_X1BUFCFG_X1_BASE_Pos) /*!< 0x000000FF */
#define FMAC_X1BUFCFG_X1_BASE FMAC_X1BUFCFG_X1_BASE_Msk /*!< Base address of X1 buffer */
#define FMAC_X1BUFCFG_X1_BUF_SIZE_Pos (8U)
#define FMAC_X1BUFCFG_X1_BUF_SIZE_Msk (0xFFUL << FMAC_X1BUFCFG_X1_BUF_SIZE_Pos)/*!< 0x0000FF00 */
#define FMAC_X1BUFCFG_X1_BUF_SIZE FMAC_X1BUFCFG_X1_BUF_SIZE_Msk /*!< Allocated size of X1 buffer in 16-bit words */
#define FMAC_X1BUFCFG_FULL_WM_Pos (24U)
#define FMAC_X1BUFCFG_FULL_WM_Msk (0x3UL << FMAC_X1BUFCFG_FULL_WM_Pos) /*!< 0x03000000 */
#define FMAC_X1BUFCFG_FULL_WM FMAC_X1BUFCFG_FULL_WM_Msk /*!< Watermark for buffer full flag */
/***************** Bit definition for FMAC_X2BUFCFG register ****************/
#define FMAC_X2BUFCFG_X2_BASE_Pos (0U)
#define FMAC_X2BUFCFG_X2_BASE_Msk (0xFFUL << FMAC_X2BUFCFG_X2_BASE_Pos) /*!< 0x000000FF */
#define FMAC_X2BUFCFG_X2_BASE FMAC_X2BUFCFG_X2_BASE_Msk /*!< Base address of X2 buffer */
#define FMAC_X2BUFCFG_X2_BUF_SIZE_Pos (8U)
#define FMAC_X2BUFCFG_X2_BUF_SIZE_Msk (0xFFUL << FMAC_X2BUFCFG_X2_BUF_SIZE_Pos)/*!< 0x0000FF00 */
#define FMAC_X2BUFCFG_X2_BUF_SIZE FMAC_X2BUFCFG_X2_BUF_SIZE_Msk /*!< Size of X2 buffer in 16-bit words */
/***************** Bit definition for FMAC_YBUFCFG register *****************/
#define FMAC_YBUFCFG_Y_BASE_Pos (0U)
#define FMAC_YBUFCFG_Y_BASE_Msk (0xFFUL << FMAC_YBUFCFG_Y_BASE_Pos) /*!< 0x000000FF */
#define FMAC_YBUFCFG_Y_BASE FMAC_YBUFCFG_Y_BASE_Msk /*!< Base address of Y buffer */
#define FMAC_YBUFCFG_Y_BUF_SIZE_Pos (8U)
#define FMAC_YBUFCFG_Y_BUF_SIZE_Msk (0xFFUL << FMAC_YBUFCFG_Y_BUF_SIZE_Pos) /*!< 0x0000FF00 */
#define FMAC_YBUFCFG_Y_BUF_SIZE FMAC_YBUFCFG_Y_BUF_SIZE_Msk /*!< Size of Y buffer in 16-bit words */
#define FMAC_YBUFCFG_EMPTY_WM_Pos (24U)
#define FMAC_YBUFCFG_EMPTY_WM_Msk (0x3UL << FMAC_YBUFCFG_EMPTY_WM_Pos) /*!< 0x03000000 */
#define FMAC_YBUFCFG_EMPTY_WM FMAC_YBUFCFG_EMPTY_WM_Msk /*!< Watermark for buffer empty flag */
/****************** Bit definition for FMAC_PARAM register ******************/
#define FMAC_PARAM_P_Pos (0U)
#define FMAC_PARAM_P_Msk (0xFFUL << FMAC_PARAM_P_Pos) /*!< 0x000000FF */
#define FMAC_PARAM_P FMAC_PARAM_P_Msk /*!< Input parameter P */
#define FMAC_PARAM_Q_Pos (8U)
#define FMAC_PARAM_Q_Msk (0xFFUL << FMAC_PARAM_Q_Pos) /*!< 0x0000FF00 */
#define FMAC_PARAM_Q FMAC_PARAM_Q_Msk /*!< Input parameter Q */
#define FMAC_PARAM_R_Pos (16U)
#define FMAC_PARAM_R_Msk (0xFFUL << FMAC_PARAM_R_Pos) /*!< 0x00FF0000 */
#define FMAC_PARAM_R FMAC_PARAM_R_Msk /*!< Input parameter R */
#define FMAC_PARAM_FUNC_Pos (24U)
#define FMAC_PARAM_FUNC_Msk (0x7FUL << FMAC_PARAM_FUNC_Pos) /*!< 0x7F000000 */
#define FMAC_PARAM_FUNC FMAC_PARAM_FUNC_Msk /*!< Function */
#define FMAC_PARAM_FUNC_0 (0x1UL << FMAC_PARAM_FUNC_Pos) /*!< 0x01000000 */
#define FMAC_PARAM_FUNC_1 (0x2UL << FMAC_PARAM_FUNC_Pos) /*!< 0x02000000 */
#define FMAC_PARAM_FUNC_2 (0x4UL << FMAC_PARAM_FUNC_Pos) /*!< 0x04000000 */
#define FMAC_PARAM_FUNC_3 (0x8UL << FMAC_PARAM_FUNC_Pos) /*!< 0x08000000 */
#define FMAC_PARAM_FUNC_4 (0x10UL << FMAC_PARAM_FUNC_Pos) /*!< 0x10000000 */
#define FMAC_PARAM_FUNC_5 (0x20UL << FMAC_PARAM_FUNC_Pos) /*!< 0x20000000 */
#define FMAC_PARAM_FUNC_6 (0x40UL << FMAC_PARAM_FUNC_Pos) /*!< 0x40000000 */
#define FMAC_PARAM_START_Pos (31U)
#define FMAC_PARAM_START_Msk (0x1UL << FMAC_PARAM_START_Pos) /*!< 0x80000000 */
#define FMAC_PARAM_START FMAC_PARAM_START_Msk /*!< Enable execution */
/******************** Bit definition for FMAC_CR register *******************/
#define FMAC_CR_RIEN_Pos (0U)
#define FMAC_CR_RIEN_Msk (0x1UL << FMAC_CR_RIEN_Pos) /*!< 0x00000001 */
#define FMAC_CR_RIEN FMAC_CR_RIEN_Msk /*!< Enable read interrupt */
#define FMAC_CR_WIEN_Pos (1U)
#define FMAC_CR_WIEN_Msk (0x1UL << FMAC_CR_WIEN_Pos) /*!< 0x00000002 */
#define FMAC_CR_WIEN FMAC_CR_WIEN_Msk /*!< Enable write interrupt */
#define FMAC_CR_OVFLIEN_Pos (2U)
#define FMAC_CR_OVFLIEN_Msk (0x1UL << FMAC_CR_OVFLIEN_Pos) /*!< 0x00000004 */
#define FMAC_CR_OVFLIEN FMAC_CR_OVFLIEN_Msk /*!< Enable overflow error interrupts */
#define FMAC_CR_UNFLIEN_Pos (3U)
#define FMAC_CR_UNFLIEN_Msk (0x1UL << FMAC_CR_UNFLIEN_Pos) /*!< 0x00000008 */
#define FMAC_CR_UNFLIEN FMAC_CR_UNFLIEN_Msk /*!< Enable underflow error interrupts */
#define FMAC_CR_SATIEN_Pos (4U)
#define FMAC_CR_SATIEN_Msk (0x1UL << FMAC_CR_SATIEN_Pos) /*!< 0x00000010 */
#define FMAC_CR_SATIEN FMAC_CR_SATIEN_Msk /*!< Enable saturation error interrupts */
#define FMAC_CR_DMAREN_Pos (8U)
#define FMAC_CR_DMAREN_Msk (0x1UL << FMAC_CR_DMAREN_Pos) /*!< 0x00000100 */
#define FMAC_CR_DMAREN FMAC_CR_DMAREN_Msk /*!< Enable DMA read channel requests */
#define FMAC_CR_DMAWEN_Pos (9U)
#define FMAC_CR_DMAWEN_Msk (0x1UL << FMAC_CR_DMAWEN_Pos) /*!< 0x00000200 */
#define FMAC_CR_DMAWEN FMAC_CR_DMAWEN_Msk /*!< Enable DMA write channel requests */
#define FMAC_CR_CLIPEN_Pos (15U)
#define FMAC_CR_CLIPEN_Msk (0x1UL << FMAC_CR_CLIPEN_Pos) /*!< 0x00008000 */
#define FMAC_CR_CLIPEN FMAC_CR_CLIPEN_Msk /*!< Enable clipping */
#define FMAC_CR_RESET_Pos (16U)
#define FMAC_CR_RESET_Msk (0x1UL << FMAC_CR_RESET_Pos) /*!< 0x00010000 */
#define FMAC_CR_RESET FMAC_CR_RESET_Msk /*!< Reset filter mathematical accelerator unit */
/******************* Bit definition for FMAC_SR register ********************/
#define FMAC_SR_YEMPTY_Pos (0U)
#define FMAC_SR_YEMPTY_Msk (0x1UL << FMAC_SR_YEMPTY_Pos) /*!< 0x00000001 */
#define FMAC_SR_YEMPTY FMAC_SR_YEMPTY_Msk /*!< Y buffer empty flag */
#define FMAC_SR_X1FULL_Pos (1U)
#define FMAC_SR_X1FULL_Msk (0x1UL << FMAC_SR_X1FULL_Pos) /*!< 0x00000002 */
#define FMAC_SR_X1FULL FMAC_SR_X1FULL_Msk /*!< X1 buffer full flag */
#define FMAC_SR_OVFL_Pos (8U)
#define FMAC_SR_OVFL_Msk (0x1UL << FMAC_SR_OVFL_Pos) /*!< 0x00000100 */
#define FMAC_SR_OVFL FMAC_SR_OVFL_Msk /*!< Overflow error flag */
#define FMAC_SR_UNFL_Pos (9U)
#define FMAC_SR_UNFL_Msk (0x1UL << FMAC_SR_UNFL_Pos) /*!< 0x00000200 */
#define FMAC_SR_UNFL FMAC_SR_UNFL_Msk /*!< Underflow error flag */
#define FMAC_SR_SAT_Pos (10U)
#define FMAC_SR_SAT_Msk (0x1UL << FMAC_SR_SAT_Pos) /*!< 0x00000400 */
#define FMAC_SR_SAT FMAC_SR_SAT_Msk /*!< Saturation error flag */
/****************** Bit definition for FMAC_WDATA register ******************/
#define FMAC_WDATA_WDATA_Pos (0U)
#define FMAC_WDATA_WDATA_Msk (0xFFFFUL << FMAC_WDATA_WDATA_Pos) /*!< 0x0000FFFF */
#define FMAC_WDATA_WDATA FMAC_WDATA_WDATA_Msk /*!< Write data */
/****************** Bit definition for FMACX_RDATA register *****************/
#define FMAC_RDATA_RDATA_Pos (0U)
#define FMAC_RDATA_RDATA_Msk (0xFFFFUL << FMAC_RDATA_RDATA_Pos) /*!< 0x0000FFFF */
#define FMAC_RDATA_RDATA FMAC_RDATA_RDATA_Msk /*!< Read data */
/******************************************************************************/
/* */
/* General Purpose IOs (GPIO) */
/* */
/******************************************************************************/
/****************** Bits definition for GPIO_MODER register *****************/
#define GPIO_MODER_MODE0_Pos (0U)
#define GPIO_MODER_MODE0_Msk (0x3UL << GPIO_MODER_MODE0_Pos) /*!< 0x00000003 */
#define GPIO_MODER_MODE0 GPIO_MODER_MODE0_Msk
#define GPIO_MODER_MODE0_0 (0x1UL << GPIO_MODER_MODE0_Pos) /*!< 0x00000001 */
#define GPIO_MODER_MODE0_1 (0x2UL << GPIO_MODER_MODE0_Pos) /*!< 0x00000002 */
#define GPIO_MODER_MODE1_Pos (2U)
#define GPIO_MODER_MODE1_Msk (0x3UL << GPIO_MODER_MODE1_Pos) /*!< 0x0000000C */
#define GPIO_MODER_MODE1 GPIO_MODER_MODE1_Msk
#define GPIO_MODER_MODE1_0 (0x1UL << GPIO_MODER_MODE1_Pos) /*!< 0x00000004 */
#define GPIO_MODER_MODE1_1 (0x2UL << GPIO_MODER_MODE1_Pos) /*!< 0x00000008 */
#define GPIO_MODER_MODE2_Pos (4U)
#define GPIO_MODER_MODE2_Msk (0x3UL << GPIO_MODER_MODE2_Pos) /*!< 0x00000030 */
#define GPIO_MODER_MODE2 GPIO_MODER_MODE2_Msk
#define GPIO_MODER_MODE2_0 (0x1UL << GPIO_MODER_MODE2_Pos) /*!< 0x00000010 */
#define GPIO_MODER_MODE2_1 (0x2UL << GPIO_MODER_MODE2_Pos) /*!< 0x00000020 */
#define GPIO_MODER_MODE3_Pos (6U)
#define GPIO_MODER_MODE3_Msk (0x3UL << GPIO_MODER_MODE3_Pos) /*!< 0x000000C0 */
#define GPIO_MODER_MODE3 GPIO_MODER_MODE3_Msk
#define GPIO_MODER_MODE3_0 (0x1UL << GPIO_MODER_MODE3_Pos) /*!< 0x00000040 */
#define GPIO_MODER_MODE3_1 (0x2UL << GPIO_MODER_MODE3_Pos) /*!< 0x00000080 */
#define GPIO_MODER_MODE4_Pos (8U)
#define GPIO_MODER_MODE4_Msk (0x3UL << GPIO_MODER_MODE4_Pos) /*!< 0x00000300 */
#define GPIO_MODER_MODE4 GPIO_MODER_MODE4_Msk
#define GPIO_MODER_MODE4_0 (0x1UL << GPIO_MODER_MODE4_Pos) /*!< 0x00000100 */
#define GPIO_MODER_MODE4_1 (0x2UL << GPIO_MODER_MODE4_Pos) /*!< 0x00000200 */
#define GPIO_MODER_MODE5_Pos (10U)
#define GPIO_MODER_MODE5_Msk (0x3UL << GPIO_MODER_MODE5_Pos) /*!< 0x00000C00 */
#define GPIO_MODER_MODE5 GPIO_MODER_MODE5_Msk
#define GPIO_MODER_MODE5_0 (0x1UL << GPIO_MODER_MODE5_Pos) /*!< 0x00000400 */
#define GPIO_MODER_MODE5_1 (0x2UL << GPIO_MODER_MODE5_Pos) /*!< 0x00000800 */
#define GPIO_MODER_MODE6_Pos (12U)
#define GPIO_MODER_MODE6_Msk (0x3UL << GPIO_MODER_MODE6_Pos) /*!< 0x00003000 */
#define GPIO_MODER_MODE6 GPIO_MODER_MODE6_Msk
#define GPIO_MODER_MODE6_0 (0x1UL << GPIO_MODER_MODE6_Pos) /*!< 0x00001000 */
#define GPIO_MODER_MODE6_1 (0x2UL << GPIO_MODER_MODE6_Pos) /*!< 0x00002000 */
#define GPIO_MODER_MODE7_Pos (14U)
#define GPIO_MODER_MODE7_Msk (0x3UL << GPIO_MODER_MODE7_Pos) /*!< 0x0000C000 */
#define GPIO_MODER_MODE7 GPIO_MODER_MODE7_Msk
#define GPIO_MODER_MODE7_0 (0x1UL << GPIO_MODER_MODE7_Pos) /*!< 0x00004000 */
#define GPIO_MODER_MODE7_1 (0x2UL << GPIO_MODER_MODE7_Pos) /*!< 0x00008000 */
#define GPIO_MODER_MODE8_Pos (16U)
#define GPIO_MODER_MODE8_Msk (0x3UL << GPIO_MODER_MODE8_Pos) /*!< 0x00030000 */
#define GPIO_MODER_MODE8 GPIO_MODER_MODE8_Msk
#define GPIO_MODER_MODE8_0 (0x1UL << GPIO_MODER_MODE8_Pos) /*!< 0x00010000 */
#define GPIO_MODER_MODE8_1 (0x2UL << GPIO_MODER_MODE8_Pos) /*!< 0x00020000 */
#define GPIO_MODER_MODE9_Pos (18U)
#define GPIO_MODER_MODE9_Msk (0x3UL << GPIO_MODER_MODE9_Pos) /*!< 0x000C0000 */
#define GPIO_MODER_MODE9 GPIO_MODER_MODE9_Msk
#define GPIO_MODER_MODE9_0 (0x1UL << GPIO_MODER_MODE9_Pos) /*!< 0x00040000 */
#define GPIO_MODER_MODE9_1 (0x2UL << GPIO_MODER_MODE9_Pos) /*!< 0x00080000 */
#define GPIO_MODER_MODE10_Pos (20U)
#define GPIO_MODER_MODE10_Msk (0x3UL << GPIO_MODER_MODE10_Pos) /*!< 0x00300000 */
#define GPIO_MODER_MODE10 GPIO_MODER_MODE10_Msk
#define GPIO_MODER_MODE10_0 (0x1UL << GPIO_MODER_MODE10_Pos) /*!< 0x00100000 */
#define GPIO_MODER_MODE10_1 (0x2UL << GPIO_MODER_MODE10_Pos) /*!< 0x00200000 */
#define GPIO_MODER_MODE11_Pos (22U)
#define GPIO_MODER_MODE11_Msk (0x3UL << GPIO_MODER_MODE11_Pos) /*!< 0x00C00000 */
#define GPIO_MODER_MODE11 GPIO_MODER_MODE11_Msk
#define GPIO_MODER_MODE11_0 (0x1UL << GPIO_MODER_MODE11_Pos) /*!< 0x00400000 */
#define GPIO_MODER_MODE11_1 (0x2UL << GPIO_MODER_MODE11_Pos) /*!< 0x00800000 */
#define GPIO_MODER_MODE12_Pos (24U)
#define GPIO_MODER_MODE12_Msk (0x3UL << GPIO_MODER_MODE12_Pos) /*!< 0x03000000 */
#define GPIO_MODER_MODE12 GPIO_MODER_MODE12_Msk
#define GPIO_MODER_MODE12_0 (0x1UL << GPIO_MODER_MODE12_Pos) /*!< 0x01000000 */
#define GPIO_MODER_MODE12_1 (0x2UL << GPIO_MODER_MODE12_Pos) /*!< 0x02000000 */
#define GPIO_MODER_MODE13_Pos (26U)
#define GPIO_MODER_MODE13_Msk (0x3UL << GPIO_MODER_MODE13_Pos) /*!< 0x0C000000 */
#define GPIO_MODER_MODE13 GPIO_MODER_MODE13_Msk
#define GPIO_MODER_MODE13_0 (0x1UL << GPIO_MODER_MODE13_Pos) /*!< 0x04000000 */
#define GPIO_MODER_MODE13_1 (0x2UL << GPIO_MODER_MODE13_Pos) /*!< 0x08000000 */
#define GPIO_MODER_MODE14_Pos (28U)
#define GPIO_MODER_MODE14_Msk (0x3UL << GPIO_MODER_MODE14_Pos) /*!< 0x30000000 */
#define GPIO_MODER_MODE14 GPIO_MODER_MODE14_Msk
#define GPIO_MODER_MODE14_0 (0x1UL << GPIO_MODER_MODE14_Pos) /*!< 0x10000000 */
#define GPIO_MODER_MODE14_1 (0x2UL << GPIO_MODER_MODE14_Pos) /*!< 0x20000000 */
#define GPIO_MODER_MODE15_Pos (30U)
#define GPIO_MODER_MODE15_Msk (0x3UL << GPIO_MODER_MODE15_Pos) /*!< 0xC0000000 */
#define GPIO_MODER_MODE15 GPIO_MODER_MODE15_Msk
#define GPIO_MODER_MODE15_0 (0x1UL << GPIO_MODER_MODE15_Pos) /*!< 0x40000000 */
#define GPIO_MODER_MODE15_1 (0x2UL << GPIO_MODER_MODE15_Pos) /*!< 0x80000000 */
/* Legacy defines */
#define GPIO_MODER_MODER0 GPIO_MODER_MODE0
#define GPIO_MODER_MODER0_0 GPIO_MODER_MODE0_0
#define GPIO_MODER_MODER0_1 GPIO_MODER_MODE0_1
#define GPIO_MODER_MODER1 GPIO_MODER_MODE1
#define GPIO_MODER_MODER1_0 GPIO_MODER_MODE1_0
#define GPIO_MODER_MODER1_1 GPIO_MODER_MODE1_1
#define GPIO_MODER_MODER2 GPIO_MODER_MODE2
#define GPIO_MODER_MODER2_0 GPIO_MODER_MODE2_0
#define GPIO_MODER_MODER2_1 GPIO_MODER_MODE2_1
#define GPIO_MODER_MODER3 GPIO_MODER_MODE3
#define GPIO_MODER_MODER3_0 GPIO_MODER_MODE3_0
#define GPIO_MODER_MODER3_1 GPIO_MODER_MODE3_1
#define GPIO_MODER_MODER4 GPIO_MODER_MODE4
#define GPIO_MODER_MODER4_0 GPIO_MODER_MODE4_0
#define GPIO_MODER_MODER4_1 GPIO_MODER_MODE4_1
#define GPIO_MODER_MODER5 GPIO_MODER_MODE5
#define GPIO_MODER_MODER5_0 GPIO_MODER_MODE5_0
#define GPIO_MODER_MODER5_1 GPIO_MODER_MODE5_1
#define GPIO_MODER_MODER6 GPIO_MODER_MODE6
#define GPIO_MODER_MODER6_0 GPIO_MODER_MODE6_0
#define GPIO_MODER_MODER6_1 GPIO_MODER_MODE6_1
#define GPIO_MODER_MODER7 GPIO_MODER_MODE7
#define GPIO_MODER_MODER7_0 GPIO_MODER_MODE7_0
#define GPIO_MODER_MODER7_1 GPIO_MODER_MODE7_1
#define GPIO_MODER_MODER8 GPIO_MODER_MODE8
#define GPIO_MODER_MODER8_0 GPIO_MODER_MODE8_0
#define GPIO_MODER_MODER8_1 GPIO_MODER_MODE8_1
#define GPIO_MODER_MODER9 GPIO_MODER_MODE9
#define GPIO_MODER_MODER9_0 GPIO_MODER_MODE9_0
#define GPIO_MODER_MODER9_1 GPIO_MODER_MODE9_1
#define GPIO_MODER_MODER10 GPIO_MODER_MODE10
#define GPIO_MODER_MODER10_0 GPIO_MODER_MODE10_0
#define GPIO_MODER_MODER10_1 GPIO_MODER_MODE10_1
#define GPIO_MODER_MODER11 GPIO_MODER_MODE11
#define GPIO_MODER_MODER11_0 GPIO_MODER_MODE11_0
#define GPIO_MODER_MODER11_1 GPIO_MODER_MODE11_1
#define GPIO_MODER_MODER12 GPIO_MODER_MODE12
#define GPIO_MODER_MODER12_0 GPIO_MODER_MODE12_0
#define GPIO_MODER_MODER12_1 GPIO_MODER_MODE12_1
#define GPIO_MODER_MODER13 GPIO_MODER_MODE13
#define GPIO_MODER_MODER13_0 GPIO_MODER_MODE13_0
#define GPIO_MODER_MODER13_1 GPIO_MODER_MODE13_1
#define GPIO_MODER_MODER14 GPIO_MODER_MODE14
#define GPIO_MODER_MODER14_0 GPIO_MODER_MODE14_0
#define GPIO_MODER_MODER14_1 GPIO_MODER_MODE14_1
#define GPIO_MODER_MODER15 GPIO_MODER_MODE15
#define GPIO_MODER_MODER15_0 GPIO_MODER_MODE15_0
#define GPIO_MODER_MODER15_1 GPIO_MODER_MODE15_1
/****************** Bits definition for GPIO_OTYPER register ****************/
#define GPIO_OTYPER_OT0_Pos (0U)
#define GPIO_OTYPER_OT0_Msk (0x1UL << GPIO_OTYPER_OT0_Pos) /*!< 0x00000001 */
#define GPIO_OTYPER_OT0 GPIO_OTYPER_OT0_Msk
#define GPIO_OTYPER_OT1_Pos (1U)
#define GPIO_OTYPER_OT1_Msk (0x1UL << GPIO_OTYPER_OT1_Pos) /*!< 0x00000002 */
#define GPIO_OTYPER_OT1 GPIO_OTYPER_OT1_Msk
#define GPIO_OTYPER_OT2_Pos (2U)
#define GPIO_OTYPER_OT2_Msk (0x1UL << GPIO_OTYPER_OT2_Pos) /*!< 0x00000004 */
#define GPIO_OTYPER_OT2 GPIO_OTYPER_OT2_Msk
#define GPIO_OTYPER_OT3_Pos (3U)
#define GPIO_OTYPER_OT3_Msk (0x1UL << GPIO_OTYPER_OT3_Pos) /*!< 0x00000008 */
#define GPIO_OTYPER_OT3 GPIO_OTYPER_OT3_Msk
#define GPIO_OTYPER_OT4_Pos (4U)
#define GPIO_OTYPER_OT4_Msk (0x1UL << GPIO_OTYPER_OT4_Pos) /*!< 0x00000010 */
#define GPIO_OTYPER_OT4 GPIO_OTYPER_OT4_Msk
#define GPIO_OTYPER_OT5_Pos (5U)
#define GPIO_OTYPER_OT5_Msk (0x1UL << GPIO_OTYPER_OT5_Pos) /*!< 0x00000020 */
#define GPIO_OTYPER_OT5 GPIO_OTYPER_OT5_Msk
#define GPIO_OTYPER_OT6_Pos (6U)
#define GPIO_OTYPER_OT6_Msk (0x1UL << GPIO_OTYPER_OT6_Pos) /*!< 0x00000040 */
#define GPIO_OTYPER_OT6 GPIO_OTYPER_OT6_Msk
#define GPIO_OTYPER_OT7_Pos (7U)
#define GPIO_OTYPER_OT7_Msk (0x1UL << GPIO_OTYPER_OT7_Pos) /*!< 0x00000080 */
#define GPIO_OTYPER_OT7 GPIO_OTYPER_OT7_Msk
#define GPIO_OTYPER_OT8_Pos (8U)
#define GPIO_OTYPER_OT8_Msk (0x1UL << GPIO_OTYPER_OT8_Pos) /*!< 0x00000100 */
#define GPIO_OTYPER_OT8 GPIO_OTYPER_OT8_Msk
#define GPIO_OTYPER_OT9_Pos (9U)
#define GPIO_OTYPER_OT9_Msk (0x1UL << GPIO_OTYPER_OT9_Pos) /*!< 0x00000200 */
#define GPIO_OTYPER_OT9 GPIO_OTYPER_OT9_Msk
#define GPIO_OTYPER_OT10_Pos (10U)
#define GPIO_OTYPER_OT10_Msk (0x1UL << GPIO_OTYPER_OT10_Pos) /*!< 0x00000400 */
#define GPIO_OTYPER_OT10 GPIO_OTYPER_OT10_Msk
#define GPIO_OTYPER_OT11_Pos (11U)
#define GPIO_OTYPER_OT11_Msk (0x1UL << GPIO_OTYPER_OT11_Pos) /*!< 0x00000800 */
#define GPIO_OTYPER_OT11 GPIO_OTYPER_OT11_Msk
#define GPIO_OTYPER_OT12_Pos (12U)
#define GPIO_OTYPER_OT12_Msk (0x1UL << GPIO_OTYPER_OT12_Pos) /*!< 0x00001000 */
#define GPIO_OTYPER_OT12 GPIO_OTYPER_OT12_Msk
#define GPIO_OTYPER_OT13_Pos (13U)
#define GPIO_OTYPER_OT13_Msk (0x1UL << GPIO_OTYPER_OT13_Pos) /*!< 0x00002000 */
#define GPIO_OTYPER_OT13 GPIO_OTYPER_OT13_Msk
#define GPIO_OTYPER_OT14_Pos (14U)
#define GPIO_OTYPER_OT14_Msk (0x1UL << GPIO_OTYPER_OT14_Pos) /*!< 0x00004000 */
#define GPIO_OTYPER_OT14 GPIO_OTYPER_OT14_Msk
#define GPIO_OTYPER_OT15_Pos (15U)
#define GPIO_OTYPER_OT15_Msk (0x1UL << GPIO_OTYPER_OT15_Pos) /*!< 0x00008000 */
#define GPIO_OTYPER_OT15 GPIO_OTYPER_OT15_Msk
/* Legacy defines */
#define GPIO_OTYPER_OT_0 GPIO_OTYPER_OT0
#define GPIO_OTYPER_OT_1 GPIO_OTYPER_OT1
#define GPIO_OTYPER_OT_2 GPIO_OTYPER_OT2
#define GPIO_OTYPER_OT_3 GPIO_OTYPER_OT3
#define GPIO_OTYPER_OT_4 GPIO_OTYPER_OT4
#define GPIO_OTYPER_OT_5 GPIO_OTYPER_OT5
#define GPIO_OTYPER_OT_6 GPIO_OTYPER_OT6
#define GPIO_OTYPER_OT_7 GPIO_OTYPER_OT7
#define GPIO_OTYPER_OT_8 GPIO_OTYPER_OT8
#define GPIO_OTYPER_OT_9 GPIO_OTYPER_OT9
#define GPIO_OTYPER_OT_10 GPIO_OTYPER_OT10
#define GPIO_OTYPER_OT_11 GPIO_OTYPER_OT11
#define GPIO_OTYPER_OT_12 GPIO_OTYPER_OT12
#define GPIO_OTYPER_OT_13 GPIO_OTYPER_OT13
#define GPIO_OTYPER_OT_14 GPIO_OTYPER_OT14
#define GPIO_OTYPER_OT_15 GPIO_OTYPER_OT15
/****************** Bits definition for GPIO_OSPEEDR register ***************/
#define GPIO_OSPEEDR_OSPEED0_Pos (0U)
#define GPIO_OSPEEDR_OSPEED0_Msk (0x3UL << GPIO_OSPEEDR_OSPEED0_Pos) /*!< 0x00000003 */
#define GPIO_OSPEEDR_OSPEED0 GPIO_OSPEEDR_OSPEED0_Msk
#define GPIO_OSPEEDR_OSPEED0_0 (0x1UL << GPIO_OSPEEDR_OSPEED0_Pos) /*!< 0x00000001 */
#define GPIO_OSPEEDR_OSPEED0_1 (0x2UL << GPIO_OSPEEDR_OSPEED0_Pos) /*!< 0x00000002 */
#define GPIO_OSPEEDR_OSPEED1_Pos (2U)
#define GPIO_OSPEEDR_OSPEED1_Msk (0x3UL << GPIO_OSPEEDR_OSPEED1_Pos) /*!< 0x0000000C */
#define GPIO_OSPEEDR_OSPEED1 GPIO_OSPEEDR_OSPEED1_Msk
#define GPIO_OSPEEDR_OSPEED1_0 (0x1UL << GPIO_OSPEEDR_OSPEED1_Pos) /*!< 0x00000004 */
#define GPIO_OSPEEDR_OSPEED1_1 (0x2UL << GPIO_OSPEEDR_OSPEED1_Pos) /*!< 0x00000008 */
#define GPIO_OSPEEDR_OSPEED2_Pos (4U)
#define GPIO_OSPEEDR_OSPEED2_Msk (0x3UL << GPIO_OSPEEDR_OSPEED2_Pos) /*!< 0x00000030 */
#define GPIO_OSPEEDR_OSPEED2 GPIO_OSPEEDR_OSPEED2_Msk
#define GPIO_OSPEEDR_OSPEED2_0 (0x1UL << GPIO_OSPEEDR_OSPEED2_Pos) /*!< 0x00000010 */
#define GPIO_OSPEEDR_OSPEED2_1 (0x2UL << GPIO_OSPEEDR_OSPEED2_Pos) /*!< 0x00000020 */
#define GPIO_OSPEEDR_OSPEED3_Pos (6U)
#define GPIO_OSPEEDR_OSPEED3_Msk (0x3UL << GPIO_OSPEEDR_OSPEED3_Pos) /*!< 0x000000C0 */
#define GPIO_OSPEEDR_OSPEED3 GPIO_OSPEEDR_OSPEED3_Msk
#define GPIO_OSPEEDR_OSPEED3_0 (0x1UL << GPIO_OSPEEDR_OSPEED3_Pos) /*!< 0x00000040 */
#define GPIO_OSPEEDR_OSPEED3_1 (0x2UL << GPIO_OSPEEDR_OSPEED3_Pos) /*!< 0x00000080 */
#define GPIO_OSPEEDR_OSPEED4_Pos (8U)
#define GPIO_OSPEEDR_OSPEED4_Msk (0x3UL << GPIO_OSPEEDR_OSPEED4_Pos) /*!< 0x00000300 */
#define GPIO_OSPEEDR_OSPEED4 GPIO_OSPEEDR_OSPEED4_Msk
#define GPIO_OSPEEDR_OSPEED4_0 (0x1UL << GPIO_OSPEEDR_OSPEED4_Pos) /*!< 0x00000100 */
#define GPIO_OSPEEDR_OSPEED4_1 (0x2UL << GPIO_OSPEEDR_OSPEED4_Pos) /*!< 0x00000200 */
#define GPIO_OSPEEDR_OSPEED5_Pos (10U)
#define GPIO_OSPEEDR_OSPEED5_Msk (0x3UL << GPIO_OSPEEDR_OSPEED5_Pos) /*!< 0x00000C00 */
#define GPIO_OSPEEDR_OSPEED5 GPIO_OSPEEDR_OSPEED5_Msk
#define GPIO_OSPEEDR_OSPEED5_0 (0x1UL << GPIO_OSPEEDR_OSPEED5_Pos) /*!< 0x00000400 */
#define GPIO_OSPEEDR_OSPEED5_1 (0x2UL << GPIO_OSPEEDR_OSPEED5_Pos) /*!< 0x00000800 */
#define GPIO_OSPEEDR_OSPEED6_Pos (12U)
#define GPIO_OSPEEDR_OSPEED6_Msk (0x3UL << GPIO_OSPEEDR_OSPEED6_Pos) /*!< 0x00003000 */
#define GPIO_OSPEEDR_OSPEED6 GPIO_OSPEEDR_OSPEED6_Msk
#define GPIO_OSPEEDR_OSPEED6_0 (0x1UL << GPIO_OSPEEDR_OSPEED6_Pos) /*!< 0x00001000 */
#define GPIO_OSPEEDR_OSPEED6_1 (0x2UL << GPIO_OSPEEDR_OSPEED6_Pos) /*!< 0x00002000 */
#define GPIO_OSPEEDR_OSPEED7_Pos (14U)
#define GPIO_OSPEEDR_OSPEED7_Msk (0x3UL << GPIO_OSPEEDR_OSPEED7_Pos) /*!< 0x0000C000 */
#define GPIO_OSPEEDR_OSPEED7 GPIO_OSPEEDR_OSPEED7_Msk
#define GPIO_OSPEEDR_OSPEED7_0 (0x1UL << GPIO_OSPEEDR_OSPEED7_Pos) /*!< 0x00004000 */
#define GPIO_OSPEEDR_OSPEED7_1 (0x2UL << GPIO_OSPEEDR_OSPEED7_Pos) /*!< 0x00008000 */
#define GPIO_OSPEEDR_OSPEED8_Pos (16U)
#define GPIO_OSPEEDR_OSPEED8_Msk (0x3UL << GPIO_OSPEEDR_OSPEED8_Pos) /*!< 0x00030000 */
#define GPIO_OSPEEDR_OSPEED8 GPIO_OSPEEDR_OSPEED8_Msk
#define GPIO_OSPEEDR_OSPEED8_0 (0x1UL << GPIO_OSPEEDR_OSPEED8_Pos) /*!< 0x00010000 */
#define GPIO_OSPEEDR_OSPEED8_1 (0x2UL << GPIO_OSPEEDR_OSPEED8_Pos) /*!< 0x00020000 */
#define GPIO_OSPEEDR_OSPEED9_Pos (18U)
#define GPIO_OSPEEDR_OSPEED9_Msk (0x3UL << GPIO_OSPEEDR_OSPEED9_Pos) /*!< 0x000C0000 */
#define GPIO_OSPEEDR_OSPEED9 GPIO_OSPEEDR_OSPEED9_Msk
#define GPIO_OSPEEDR_OSPEED9_0 (0x1UL << GPIO_OSPEEDR_OSPEED9_Pos) /*!< 0x00040000 */
#define GPIO_OSPEEDR_OSPEED9_1 (0x2UL << GPIO_OSPEEDR_OSPEED9_Pos) /*!< 0x00080000 */
#define GPIO_OSPEEDR_OSPEED10_Pos (20U)
#define GPIO_OSPEEDR_OSPEED10_Msk (0x3UL << GPIO_OSPEEDR_OSPEED10_Pos) /*!< 0x00300000 */
#define GPIO_OSPEEDR_OSPEED10 GPIO_OSPEEDR_OSPEED10_Msk
#define GPIO_OSPEEDR_OSPEED10_0 (0x1UL << GPIO_OSPEEDR_OSPEED10_Pos) /*!< 0x00100000 */
#define GPIO_OSPEEDR_OSPEED10_1 (0x2UL << GPIO_OSPEEDR_OSPEED10_Pos) /*!< 0x00200000 */
#define GPIO_OSPEEDR_OSPEED11_Pos (22U)
#define GPIO_OSPEEDR_OSPEED11_Msk (0x3UL << GPIO_OSPEEDR_OSPEED11_Pos) /*!< 0x00C00000 */
#define GPIO_OSPEEDR_OSPEED11 GPIO_OSPEEDR_OSPEED11_Msk
#define GPIO_OSPEEDR_OSPEED11_0 (0x1UL << GPIO_OSPEEDR_OSPEED11_Pos) /*!< 0x00400000 */
#define GPIO_OSPEEDR_OSPEED11_1 (0x2UL << GPIO_OSPEEDR_OSPEED11_Pos) /*!< 0x00800000 */
#define GPIO_OSPEEDR_OSPEED12_Pos (24U)
#define GPIO_OSPEEDR_OSPEED12_Msk (0x3UL << GPIO_OSPEEDR_OSPEED12_Pos) /*!< 0x03000000 */
#define GPIO_OSPEEDR_OSPEED12 GPIO_OSPEEDR_OSPEED12_Msk
#define GPIO_OSPEEDR_OSPEED12_0 (0x1UL << GPIO_OSPEEDR_OSPEED12_Pos) /*!< 0x01000000 */
#define GPIO_OSPEEDR_OSPEED12_1 (0x2UL << GPIO_OSPEEDR_OSPEED12_Pos) /*!< 0x02000000 */
#define GPIO_OSPEEDR_OSPEED13_Pos (26U)
#define GPIO_OSPEEDR_OSPEED13_Msk (0x3UL << GPIO_OSPEEDR_OSPEED13_Pos) /*!< 0x0C000000 */
#define GPIO_OSPEEDR_OSPEED13 GPIO_OSPEEDR_OSPEED13_Msk
#define GPIO_OSPEEDR_OSPEED13_0 (0x1UL << GPIO_OSPEEDR_OSPEED13_Pos) /*!< 0x04000000 */
#define GPIO_OSPEEDR_OSPEED13_1 (0x2UL << GPIO_OSPEEDR_OSPEED13_Pos) /*!< 0x08000000 */
#define GPIO_OSPEEDR_OSPEED14_Pos (28U)
#define GPIO_OSPEEDR_OSPEED14_Msk (0x3UL << GPIO_OSPEEDR_OSPEED14_Pos) /*!< 0x30000000 */
#define GPIO_OSPEEDR_OSPEED14 GPIO_OSPEEDR_OSPEED14_Msk
#define GPIO_OSPEEDR_OSPEED14_0 (0x1UL << GPIO_OSPEEDR_OSPEED14_Pos) /*!< 0x10000000 */
#define GPIO_OSPEEDR_OSPEED14_1 (0x2UL << GPIO_OSPEEDR_OSPEED14_Pos) /*!< 0x20000000 */
#define GPIO_OSPEEDR_OSPEED15_Pos (30U)
#define GPIO_OSPEEDR_OSPEED15_Msk (0x3UL << GPIO_OSPEEDR_OSPEED15_Pos) /*!< 0xC0000000 */
#define GPIO_OSPEEDR_OSPEED15 GPIO_OSPEEDR_OSPEED15_Msk
#define GPIO_OSPEEDR_OSPEED15_0 (0x1UL << GPIO_OSPEEDR_OSPEED15_Pos) /*!< 0x40000000 */
#define GPIO_OSPEEDR_OSPEED15_1 (0x2UL << GPIO_OSPEEDR_OSPEED15_Pos) /*!< 0x80000000 */
/* Legacy defines */
#define GPIO_OSPEEDER_OSPEEDR0 GPIO_OSPEEDR_OSPEED0
#define GPIO_OSPEEDER_OSPEEDR0_0 GPIO_OSPEEDR_OSPEED0_0
#define GPIO_OSPEEDER_OSPEEDR0_1 GPIO_OSPEEDR_OSPEED0_1
#define GPIO_OSPEEDER_OSPEEDR1 GPIO_OSPEEDR_OSPEED1
#define GPIO_OSPEEDER_OSPEEDR1_0 GPIO_OSPEEDR_OSPEED1_0
#define GPIO_OSPEEDER_OSPEEDR1_1 GPIO_OSPEEDR_OSPEED1_1
#define GPIO_OSPEEDER_OSPEEDR2 GPIO_OSPEEDR_OSPEED2
#define GPIO_OSPEEDER_OSPEEDR2_0 GPIO_OSPEEDR_OSPEED2_0
#define GPIO_OSPEEDER_OSPEEDR2_1 GPIO_OSPEEDR_OSPEED2_1
#define GPIO_OSPEEDER_OSPEEDR3 GPIO_OSPEEDR_OSPEED3
#define GPIO_OSPEEDER_OSPEEDR3_0 GPIO_OSPEEDR_OSPEED3_0
#define GPIO_OSPEEDER_OSPEEDR3_1 GPIO_OSPEEDR_OSPEED3_1
#define GPIO_OSPEEDER_OSPEEDR4 GPIO_OSPEEDR_OSPEED4
#define GPIO_OSPEEDER_OSPEEDR4_0 GPIO_OSPEEDR_OSPEED4_0
#define GPIO_OSPEEDER_OSPEEDR4_1 GPIO_OSPEEDR_OSPEED4_1
#define GPIO_OSPEEDER_OSPEEDR5 GPIO_OSPEEDR_OSPEED5
#define GPIO_OSPEEDER_OSPEEDR5_0 GPIO_OSPEEDR_OSPEED5_0
#define GPIO_OSPEEDER_OSPEEDR5_1 GPIO_OSPEEDR_OSPEED5_1
#define GPIO_OSPEEDER_OSPEEDR6 GPIO_OSPEEDR_OSPEED6
#define GPIO_OSPEEDER_OSPEEDR6_0 GPIO_OSPEEDR_OSPEED6_0
#define GPIO_OSPEEDER_OSPEEDR6_1 GPIO_OSPEEDR_OSPEED6_1
#define GPIO_OSPEEDER_OSPEEDR7 GPIO_OSPEEDR_OSPEED7
#define GPIO_OSPEEDER_OSPEEDR7_0 GPIO_OSPEEDR_OSPEED7_0
#define GPIO_OSPEEDER_OSPEEDR7_1 GPIO_OSPEEDR_OSPEED7_1
#define GPIO_OSPEEDER_OSPEEDR8 GPIO_OSPEEDR_OSPEED8
#define GPIO_OSPEEDER_OSPEEDR8_0 GPIO_OSPEEDR_OSPEED8_0
#define GPIO_OSPEEDER_OSPEEDR8_1 GPIO_OSPEEDR_OSPEED8_1
#define GPIO_OSPEEDER_OSPEEDR9 GPIO_OSPEEDR_OSPEED9
#define GPIO_OSPEEDER_OSPEEDR9_0 GPIO_OSPEEDR_OSPEED9_0
#define GPIO_OSPEEDER_OSPEEDR9_1 GPIO_OSPEEDR_OSPEED9_1
#define GPIO_OSPEEDER_OSPEEDR10 GPIO_OSPEEDR_OSPEED10
#define GPIO_OSPEEDER_OSPEEDR10_0 GPIO_OSPEEDR_OSPEED10_0
#define GPIO_OSPEEDER_OSPEEDR10_1 GPIO_OSPEEDR_OSPEED10_1
#define GPIO_OSPEEDER_OSPEEDR11 GPIO_OSPEEDR_OSPEED11
#define GPIO_OSPEEDER_OSPEEDR11_0 GPIO_OSPEEDR_OSPEED11_0
#define GPIO_OSPEEDER_OSPEEDR11_1 GPIO_OSPEEDR_OSPEED11_1
#define GPIO_OSPEEDER_OSPEEDR12 GPIO_OSPEEDR_OSPEED12
#define GPIO_OSPEEDER_OSPEEDR12_0 GPIO_OSPEEDR_OSPEED12_0
#define GPIO_OSPEEDER_OSPEEDR12_1 GPIO_OSPEEDR_OSPEED12_1
#define GPIO_OSPEEDER_OSPEEDR13 GPIO_OSPEEDR_OSPEED13
#define GPIO_OSPEEDER_OSPEEDR13_0 GPIO_OSPEEDR_OSPEED13_0
#define GPIO_OSPEEDER_OSPEEDR13_1 GPIO_OSPEEDR_OSPEED13_1
#define GPIO_OSPEEDER_OSPEEDR14 GPIO_OSPEEDR_OSPEED14
#define GPIO_OSPEEDER_OSPEEDR14_0 GPIO_OSPEEDR_OSPEED14_0
#define GPIO_OSPEEDER_OSPEEDR14_1 GPIO_OSPEEDR_OSPEED14_1
#define GPIO_OSPEEDER_OSPEEDR15 GPIO_OSPEEDR_OSPEED15
#define GPIO_OSPEEDER_OSPEEDR15_0 GPIO_OSPEEDR_OSPEED15_0
#define GPIO_OSPEEDER_OSPEEDR15_1 GPIO_OSPEEDR_OSPEED15_1
/****************** Bits definition for GPIO_PUPDR register *****************/
#define GPIO_PUPDR_PUPD0_Pos (0U)
#define GPIO_PUPDR_PUPD0_Msk (0x3UL << GPIO_PUPDR_PUPD0_Pos) /*!< 0x00000003 */
#define GPIO_PUPDR_PUPD0 GPIO_PUPDR_PUPD0_Msk
#define GPIO_PUPDR_PUPD0_0 (0x1UL << GPIO_PUPDR_PUPD0_Pos) /*!< 0x00000001 */
#define GPIO_PUPDR_PUPD0_1 (0x2UL << GPIO_PUPDR_PUPD0_Pos) /*!< 0x00000002 */
#define GPIO_PUPDR_PUPD1_Pos (2U)
#define GPIO_PUPDR_PUPD1_Msk (0x3UL << GPIO_PUPDR_PUPD1_Pos) /*!< 0x0000000C */
#define GPIO_PUPDR_PUPD1 GPIO_PUPDR_PUPD1_Msk
#define GPIO_PUPDR_PUPD1_0 (0x1UL << GPIO_PUPDR_PUPD1_Pos) /*!< 0x00000004 */
#define GPIO_PUPDR_PUPD1_1 (0x2UL << GPIO_PUPDR_PUPD1_Pos) /*!< 0x00000008 */
#define GPIO_PUPDR_PUPD2_Pos (4U)
#define GPIO_PUPDR_PUPD2_Msk (0x3UL << GPIO_PUPDR_PUPD2_Pos) /*!< 0x00000030 */
#define GPIO_PUPDR_PUPD2 GPIO_PUPDR_PUPD2_Msk
#define GPIO_PUPDR_PUPD2_0 (0x1UL << GPIO_PUPDR_PUPD2_Pos) /*!< 0x00000010 */
#define GPIO_PUPDR_PUPD2_1 (0x2UL << GPIO_PUPDR_PUPD2_Pos) /*!< 0x00000020 */
#define GPIO_PUPDR_PUPD3_Pos (6U)
#define GPIO_PUPDR_PUPD3_Msk (0x3UL << GPIO_PUPDR_PUPD3_Pos) /*!< 0x000000C0 */
#define GPIO_PUPDR_PUPD3 GPIO_PUPDR_PUPD3_Msk
#define GPIO_PUPDR_PUPD3_0 (0x1UL << GPIO_PUPDR_PUPD3_Pos) /*!< 0x00000040 */
#define GPIO_PUPDR_PUPD3_1 (0x2UL << GPIO_PUPDR_PUPD3_Pos) /*!< 0x00000080 */
#define GPIO_PUPDR_PUPD4_Pos (8U)
#define GPIO_PUPDR_PUPD4_Msk (0x3UL << GPIO_PUPDR_PUPD4_Pos) /*!< 0x00000300 */
#define GPIO_PUPDR_PUPD4 GPIO_PUPDR_PUPD4_Msk
#define GPIO_PUPDR_PUPD4_0 (0x1UL << GPIO_PUPDR_PUPD4_Pos) /*!< 0x00000100 */
#define GPIO_PUPDR_PUPD4_1 (0x2UL << GPIO_PUPDR_PUPD4_Pos) /*!< 0x00000200 */
#define GPIO_PUPDR_PUPD5_Pos (10U)
#define GPIO_PUPDR_PUPD5_Msk (0x3UL << GPIO_PUPDR_PUPD5_Pos) /*!< 0x00000C00 */
#define GPIO_PUPDR_PUPD5 GPIO_PUPDR_PUPD5_Msk
#define GPIO_PUPDR_PUPD5_0 (0x1UL << GPIO_PUPDR_PUPD5_Pos) /*!< 0x00000400 */
#define GPIO_PUPDR_PUPD5_1 (0x2UL << GPIO_PUPDR_PUPD5_Pos) /*!< 0x00000800 */
#define GPIO_PUPDR_PUPD6_Pos (12U)
#define GPIO_PUPDR_PUPD6_Msk (0x3UL << GPIO_PUPDR_PUPD6_Pos) /*!< 0x00003000 */
#define GPIO_PUPDR_PUPD6 GPIO_PUPDR_PUPD6_Msk
#define GPIO_PUPDR_PUPD6_0 (0x1UL << GPIO_PUPDR_PUPD6_Pos) /*!< 0x00001000 */
#define GPIO_PUPDR_PUPD6_1 (0x2UL << GPIO_PUPDR_PUPD6_Pos) /*!< 0x00002000 */
#define GPIO_PUPDR_PUPD7_Pos (14U)
#define GPIO_PUPDR_PUPD7_Msk (0x3UL << GPIO_PUPDR_PUPD7_Pos) /*!< 0x0000C000 */
#define GPIO_PUPDR_PUPD7 GPIO_PUPDR_PUPD7_Msk
#define GPIO_PUPDR_PUPD7_0 (0x1UL << GPIO_PUPDR_PUPD7_Pos) /*!< 0x00004000 */
#define GPIO_PUPDR_PUPD7_1 (0x2UL << GPIO_PUPDR_PUPD7_Pos) /*!< 0x00008000 */
#define GPIO_PUPDR_PUPD8_Pos (16U)
#define GPIO_PUPDR_PUPD8_Msk (0x3UL << GPIO_PUPDR_PUPD8_Pos) /*!< 0x00030000 */
#define GPIO_PUPDR_PUPD8 GPIO_PUPDR_PUPD8_Msk
#define GPIO_PUPDR_PUPD8_0 (0x1UL << GPIO_PUPDR_PUPD8_Pos) /*!< 0x00010000 */
#define GPIO_PUPDR_PUPD8_1 (0x2UL << GPIO_PUPDR_PUPD8_Pos) /*!< 0x00020000 */
#define GPIO_PUPDR_PUPD9_Pos (18U)
#define GPIO_PUPDR_PUPD9_Msk (0x3UL << GPIO_PUPDR_PUPD9_Pos) /*!< 0x000C0000 */
#define GPIO_PUPDR_PUPD9 GPIO_PUPDR_PUPD9_Msk
#define GPIO_PUPDR_PUPD9_0 (0x1UL << GPIO_PUPDR_PUPD9_Pos) /*!< 0x00040000 */
#define GPIO_PUPDR_PUPD9_1 (0x2UL << GPIO_PUPDR_PUPD9_Pos) /*!< 0x00080000 */
#define GPIO_PUPDR_PUPD10_Pos (20U)
#define GPIO_PUPDR_PUPD10_Msk (0x3UL << GPIO_PUPDR_PUPD10_Pos) /*!< 0x00300000 */
#define GPIO_PUPDR_PUPD10 GPIO_PUPDR_PUPD10_Msk
#define GPIO_PUPDR_PUPD10_0 (0x1UL << GPIO_PUPDR_PUPD10_Pos) /*!< 0x00100000 */
#define GPIO_PUPDR_PUPD10_1 (0x2UL << GPIO_PUPDR_PUPD10_Pos) /*!< 0x00200000 */
#define GPIO_PUPDR_PUPD11_Pos (22U)
#define GPIO_PUPDR_PUPD11_Msk (0x3UL << GPIO_PUPDR_PUPD11_Pos) /*!< 0x00C00000 */
#define GPIO_PUPDR_PUPD11 GPIO_PUPDR_PUPD11_Msk
#define GPIO_PUPDR_PUPD11_0 (0x1UL << GPIO_PUPDR_PUPD11_Pos) /*!< 0x00400000 */
#define GPIO_PUPDR_PUPD11_1 (0x2UL << GPIO_PUPDR_PUPD11_Pos) /*!< 0x00800000 */
#define GPIO_PUPDR_PUPD12_Pos (24U)
#define GPIO_PUPDR_PUPD12_Msk (0x3UL << GPIO_PUPDR_PUPD12_Pos) /*!< 0x03000000 */
#define GPIO_PUPDR_PUPD12 GPIO_PUPDR_PUPD12_Msk
#define GPIO_PUPDR_PUPD12_0 (0x1UL << GPIO_PUPDR_PUPD12_Pos) /*!< 0x01000000 */
#define GPIO_PUPDR_PUPD12_1 (0x2UL << GPIO_PUPDR_PUPD12_Pos) /*!< 0x02000000 */
#define GPIO_PUPDR_PUPD13_Pos (26U)
#define GPIO_PUPDR_PUPD13_Msk (0x3UL << GPIO_PUPDR_PUPD13_Pos) /*!< 0x0C000000 */
#define GPIO_PUPDR_PUPD13 GPIO_PUPDR_PUPD13_Msk
#define GPIO_PUPDR_PUPD13_0 (0x1UL << GPIO_PUPDR_PUPD13_Pos) /*!< 0x04000000 */
#define GPIO_PUPDR_PUPD13_1 (0x2UL << GPIO_PUPDR_PUPD13_Pos) /*!< 0x08000000 */
#define GPIO_PUPDR_PUPD14_Pos (28U)
#define GPIO_PUPDR_PUPD14_Msk (0x3UL << GPIO_PUPDR_PUPD14_Pos) /*!< 0x30000000 */
#define GPIO_PUPDR_PUPD14 GPIO_PUPDR_PUPD14_Msk
#define GPIO_PUPDR_PUPD14_0 (0x1UL << GPIO_PUPDR_PUPD14_Pos) /*!< 0x10000000 */
#define GPIO_PUPDR_PUPD14_1 (0x2UL << GPIO_PUPDR_PUPD14_Pos) /*!< 0x20000000 */
#define GPIO_PUPDR_PUPD15_Pos (30U)
#define GPIO_PUPDR_PUPD15_Msk (0x3UL << GPIO_PUPDR_PUPD15_Pos) /*!< 0xC0000000 */
#define GPIO_PUPDR_PUPD15 GPIO_PUPDR_PUPD15_Msk
#define GPIO_PUPDR_PUPD15_0 (0x1UL << GPIO_PUPDR_PUPD15_Pos) /*!< 0x40000000 */
#define GPIO_PUPDR_PUPD15_1 (0x2UL << GPIO_PUPDR_PUPD15_Pos) /*!< 0x80000000 */
/* Legacy defines */
#define GPIO_PUPDR_PUPDR0 GPIO_PUPDR_PUPD0
#define GPIO_PUPDR_PUPDR0_0 GPIO_PUPDR_PUPD0_0
#define GPIO_PUPDR_PUPDR0_1 GPIO_PUPDR_PUPD0_1
#define GPIO_PUPDR_PUPDR1 GPIO_PUPDR_PUPD1
#define GPIO_PUPDR_PUPDR1_0 GPIO_PUPDR_PUPD1_0
#define GPIO_PUPDR_PUPDR1_1 GPIO_PUPDR_PUPD1_1
#define GPIO_PUPDR_PUPDR2 GPIO_PUPDR_PUPD2
#define GPIO_PUPDR_PUPDR2_0 GPIO_PUPDR_PUPD2_0
#define GPIO_PUPDR_PUPDR2_1 GPIO_PUPDR_PUPD2_1
#define GPIO_PUPDR_PUPDR3 GPIO_PUPDR_PUPD3
#define GPIO_PUPDR_PUPDR3_0 GPIO_PUPDR_PUPD3_0
#define GPIO_PUPDR_PUPDR3_1 GPIO_PUPDR_PUPD3_1
#define GPIO_PUPDR_PUPDR4 GPIO_PUPDR_PUPD4
#define GPIO_PUPDR_PUPDR4_0 GPIO_PUPDR_PUPD4_0
#define GPIO_PUPDR_PUPDR4_1 GPIO_PUPDR_PUPD4_1
#define GPIO_PUPDR_PUPDR5 GPIO_PUPDR_PUPD5
#define GPIO_PUPDR_PUPDR5_0 GPIO_PUPDR_PUPD5_0
#define GPIO_PUPDR_PUPDR5_1 GPIO_PUPDR_PUPD5_1
#define GPIO_PUPDR_PUPDR6 GPIO_PUPDR_PUPD6
#define GPIO_PUPDR_PUPDR6_0 GPIO_PUPDR_PUPD6_0
#define GPIO_PUPDR_PUPDR6_1 GPIO_PUPDR_PUPD6_1
#define GPIO_PUPDR_PUPDR7 GPIO_PUPDR_PUPD7
#define GPIO_PUPDR_PUPDR7_0 GPIO_PUPDR_PUPD7_0
#define GPIO_PUPDR_PUPDR7_1 GPIO_PUPDR_PUPD7_1
#define GPIO_PUPDR_PUPDR8 GPIO_PUPDR_PUPD8
#define GPIO_PUPDR_PUPDR8_0 GPIO_PUPDR_PUPD8_0
#define GPIO_PUPDR_PUPDR8_1 GPIO_PUPDR_PUPD8_1
#define GPIO_PUPDR_PUPDR9 GPIO_PUPDR_PUPD9
#define GPIO_PUPDR_PUPDR9_0 GPIO_PUPDR_PUPD9_0
#define GPIO_PUPDR_PUPDR9_1 GPIO_PUPDR_PUPD9_1
#define GPIO_PUPDR_PUPDR10 GPIO_PUPDR_PUPD10
#define GPIO_PUPDR_PUPDR10_0 GPIO_PUPDR_PUPD10_0
#define GPIO_PUPDR_PUPDR10_1 GPIO_PUPDR_PUPD10_1
#define GPIO_PUPDR_PUPDR11 GPIO_PUPDR_PUPD11
#define GPIO_PUPDR_PUPDR11_0 GPIO_PUPDR_PUPD11_0
#define GPIO_PUPDR_PUPDR11_1 GPIO_PUPDR_PUPD11_1
#define GPIO_PUPDR_PUPDR12 GPIO_PUPDR_PUPD12
#define GPIO_PUPDR_PUPDR12_0 GPIO_PUPDR_PUPD12_0
#define GPIO_PUPDR_PUPDR12_1 GPIO_PUPDR_PUPD12_1
#define GPIO_PUPDR_PUPDR13 GPIO_PUPDR_PUPD13
#define GPIO_PUPDR_PUPDR13_0 GPIO_PUPDR_PUPD13_0
#define GPIO_PUPDR_PUPDR13_1 GPIO_PUPDR_PUPD13_1
#define GPIO_PUPDR_PUPDR14 GPIO_PUPDR_PUPD14
#define GPIO_PUPDR_PUPDR14_0 GPIO_PUPDR_PUPD14_0
#define GPIO_PUPDR_PUPDR14_1 GPIO_PUPDR_PUPD14_1
#define GPIO_PUPDR_PUPDR15 GPIO_PUPDR_PUPD15
#define GPIO_PUPDR_PUPDR15_0 GPIO_PUPDR_PUPD15_0
#define GPIO_PUPDR_PUPDR15_1 GPIO_PUPDR_PUPD15_1
/****************** Bits definition for GPIO_IDR register *******************/
#define GPIO_IDR_ID0_Pos (0U)
#define GPIO_IDR_ID0_Msk (0x1UL << GPIO_IDR_ID0_Pos) /*!< 0x00000001 */
#define GPIO_IDR_ID0 GPIO_IDR_ID0_Msk
#define GPIO_IDR_ID1_Pos (1U)
#define GPIO_IDR_ID1_Msk (0x1UL << GPIO_IDR_ID1_Pos) /*!< 0x00000002 */
#define GPIO_IDR_ID1 GPIO_IDR_ID1_Msk
#define GPIO_IDR_ID2_Pos (2U)
#define GPIO_IDR_ID2_Msk (0x1UL << GPIO_IDR_ID2_Pos) /*!< 0x00000004 */
#define GPIO_IDR_ID2 GPIO_IDR_ID2_Msk
#define GPIO_IDR_ID3_Pos (3U)
#define GPIO_IDR_ID3_Msk (0x1UL << GPIO_IDR_ID3_Pos) /*!< 0x00000008 */
#define GPIO_IDR_ID3 GPIO_IDR_ID3_Msk
#define GPIO_IDR_ID4_Pos (4U)
#define GPIO_IDR_ID4_Msk (0x1UL << GPIO_IDR_ID4_Pos) /*!< 0x00000010 */
#define GPIO_IDR_ID4 GPIO_IDR_ID4_Msk
#define GPIO_IDR_ID5_Pos (5U)
#define GPIO_IDR_ID5_Msk (0x1UL << GPIO_IDR_ID5_Pos) /*!< 0x00000020 */
#define GPIO_IDR_ID5 GPIO_IDR_ID5_Msk
#define GPIO_IDR_ID6_Pos (6U)
#define GPIO_IDR_ID6_Msk (0x1UL << GPIO_IDR_ID6_Pos) /*!< 0x00000040 */
#define GPIO_IDR_ID6 GPIO_IDR_ID6_Msk
#define GPIO_IDR_ID7_Pos (7U)
#define GPIO_IDR_ID7_Msk (0x1UL << GPIO_IDR_ID7_Pos) /*!< 0x00000080 */
#define GPIO_IDR_ID7 GPIO_IDR_ID7_Msk
#define GPIO_IDR_ID8_Pos (8U)
#define GPIO_IDR_ID8_Msk (0x1UL << GPIO_IDR_ID8_Pos) /*!< 0x00000100 */
#define GPIO_IDR_ID8 GPIO_IDR_ID8_Msk
#define GPIO_IDR_ID9_Pos (9U)
#define GPIO_IDR_ID9_Msk (0x1UL << GPIO_IDR_ID9_Pos) /*!< 0x00000200 */
#define GPIO_IDR_ID9 GPIO_IDR_ID9_Msk
#define GPIO_IDR_ID10_Pos (10U)
#define GPIO_IDR_ID10_Msk (0x1UL << GPIO_IDR_ID10_Pos) /*!< 0x00000400 */
#define GPIO_IDR_ID10 GPIO_IDR_ID10_Msk
#define GPIO_IDR_ID11_Pos (11U)
#define GPIO_IDR_ID11_Msk (0x1UL << GPIO_IDR_ID11_Pos) /*!< 0x00000800 */
#define GPIO_IDR_ID11 GPIO_IDR_ID11_Msk
#define GPIO_IDR_ID12_Pos (12U)
#define GPIO_IDR_ID12_Msk (0x1UL << GPIO_IDR_ID12_Pos) /*!< 0x00001000 */
#define GPIO_IDR_ID12 GPIO_IDR_ID12_Msk
#define GPIO_IDR_ID13_Pos (13U)
#define GPIO_IDR_ID13_Msk (0x1UL << GPIO_IDR_ID13_Pos) /*!< 0x00002000 */
#define GPIO_IDR_ID13 GPIO_IDR_ID13_Msk
#define GPIO_IDR_ID14_Pos (14U)
#define GPIO_IDR_ID14_Msk (0x1UL << GPIO_IDR_ID14_Pos) /*!< 0x00004000 */
#define GPIO_IDR_ID14 GPIO_IDR_ID14_Msk
#define GPIO_IDR_ID15_Pos (15U)
#define GPIO_IDR_ID15_Msk (0x1UL << GPIO_IDR_ID15_Pos) /*!< 0x00008000 */
#define GPIO_IDR_ID15 GPIO_IDR_ID15_Msk
/* Legacy defines */
#define GPIO_IDR_IDR_0 GPIO_IDR_ID0
#define GPIO_IDR_IDR_1 GPIO_IDR_ID1
#define GPIO_IDR_IDR_2 GPIO_IDR_ID2
#define GPIO_IDR_IDR_3 GPIO_IDR_ID3
#define GPIO_IDR_IDR_4 GPIO_IDR_ID4
#define GPIO_IDR_IDR_5 GPIO_IDR_ID5
#define GPIO_IDR_IDR_6 GPIO_IDR_ID6
#define GPIO_IDR_IDR_7 GPIO_IDR_ID7
#define GPIO_IDR_IDR_8 GPIO_IDR_ID8
#define GPIO_IDR_IDR_9 GPIO_IDR_ID9
#define GPIO_IDR_IDR_10 GPIO_IDR_ID10
#define GPIO_IDR_IDR_11 GPIO_IDR_ID11
#define GPIO_IDR_IDR_12 GPIO_IDR_ID12
#define GPIO_IDR_IDR_13 GPIO_IDR_ID13
#define GPIO_IDR_IDR_14 GPIO_IDR_ID14
#define GPIO_IDR_IDR_15 GPIO_IDR_ID15
/* Old GPIO_IDR register bits definition, maintained for legacy purpose */
#define GPIO_OTYPER_IDR_0 GPIO_IDR_ID0
#define GPIO_OTYPER_IDR_1 GPIO_IDR_ID1
#define GPIO_OTYPER_IDR_2 GPIO_IDR_ID2
#define GPIO_OTYPER_IDR_3 GPIO_IDR_ID3
#define GPIO_OTYPER_IDR_4 GPIO_IDR_ID4
#define GPIO_OTYPER_IDR_5 GPIO_IDR_ID5
#define GPIO_OTYPER_IDR_6 GPIO_IDR_ID6
#define GPIO_OTYPER_IDR_7 GPIO_IDR_ID7
#define GPIO_OTYPER_IDR_8 GPIO_IDR_ID8
#define GPIO_OTYPER_IDR_9 GPIO_IDR_ID9
#define GPIO_OTYPER_IDR_10 GPIO_IDR_ID10
#define GPIO_OTYPER_IDR_11 GPIO_IDR_ID11
#define GPIO_OTYPER_IDR_12 GPIO_IDR_ID12
#define GPIO_OTYPER_IDR_13 GPIO_IDR_ID13
#define GPIO_OTYPER_IDR_14 GPIO_IDR_ID14
#define GPIO_OTYPER_IDR_15 GPIO_IDR_ID15
/****************** Bits definition for GPIO_ODR register *******************/
#define GPIO_ODR_OD0_Pos (0U)
#define GPIO_ODR_OD0_Msk (0x1UL << GPIO_ODR_OD0_Pos) /*!< 0x00000001 */
#define GPIO_ODR_OD0 GPIO_ODR_OD0_Msk
#define GPIO_ODR_OD1_Pos (1U)
#define GPIO_ODR_OD1_Msk (0x1UL << GPIO_ODR_OD1_Pos) /*!< 0x00000002 */
#define GPIO_ODR_OD1 GPIO_ODR_OD1_Msk
#define GPIO_ODR_OD2_Pos (2U)
#define GPIO_ODR_OD2_Msk (0x1UL << GPIO_ODR_OD2_Pos) /*!< 0x00000004 */
#define GPIO_ODR_OD2 GPIO_ODR_OD2_Msk
#define GPIO_ODR_OD3_Pos (3U)
#define GPIO_ODR_OD3_Msk (0x1UL << GPIO_ODR_OD3_Pos) /*!< 0x00000008 */
#define GPIO_ODR_OD3 GPIO_ODR_OD3_Msk
#define GPIO_ODR_OD4_Pos (4U)
#define GPIO_ODR_OD4_Msk (0x1UL << GPIO_ODR_OD4_Pos) /*!< 0x00000010 */
#define GPIO_ODR_OD4 GPIO_ODR_OD4_Msk
#define GPIO_ODR_OD5_Pos (5U)
#define GPIO_ODR_OD5_Msk (0x1UL << GPIO_ODR_OD5_Pos) /*!< 0x00000020 */
#define GPIO_ODR_OD5 GPIO_ODR_OD5_Msk
#define GPIO_ODR_OD6_Pos (6U)
#define GPIO_ODR_OD6_Msk (0x1UL << GPIO_ODR_OD6_Pos) /*!< 0x00000040 */
#define GPIO_ODR_OD6 GPIO_ODR_OD6_Msk
#define GPIO_ODR_OD7_Pos (7U)
#define GPIO_ODR_OD7_Msk (0x1UL << GPIO_ODR_OD7_Pos) /*!< 0x00000080 */
#define GPIO_ODR_OD7 GPIO_ODR_OD7_Msk
#define GPIO_ODR_OD8_Pos (8U)
#define GPIO_ODR_OD8_Msk (0x1UL << GPIO_ODR_OD8_Pos) /*!< 0x00000100 */
#define GPIO_ODR_OD8 GPIO_ODR_OD8_Msk
#define GPIO_ODR_OD9_Pos (9U)
#define GPIO_ODR_OD9_Msk (0x1UL << GPIO_ODR_OD9_Pos) /*!< 0x00000200 */
#define GPIO_ODR_OD9 GPIO_ODR_OD9_Msk
#define GPIO_ODR_OD10_Pos (10U)
#define GPIO_ODR_OD10_Msk (0x1UL << GPIO_ODR_OD10_Pos) /*!< 0x00000400 */
#define GPIO_ODR_OD10 GPIO_ODR_OD10_Msk
#define GPIO_ODR_OD11_Pos (11U)
#define GPIO_ODR_OD11_Msk (0x1UL << GPIO_ODR_OD11_Pos) /*!< 0x00000800 */
#define GPIO_ODR_OD11 GPIO_ODR_OD11_Msk
#define GPIO_ODR_OD12_Pos (12U)
#define GPIO_ODR_OD12_Msk (0x1UL << GPIO_ODR_OD12_Pos) /*!< 0x00001000 */
#define GPIO_ODR_OD12 GPIO_ODR_OD12_Msk
#define GPIO_ODR_OD13_Pos (13U)
#define GPIO_ODR_OD13_Msk (0x1UL << GPIO_ODR_OD13_Pos) /*!< 0x00002000 */
#define GPIO_ODR_OD13 GPIO_ODR_OD13_Msk
#define GPIO_ODR_OD14_Pos (14U)
#define GPIO_ODR_OD14_Msk (0x1UL << GPIO_ODR_OD14_Pos) /*!< 0x00004000 */
#define GPIO_ODR_OD14 GPIO_ODR_OD14_Msk
#define GPIO_ODR_OD15_Pos (15U)
#define GPIO_ODR_OD15_Msk (0x1UL << GPIO_ODR_OD15_Pos) /*!< 0x00008000 */
#define GPIO_ODR_OD15 GPIO_ODR_OD15_Msk
/* Legacy defines */
#define GPIO_ODR_ODR_0 GPIO_ODR_OD0
#define GPIO_ODR_ODR_1 GPIO_ODR_OD1
#define GPIO_ODR_ODR_2 GPIO_ODR_OD2
#define GPIO_ODR_ODR_3 GPIO_ODR_OD3
#define GPIO_ODR_ODR_4 GPIO_ODR_OD4
#define GPIO_ODR_ODR_5 GPIO_ODR_OD5
#define GPIO_ODR_ODR_6 GPIO_ODR_OD6
#define GPIO_ODR_ODR_7 GPIO_ODR_OD7
#define GPIO_ODR_ODR_8 GPIO_ODR_OD8
#define GPIO_ODR_ODR_9 GPIO_ODR_OD9
#define GPIO_ODR_ODR_10 GPIO_ODR_OD10
#define GPIO_ODR_ODR_11 GPIO_ODR_OD11
#define GPIO_ODR_ODR_12 GPIO_ODR_OD12
#define GPIO_ODR_ODR_13 GPIO_ODR_OD13
#define GPIO_ODR_ODR_14 GPIO_ODR_OD14
#define GPIO_ODR_ODR_15 GPIO_ODR_OD15
/* Old GPIO_ODR register bits definition, maintained for legacy purpose */
#define GPIO_OTYPER_ODR_0 GPIO_ODR_OD0
#define GPIO_OTYPER_ODR_1 GPIO_ODR_OD1
#define GPIO_OTYPER_ODR_2 GPIO_ODR_OD2
#define GPIO_OTYPER_ODR_3 GPIO_ODR_OD3
#define GPIO_OTYPER_ODR_4 GPIO_ODR_OD4
#define GPIO_OTYPER_ODR_5 GPIO_ODR_OD5
#define GPIO_OTYPER_ODR_6 GPIO_ODR_OD6
#define GPIO_OTYPER_ODR_7 GPIO_ODR_OD7
#define GPIO_OTYPER_ODR_8 GPIO_ODR_OD8
#define GPIO_OTYPER_ODR_9 GPIO_ODR_OD9
#define GPIO_OTYPER_ODR_10 GPIO_ODR_OD10
#define GPIO_OTYPER_ODR_11 GPIO_ODR_OD11
#define GPIO_OTYPER_ODR_12 GPIO_ODR_OD12
#define GPIO_OTYPER_ODR_13 GPIO_ODR_OD13
#define GPIO_OTYPER_ODR_14 GPIO_ODR_OD14
#define GPIO_OTYPER_ODR_15 GPIO_ODR_OD15
/****************** Bits definition for GPIO_BSRR register ******************/
#define GPIO_BSRR_BS0_Pos (0U)
#define GPIO_BSRR_BS0_Msk (0x1UL << GPIO_BSRR_BS0_Pos) /*!< 0x00000001 */
#define GPIO_BSRR_BS0 GPIO_BSRR_BS0_Msk
#define GPIO_BSRR_BS1_Pos (1U)
#define GPIO_BSRR_BS1_Msk (0x1UL << GPIO_BSRR_BS1_Pos) /*!< 0x00000002 */
#define GPIO_BSRR_BS1 GPIO_BSRR_BS1_Msk
#define GPIO_BSRR_BS2_Pos (2U)
#define GPIO_BSRR_BS2_Msk (0x1UL << GPIO_BSRR_BS2_Pos) /*!< 0x00000004 */
#define GPIO_BSRR_BS2 GPIO_BSRR_BS2_Msk
#define GPIO_BSRR_BS3_Pos (3U)
#define GPIO_BSRR_BS3_Msk (0x1UL << GPIO_BSRR_BS3_Pos) /*!< 0x00000008 */
#define GPIO_BSRR_BS3 GPIO_BSRR_BS3_Msk
#define GPIO_BSRR_BS4_Pos (4U)
#define GPIO_BSRR_BS4_Msk (0x1UL << GPIO_BSRR_BS4_Pos) /*!< 0x00000010 */
#define GPIO_BSRR_BS4 GPIO_BSRR_BS4_Msk
#define GPIO_BSRR_BS5_Pos (5U)
#define GPIO_BSRR_BS5_Msk (0x1UL << GPIO_BSRR_BS5_Pos) /*!< 0x00000020 */
#define GPIO_BSRR_BS5 GPIO_BSRR_BS5_Msk
#define GPIO_BSRR_BS6_Pos (6U)
#define GPIO_BSRR_BS6_Msk (0x1UL << GPIO_BSRR_BS6_Pos) /*!< 0x00000040 */
#define GPIO_BSRR_BS6 GPIO_BSRR_BS6_Msk
#define GPIO_BSRR_BS7_Pos (7U)
#define GPIO_BSRR_BS7_Msk (0x1UL << GPIO_BSRR_BS7_Pos) /*!< 0x00000080 */
#define GPIO_BSRR_BS7 GPIO_BSRR_BS7_Msk
#define GPIO_BSRR_BS8_Pos (8U)
#define GPIO_BSRR_BS8_Msk (0x1UL << GPIO_BSRR_BS8_Pos) /*!< 0x00000100 */
#define GPIO_BSRR_BS8 GPIO_BSRR_BS8_Msk
#define GPIO_BSRR_BS9_Pos (9U)
#define GPIO_BSRR_BS9_Msk (0x1UL << GPIO_BSRR_BS9_Pos) /*!< 0x00000200 */
#define GPIO_BSRR_BS9 GPIO_BSRR_BS9_Msk
#define GPIO_BSRR_BS10_Pos (10U)
#define GPIO_BSRR_BS10_Msk (0x1UL << GPIO_BSRR_BS10_Pos) /*!< 0x00000400 */
#define GPIO_BSRR_BS10 GPIO_BSRR_BS10_Msk
#define GPIO_BSRR_BS11_Pos (11U)
#define GPIO_BSRR_BS11_Msk (0x1UL << GPIO_BSRR_BS11_Pos) /*!< 0x00000800 */
#define GPIO_BSRR_BS11 GPIO_BSRR_BS11_Msk
#define GPIO_BSRR_BS12_Pos (12U)
#define GPIO_BSRR_BS12_Msk (0x1UL << GPIO_BSRR_BS12_Pos) /*!< 0x00001000 */
#define GPIO_BSRR_BS12 GPIO_BSRR_BS12_Msk
#define GPIO_BSRR_BS13_Pos (13U)
#define GPIO_BSRR_BS13_Msk (0x1UL << GPIO_BSRR_BS13_Pos) /*!< 0x00002000 */
#define GPIO_BSRR_BS13 GPIO_BSRR_BS13_Msk
#define GPIO_BSRR_BS14_Pos (14U)
#define GPIO_BSRR_BS14_Msk (0x1UL << GPIO_BSRR_BS14_Pos) /*!< 0x00004000 */
#define GPIO_BSRR_BS14 GPIO_BSRR_BS14_Msk
#define GPIO_BSRR_BS15_Pos (15U)
#define GPIO_BSRR_BS15_Msk (0x1UL << GPIO_BSRR_BS15_Pos) /*!< 0x00008000 */
#define GPIO_BSRR_BS15 GPIO_BSRR_BS15_Msk
#define GPIO_BSRR_BR0_Pos (16U)
#define GPIO_BSRR_BR0_Msk (0x1UL << GPIO_BSRR_BR0_Pos) /*!< 0x00010000 */
#define GPIO_BSRR_BR0 GPIO_BSRR_BR0_Msk
#define GPIO_BSRR_BR1_Pos (17U)
#define GPIO_BSRR_BR1_Msk (0x1UL << GPIO_BSRR_BR1_Pos) /*!< 0x00020000 */
#define GPIO_BSRR_BR1 GPIO_BSRR_BR1_Msk
#define GPIO_BSRR_BR2_Pos (18U)
#define GPIO_BSRR_BR2_Msk (0x1UL << GPIO_BSRR_BR2_Pos) /*!< 0x00040000 */
#define GPIO_BSRR_BR2 GPIO_BSRR_BR2_Msk
#define GPIO_BSRR_BR3_Pos (19U)
#define GPIO_BSRR_BR3_Msk (0x1UL << GPIO_BSRR_BR3_Pos) /*!< 0x00080000 */
#define GPIO_BSRR_BR3 GPIO_BSRR_BR3_Msk
#define GPIO_BSRR_BR4_Pos (20U)
#define GPIO_BSRR_BR4_Msk (0x1UL << GPIO_BSRR_BR4_Pos) /*!< 0x00100000 */
#define GPIO_BSRR_BR4 GPIO_BSRR_BR4_Msk
#define GPIO_BSRR_BR5_Pos (21U)
#define GPIO_BSRR_BR5_Msk (0x1UL << GPIO_BSRR_BR5_Pos) /*!< 0x00200000 */
#define GPIO_BSRR_BR5 GPIO_BSRR_BR5_Msk
#define GPIO_BSRR_BR6_Pos (22U)
#define GPIO_BSRR_BR6_Msk (0x1UL << GPIO_BSRR_BR6_Pos) /*!< 0x00400000 */
#define GPIO_BSRR_BR6 GPIO_BSRR_BR6_Msk
#define GPIO_BSRR_BR7_Pos (23U)
#define GPIO_BSRR_BR7_Msk (0x1UL << GPIO_BSRR_BR7_Pos) /*!< 0x00800000 */
#define GPIO_BSRR_BR7 GPIO_BSRR_BR7_Msk
#define GPIO_BSRR_BR8_Pos (24U)
#define GPIO_BSRR_BR8_Msk (0x1UL << GPIO_BSRR_BR8_Pos) /*!< 0x01000000 */
#define GPIO_BSRR_BR8 GPIO_BSRR_BR8_Msk
#define GPIO_BSRR_BR9_Pos (25U)
#define GPIO_BSRR_BR9_Msk (0x1UL << GPIO_BSRR_BR9_Pos) /*!< 0x02000000 */
#define GPIO_BSRR_BR9 GPIO_BSRR_BR9_Msk
#define GPIO_BSRR_BR10_Pos (26U)
#define GPIO_BSRR_BR10_Msk (0x1UL << GPIO_BSRR_BR10_Pos) /*!< 0x04000000 */
#define GPIO_BSRR_BR10 GPIO_BSRR_BR10_Msk
#define GPIO_BSRR_BR11_Pos (27U)
#define GPIO_BSRR_BR11_Msk (0x1UL << GPIO_BSRR_BR11_Pos) /*!< 0x08000000 */
#define GPIO_BSRR_BR11 GPIO_BSRR_BR11_Msk
#define GPIO_BSRR_BR12_Pos (28U)
#define GPIO_BSRR_BR12_Msk (0x1UL << GPIO_BSRR_BR12_Pos) /*!< 0x10000000 */
#define GPIO_BSRR_BR12 GPIO_BSRR_BR12_Msk
#define GPIO_BSRR_BR13_Pos (29U)
#define GPIO_BSRR_BR13_Msk (0x1UL << GPIO_BSRR_BR13_Pos) /*!< 0x20000000 */
#define GPIO_BSRR_BR13 GPIO_BSRR_BR13_Msk
#define GPIO_BSRR_BR14_Pos (30U)
#define GPIO_BSRR_BR14_Msk (0x1UL << GPIO_BSRR_BR14_Pos) /*!< 0x40000000 */
#define GPIO_BSRR_BR14 GPIO_BSRR_BR14_Msk
#define GPIO_BSRR_BR15_Pos (31U)
#define GPIO_BSRR_BR15_Msk (0x1UL << GPIO_BSRR_BR15_Pos) /*!< 0x80000000 */
#define GPIO_BSRR_BR15 GPIO_BSRR_BR15_Msk
/* Legacy defines */
#define GPIO_BSRR_BS_0 GPIO_BSRR_BS0
#define GPIO_BSRR_BS_1 GPIO_BSRR_BS1
#define GPIO_BSRR_BS_2 GPIO_BSRR_BS2
#define GPIO_BSRR_BS_3 GPIO_BSRR_BS3
#define GPIO_BSRR_BS_4 GPIO_BSRR_BS4
#define GPIO_BSRR_BS_5 GPIO_BSRR_BS5
#define GPIO_BSRR_BS_6 GPIO_BSRR_BS6
#define GPIO_BSRR_BS_7 GPIO_BSRR_BS7
#define GPIO_BSRR_BS_8 GPIO_BSRR_BS8
#define GPIO_BSRR_BS_9 GPIO_BSRR_BS9
#define GPIO_BSRR_BS_10 GPIO_BSRR_BS10
#define GPIO_BSRR_BS_11 GPIO_BSRR_BS11
#define GPIO_BSRR_BS_12 GPIO_BSRR_BS12
#define GPIO_BSRR_BS_13 GPIO_BSRR_BS13
#define GPIO_BSRR_BS_14 GPIO_BSRR_BS14
#define GPIO_BSRR_BS_15 GPIO_BSRR_BS15
#define GPIO_BSRR_BR_0 GPIO_BSRR_BR0
#define GPIO_BSRR_BR_1 GPIO_BSRR_BR1
#define GPIO_BSRR_BR_2 GPIO_BSRR_BR2
#define GPIO_BSRR_BR_3 GPIO_BSRR_BR3
#define GPIO_BSRR_BR_4 GPIO_BSRR_BR4
#define GPIO_BSRR_BR_5 GPIO_BSRR_BR5
#define GPIO_BSRR_BR_6 GPIO_BSRR_BR6
#define GPIO_BSRR_BR_7 GPIO_BSRR_BR7
#define GPIO_BSRR_BR_8 GPIO_BSRR_BR8
#define GPIO_BSRR_BR_9 GPIO_BSRR_BR9
#define GPIO_BSRR_BR_10 GPIO_BSRR_BR10
#define GPIO_BSRR_BR_11 GPIO_BSRR_BR11
#define GPIO_BSRR_BR_12 GPIO_BSRR_BR12
#define GPIO_BSRR_BR_13 GPIO_BSRR_BR13
#define GPIO_BSRR_BR_14 GPIO_BSRR_BR14
#define GPIO_BSRR_BR_15 GPIO_BSRR_BR15
/****************** Bit definition for GPIO_LCKR register *********************/
#define GPIO_LCKR_LCK0_Pos (0U)
#define GPIO_LCKR_LCK0_Msk (0x1UL << GPIO_LCKR_LCK0_Pos) /*!< 0x00000001 */
#define GPIO_LCKR_LCK0 GPIO_LCKR_LCK0_Msk
#define GPIO_LCKR_LCK1_Pos (1U)
#define GPIO_LCKR_LCK1_Msk (0x1UL << GPIO_LCKR_LCK1_Pos) /*!< 0x00000002 */
#define GPIO_LCKR_LCK1 GPIO_LCKR_LCK1_Msk
#define GPIO_LCKR_LCK2_Pos (2U)
#define GPIO_LCKR_LCK2_Msk (0x1UL << GPIO_LCKR_LCK2_Pos) /*!< 0x00000004 */
#define GPIO_LCKR_LCK2 GPIO_LCKR_LCK2_Msk
#define GPIO_LCKR_LCK3_Pos (3U)
#define GPIO_LCKR_LCK3_Msk (0x1UL << GPIO_LCKR_LCK3_Pos) /*!< 0x00000008 */
#define GPIO_LCKR_LCK3 GPIO_LCKR_LCK3_Msk
#define GPIO_LCKR_LCK4_Pos (4U)
#define GPIO_LCKR_LCK4_Msk (0x1UL << GPIO_LCKR_LCK4_Pos) /*!< 0x00000010 */
#define GPIO_LCKR_LCK4 GPIO_LCKR_LCK4_Msk
#define GPIO_LCKR_LCK5_Pos (5U)
#define GPIO_LCKR_LCK5_Msk (0x1UL << GPIO_LCKR_LCK5_Pos) /*!< 0x00000020 */
#define GPIO_LCKR_LCK5 GPIO_LCKR_LCK5_Msk
#define GPIO_LCKR_LCK6_Pos (6U)
#define GPIO_LCKR_LCK6_Msk (0x1UL << GPIO_LCKR_LCK6_Pos) /*!< 0x00000040 */
#define GPIO_LCKR_LCK6 GPIO_LCKR_LCK6_Msk
#define GPIO_LCKR_LCK7_Pos (7U)
#define GPIO_LCKR_LCK7_Msk (0x1UL << GPIO_LCKR_LCK7_Pos) /*!< 0x00000080 */
#define GPIO_LCKR_LCK7 GPIO_LCKR_LCK7_Msk
#define GPIO_LCKR_LCK8_Pos (8U)
#define GPIO_LCKR_LCK8_Msk (0x1UL << GPIO_LCKR_LCK8_Pos) /*!< 0x00000100 */
#define GPIO_LCKR_LCK8 GPIO_LCKR_LCK8_Msk
#define GPIO_LCKR_LCK9_Pos (9U)
#define GPIO_LCKR_LCK9_Msk (0x1UL << GPIO_LCKR_LCK9_Pos) /*!< 0x00000200 */
#define GPIO_LCKR_LCK9 GPIO_LCKR_LCK9_Msk
#define GPIO_LCKR_LCK10_Pos (10U)
#define GPIO_LCKR_LCK10_Msk (0x1UL << GPIO_LCKR_LCK10_Pos) /*!< 0x00000400 */
#define GPIO_LCKR_LCK10 GPIO_LCKR_LCK10_Msk
#define GPIO_LCKR_LCK11_Pos (11U)
#define GPIO_LCKR_LCK11_Msk (0x1UL << GPIO_LCKR_LCK11_Pos) /*!< 0x00000800 */
#define GPIO_LCKR_LCK11 GPIO_LCKR_LCK11_Msk
#define GPIO_LCKR_LCK12_Pos (12U)
#define GPIO_LCKR_LCK12_Msk (0x1UL << GPIO_LCKR_LCK12_Pos) /*!< 0x00001000 */
#define GPIO_LCKR_LCK12 GPIO_LCKR_LCK12_Msk
#define GPIO_LCKR_LCK13_Pos (13U)
#define GPIO_LCKR_LCK13_Msk (0x1UL << GPIO_LCKR_LCK13_Pos) /*!< 0x00002000 */
#define GPIO_LCKR_LCK13 GPIO_LCKR_LCK13_Msk
#define GPIO_LCKR_LCK14_Pos (14U)
#define GPIO_LCKR_LCK14_Msk (0x1UL << GPIO_LCKR_LCK14_Pos) /*!< 0x00004000 */
#define GPIO_LCKR_LCK14 GPIO_LCKR_LCK14_Msk
#define GPIO_LCKR_LCK15_Pos (15U)
#define GPIO_LCKR_LCK15_Msk (0x1UL << GPIO_LCKR_LCK15_Pos) /*!< 0x00008000 */
#define GPIO_LCKR_LCK15 GPIO_LCKR_LCK15_Msk
#define GPIO_LCKR_LCKK_Pos (16U)
#define GPIO_LCKR_LCKK_Msk (0x1UL << GPIO_LCKR_LCKK_Pos) /*!< 0x00010000 */
#define GPIO_LCKR_LCKK GPIO_LCKR_LCKK_Msk
/****************** Bit definition for GPIO_AFRL register *********************/
#define GPIO_AFRL_AFSEL0_Pos (0U)
#define GPIO_AFRL_AFSEL0_Msk (0xFUL << GPIO_AFRL_AFSEL0_Pos) /*!< 0x0000000F */
#define GPIO_AFRL_AFSEL0 GPIO_AFRL_AFSEL0_Msk
#define GPIO_AFRL_AFSEL0_0 (0x1UL << GPIO_AFRL_AFSEL0_Pos) /*!< 0x00000001 */
#define GPIO_AFRL_AFSEL0_1 (0x2UL << GPIO_AFRL_AFSEL0_Pos) /*!< 0x00000002 */
#define GPIO_AFRL_AFSEL0_2 (0x4UL << GPIO_AFRL_AFSEL0_Pos) /*!< 0x00000004 */
#define GPIO_AFRL_AFSEL0_3 (0x8UL << GPIO_AFRL_AFSEL0_Pos) /*!< 0x00000008 */
#define GPIO_AFRL_AFSEL1_Pos (4U)
#define GPIO_AFRL_AFSEL1_Msk (0xFUL << GPIO_AFRL_AFSEL1_Pos) /*!< 0x000000F0 */
#define GPIO_AFRL_AFSEL1 GPIO_AFRL_AFSEL1_Msk
#define GPIO_AFRL_AFSEL1_0 (0x1UL << GPIO_AFRL_AFSEL1_Pos) /*!< 0x00000010 */
#define GPIO_AFRL_AFSEL1_1 (0x2UL << GPIO_AFRL_AFSEL1_Pos) /*!< 0x00000020 */
#define GPIO_AFRL_AFSEL1_2 (0x4UL << GPIO_AFRL_AFSEL1_Pos) /*!< 0x00000040 */
#define GPIO_AFRL_AFSEL1_3 (0x8UL << GPIO_AFRL_AFSEL1_Pos) /*!< 0x00000080 */
#define GPIO_AFRL_AFSEL2_Pos (8U)
#define GPIO_AFRL_AFSEL2_Msk (0xFUL << GPIO_AFRL_AFSEL2_Pos) /*!< 0x00000F00 */
#define GPIO_AFRL_AFSEL2 GPIO_AFRL_AFSEL2_Msk
#define GPIO_AFRL_AFSEL2_0 (0x1UL << GPIO_AFRL_AFSEL2_Pos) /*!< 0x00000100 */
#define GPIO_AFRL_AFSEL2_1 (0x2UL << GPIO_AFRL_AFSEL2_Pos) /*!< 0x00000200 */
#define GPIO_AFRL_AFSEL2_2 (0x4UL << GPIO_AFRL_AFSEL2_Pos) /*!< 0x00000400 */
#define GPIO_AFRL_AFSEL2_3 (0x8UL << GPIO_AFRL_AFSEL2_Pos) /*!< 0x00000800 */
#define GPIO_AFRL_AFSEL3_Pos (12U)
#define GPIO_AFRL_AFSEL3_Msk (0xFUL << GPIO_AFRL_AFSEL3_Pos) /*!< 0x0000F000 */
#define GPIO_AFRL_AFSEL3 GPIO_AFRL_AFSEL3_Msk
#define GPIO_AFRL_AFSEL3_0 (0x1UL << GPIO_AFRL_AFSEL3_Pos) /*!< 0x00001000 */
#define GPIO_AFRL_AFSEL3_1 (0x2UL << GPIO_AFRL_AFSEL3_Pos) /*!< 0x00002000 */
#define GPIO_AFRL_AFSEL3_2 (0x4UL << GPIO_AFRL_AFSEL3_Pos) /*!< 0x00004000 */
#define GPIO_AFRL_AFSEL3_3 (0x8UL << GPIO_AFRL_AFSEL3_Pos) /*!< 0x00008000 */
#define GPIO_AFRL_AFSEL4_Pos (16U)
#define GPIO_AFRL_AFSEL4_Msk (0xFUL << GPIO_AFRL_AFSEL4_Pos) /*!< 0x000F0000 */
#define GPIO_AFRL_AFSEL4 GPIO_AFRL_AFSEL4_Msk
#define GPIO_AFRL_AFSEL4_0 (0x1UL << GPIO_AFRL_AFSEL4_Pos) /*!< 0x00010000 */
#define GPIO_AFRL_AFSEL4_1 (0x2UL << GPIO_AFRL_AFSEL4_Pos) /*!< 0x00020000 */
#define GPIO_AFRL_AFSEL4_2 (0x4UL << GPIO_AFRL_AFSEL4_Pos) /*!< 0x00040000 */
#define GPIO_AFRL_AFSEL4_3 (0x8UL << GPIO_AFRL_AFSEL4_Pos) /*!< 0x00080000 */
#define GPIO_AFRL_AFSEL5_Pos (20U)
#define GPIO_AFRL_AFSEL5_Msk (0xFUL << GPIO_AFRL_AFSEL5_Pos) /*!< 0x00F00000 */
#define GPIO_AFRL_AFSEL5 GPIO_AFRL_AFSEL5_Msk
#define GPIO_AFRL_AFSEL5_0 (0x1UL << GPIO_AFRL_AFSEL5_Pos) /*!< 0x00100000 */
#define GPIO_AFRL_AFSEL5_1 (0x2UL << GPIO_AFRL_AFSEL5_Pos) /*!< 0x00200000 */
#define GPIO_AFRL_AFSEL5_2 (0x4UL << GPIO_AFRL_AFSEL5_Pos) /*!< 0x00400000 */
#define GPIO_AFRL_AFSEL5_3 (0x8UL << GPIO_AFRL_AFSEL5_Pos) /*!< 0x00800000 */
#define GPIO_AFRL_AFSEL6_Pos (24U)
#define GPIO_AFRL_AFSEL6_Msk (0xFUL << GPIO_AFRL_AFSEL6_Pos) /*!< 0x0F000000 */
#define GPIO_AFRL_AFSEL6 GPIO_AFRL_AFSEL6_Msk
#define GPIO_AFRL_AFSEL6_0 (0x1UL << GPIO_AFRL_AFSEL6_Pos) /*!< 0x01000000 */
#define GPIO_AFRL_AFSEL6_1 (0x2UL << GPIO_AFRL_AFSEL6_Pos) /*!< 0x02000000 */
#define GPIO_AFRL_AFSEL6_2 (0x4UL << GPIO_AFRL_AFSEL6_Pos) /*!< 0x04000000 */
#define GPIO_AFRL_AFSEL6_3 (0x8UL << GPIO_AFRL_AFSEL6_Pos) /*!< 0x08000000 */
#define GPIO_AFRL_AFSEL7_Pos (28U)
#define GPIO_AFRL_AFSEL7_Msk (0xFUL << GPIO_AFRL_AFSEL7_Pos) /*!< 0xF0000000 */
#define GPIO_AFRL_AFSEL7 GPIO_AFRL_AFSEL7_Msk
#define GPIO_AFRL_AFSEL7_0 (0x1UL << GPIO_AFRL_AFSEL7_Pos) /*!< 0x10000000 */
#define GPIO_AFRL_AFSEL7_1 (0x2UL << GPIO_AFRL_AFSEL7_Pos) /*!< 0x20000000 */
#define GPIO_AFRL_AFSEL7_2 (0x4UL << GPIO_AFRL_AFSEL7_Pos) /*!< 0x40000000 */
#define GPIO_AFRL_AFSEL7_3 (0x8UL << GPIO_AFRL_AFSEL7_Pos) /*!< 0x80000000 */
/* Legacy defines */
#define GPIO_AFRL_AFRL0 GPIO_AFRL_AFSEL0
#define GPIO_AFRL_AFRL1 GPIO_AFRL_AFSEL1
#define GPIO_AFRL_AFRL2 GPIO_AFRL_AFSEL2
#define GPIO_AFRL_AFRL3 GPIO_AFRL_AFSEL3
#define GPIO_AFRL_AFRL4 GPIO_AFRL_AFSEL4
#define GPIO_AFRL_AFRL5 GPIO_AFRL_AFSEL5
#define GPIO_AFRL_AFRL6 GPIO_AFRL_AFSEL6
#define GPIO_AFRL_AFRL7 GPIO_AFRL_AFSEL7
/****************** Bit definition for GPIO_AFRH register *********************/
#define GPIO_AFRH_AFSEL8_Pos (0U)
#define GPIO_AFRH_AFSEL8_Msk (0xFUL << GPIO_AFRH_AFSEL8_Pos) /*!< 0x0000000F */
#define GPIO_AFRH_AFSEL8 GPIO_AFRH_AFSEL8_Msk
#define GPIO_AFRH_AFSEL8_0 (0x1UL << GPIO_AFRH_AFSEL8_Pos) /*!< 0x00000001 */
#define GPIO_AFRH_AFSEL8_1 (0x2UL << GPIO_AFRH_AFSEL8_Pos) /*!< 0x00000002 */
#define GPIO_AFRH_AFSEL8_2 (0x4UL << GPIO_AFRH_AFSEL8_Pos) /*!< 0x00000004 */
#define GPIO_AFRH_AFSEL8_3 (0x8UL << GPIO_AFRH_AFSEL8_Pos) /*!< 0x00000008 */
#define GPIO_AFRH_AFSEL9_Pos (4U)
#define GPIO_AFRH_AFSEL9_Msk (0xFUL << GPIO_AFRH_AFSEL9_Pos) /*!< 0x000000F0 */
#define GPIO_AFRH_AFSEL9 GPIO_AFRH_AFSEL9_Msk
#define GPIO_AFRH_AFSEL9_0 (0x1UL << GPIO_AFRH_AFSEL9_Pos) /*!< 0x00000010 */
#define GPIO_AFRH_AFSEL9_1 (0x2UL << GPIO_AFRH_AFSEL9_Pos) /*!< 0x00000020 */
#define GPIO_AFRH_AFSEL9_2 (0x4UL << GPIO_AFRH_AFSEL9_Pos) /*!< 0x00000040 */
#define GPIO_AFRH_AFSEL9_3 (0x8UL << GPIO_AFRH_AFSEL9_Pos) /*!< 0x00000080 */
#define GPIO_AFRH_AFSEL10_Pos (8U)
#define GPIO_AFRH_AFSEL10_Msk (0xFUL << GPIO_AFRH_AFSEL10_Pos) /*!< 0x00000F00 */
#define GPIO_AFRH_AFSEL10 GPIO_AFRH_AFSEL10_Msk
#define GPIO_AFRH_AFSEL10_0 (0x1UL << GPIO_AFRH_AFSEL10_Pos) /*!< 0x00000100 */
#define GPIO_AFRH_AFSEL10_1 (0x2UL << GPIO_AFRH_AFSEL10_Pos) /*!< 0x00000200 */
#define GPIO_AFRH_AFSEL10_2 (0x4UL << GPIO_AFRH_AFSEL10_Pos) /*!< 0x00000400 */
#define GPIO_AFRH_AFSEL10_3 (0x8UL << GPIO_AFRH_AFSEL10_Pos) /*!< 0x00000800 */
#define GPIO_AFRH_AFSEL11_Pos (12U)
#define GPIO_AFRH_AFSEL11_Msk (0xFUL << GPIO_AFRH_AFSEL11_Pos) /*!< 0x0000F000 */
#define GPIO_AFRH_AFSEL11 GPIO_AFRH_AFSEL11_Msk
#define GPIO_AFRH_AFSEL11_0 (0x1UL << GPIO_AFRH_AFSEL11_Pos) /*!< 0x00001000 */
#define GPIO_AFRH_AFSEL11_1 (0x2UL << GPIO_AFRH_AFSEL11_Pos) /*!< 0x00002000 */
#define GPIO_AFRH_AFSEL11_2 (0x4UL << GPIO_AFRH_AFSEL11_Pos) /*!< 0x00004000 */
#define GPIO_AFRH_AFSEL11_3 (0x8UL << GPIO_AFRH_AFSEL11_Pos) /*!< 0x00008000 */
#define GPIO_AFRH_AFSEL12_Pos (16U)
#define GPIO_AFRH_AFSEL12_Msk (0xFUL << GPIO_AFRH_AFSEL12_Pos) /*!< 0x000F0000 */
#define GPIO_AFRH_AFSEL12 GPIO_AFRH_AFSEL12_Msk
#define GPIO_AFRH_AFSEL12_0 (0x1UL << GPIO_AFRH_AFSEL12_Pos) /*!< 0x00010000 */
#define GPIO_AFRH_AFSEL12_1 (0x2UL << GPIO_AFRH_AFSEL12_Pos) /*!< 0x00020000 */
#define GPIO_AFRH_AFSEL12_2 (0x4UL << GPIO_AFRH_AFSEL12_Pos) /*!< 0x00040000 */
#define GPIO_AFRH_AFSEL12_3 (0x8UL << GPIO_AFRH_AFSEL12_Pos) /*!< 0x00080000 */
#define GPIO_AFRH_AFSEL13_Pos (20U)
#define GPIO_AFRH_AFSEL13_Msk (0xFUL << GPIO_AFRH_AFSEL13_Pos) /*!< 0x00F00000 */
#define GPIO_AFRH_AFSEL13 GPIO_AFRH_AFSEL13_Msk
#define GPIO_AFRH_AFSEL13_0 (0x1UL << GPIO_AFRH_AFSEL13_Pos) /*!< 0x00100000 */
#define GPIO_AFRH_AFSEL13_1 (0x2UL << GPIO_AFRH_AFSEL13_Pos) /*!< 0x00200000 */
#define GPIO_AFRH_AFSEL13_2 (0x4UL << GPIO_AFRH_AFSEL13_Pos) /*!< 0x00400000 */
#define GPIO_AFRH_AFSEL13_3 (0x8UL << GPIO_AFRH_AFSEL13_Pos) /*!< 0x00800000 */
#define GPIO_AFRH_AFSEL14_Pos (24U)
#define GPIO_AFRH_AFSEL14_Msk (0xFUL << GPIO_AFRH_AFSEL14_Pos) /*!< 0x0F000000 */
#define GPIO_AFRH_AFSEL14 GPIO_AFRH_AFSEL14_Msk
#define GPIO_AFRH_AFSEL14_0 (0x1UL << GPIO_AFRH_AFSEL14_Pos) /*!< 0x01000000 */
#define GPIO_AFRH_AFSEL14_1 (0x2UL << GPIO_AFRH_AFSEL14_Pos) /*!< 0x02000000 */
#define GPIO_AFRH_AFSEL14_2 (0x4UL << GPIO_AFRH_AFSEL14_Pos) /*!< 0x04000000 */
#define GPIO_AFRH_AFSEL14_3 (0x8UL << GPIO_AFRH_AFSEL14_Pos) /*!< 0x08000000 */
#define GPIO_AFRH_AFSEL15_Pos (28U)
#define GPIO_AFRH_AFSEL15_Msk (0xFUL << GPIO_AFRH_AFSEL15_Pos) /*!< 0xF0000000 */
#define GPIO_AFRH_AFSEL15 GPIO_AFRH_AFSEL15_Msk
#define GPIO_AFRH_AFSEL15_0 (0x1UL << GPIO_AFRH_AFSEL15_Pos) /*!< 0x10000000 */
#define GPIO_AFRH_AFSEL15_1 (0x2UL << GPIO_AFRH_AFSEL15_Pos) /*!< 0x20000000 */
#define GPIO_AFRH_AFSEL15_2 (0x4UL << GPIO_AFRH_AFSEL15_Pos) /*!< 0x40000000 */
#define GPIO_AFRH_AFSEL15_3 (0x8UL << GPIO_AFRH_AFSEL15_Pos) /*!< 0x80000000 */
/* Legacy defines */
#define GPIO_AFRH_AFRH0 GPIO_AFRH_AFSEL8
#define GPIO_AFRH_AFRH1 GPIO_AFRH_AFSEL9
#define GPIO_AFRH_AFRH2 GPIO_AFRH_AFSEL10
#define GPIO_AFRH_AFRH3 GPIO_AFRH_AFSEL11
#define GPIO_AFRH_AFRH4 GPIO_AFRH_AFSEL12
#define GPIO_AFRH_AFRH5 GPIO_AFRH_AFSEL13
#define GPIO_AFRH_AFRH6 GPIO_AFRH_AFSEL14
#define GPIO_AFRH_AFRH7 GPIO_AFRH_AFSEL15
/****************** Bits definition for GPIO_BRR register ******************/
#define GPIO_BRR_BR0_Pos (0U)
#define GPIO_BRR_BR0_Msk (0x1UL << GPIO_BRR_BR0_Pos) /*!< 0x00000001 */
#define GPIO_BRR_BR0 GPIO_BRR_BR0_Msk
#define GPIO_BRR_BR1_Pos (1U)
#define GPIO_BRR_BR1_Msk (0x1UL << GPIO_BRR_BR1_Pos) /*!< 0x00000002 */
#define GPIO_BRR_BR1 GPIO_BRR_BR1_Msk
#define GPIO_BRR_BR2_Pos (2U)
#define GPIO_BRR_BR2_Msk (0x1UL << GPIO_BRR_BR2_Pos) /*!< 0x00000004 */
#define GPIO_BRR_BR2 GPIO_BRR_BR2_Msk
#define GPIO_BRR_BR3_Pos (3U)
#define GPIO_BRR_BR3_Msk (0x1UL << GPIO_BRR_BR3_Pos) /*!< 0x00000008 */
#define GPIO_BRR_BR3 GPIO_BRR_BR3_Msk
#define GPIO_BRR_BR4_Pos (4U)
#define GPIO_BRR_BR4_Msk (0x1UL << GPIO_BRR_BR4_Pos) /*!< 0x00000010 */
#define GPIO_BRR_BR4 GPIO_BRR_BR4_Msk
#define GPIO_BRR_BR5_Pos (5U)
#define GPIO_BRR_BR5_Msk (0x1UL << GPIO_BRR_BR5_Pos) /*!< 0x00000020 */
#define GPIO_BRR_BR5 GPIO_BRR_BR5_Msk
#define GPIO_BRR_BR6_Pos (6U)
#define GPIO_BRR_BR6_Msk (0x1UL << GPIO_BRR_BR6_Pos) /*!< 0x00000040 */
#define GPIO_BRR_BR6 GPIO_BRR_BR6_Msk
#define GPIO_BRR_BR7_Pos (7U)
#define GPIO_BRR_BR7_Msk (0x1UL << GPIO_BRR_BR7_Pos) /*!< 0x00000080 */
#define GPIO_BRR_BR7 GPIO_BRR_BR7_Msk
#define GPIO_BRR_BR8_Pos (8U)
#define GPIO_BRR_BR8_Msk (0x1UL << GPIO_BRR_BR8_Pos) /*!< 0x00000100 */
#define GPIO_BRR_BR8 GPIO_BRR_BR8_Msk
#define GPIO_BRR_BR9_Pos (9U)
#define GPIO_BRR_BR9_Msk (0x1UL << GPIO_BRR_BR9_Pos) /*!< 0x00000200 */
#define GPIO_BRR_BR9 GPIO_BRR_BR9_Msk
#define GPIO_BRR_BR10_Pos (10U)
#define GPIO_BRR_BR10_Msk (0x1UL << GPIO_BRR_BR10_Pos) /*!< 0x00000400 */
#define GPIO_BRR_BR10 GPIO_BRR_BR10_Msk
#define GPIO_BRR_BR11_Pos (11U)
#define GPIO_BRR_BR11_Msk (0x1UL << GPIO_BRR_BR11_Pos) /*!< 0x00000800 */
#define GPIO_BRR_BR11 GPIO_BRR_BR11_Msk
#define GPIO_BRR_BR12_Pos (12U)
#define GPIO_BRR_BR12_Msk (0x1UL << GPIO_BRR_BR12_Pos) /*!< 0x00001000 */
#define GPIO_BRR_BR12 GPIO_BRR_BR12_Msk
#define GPIO_BRR_BR13_Pos (13U)
#define GPIO_BRR_BR13_Msk (0x1UL << GPIO_BRR_BR13_Pos) /*!< 0x00002000 */
#define GPIO_BRR_BR13 GPIO_BRR_BR13_Msk
#define GPIO_BRR_BR14_Pos (14U)
#define GPIO_BRR_BR14_Msk (0x1UL << GPIO_BRR_BR14_Pos) /*!< 0x00004000 */
#define GPIO_BRR_BR14 GPIO_BRR_BR14_Msk
#define GPIO_BRR_BR15_Pos (15U)
#define GPIO_BRR_BR15_Msk (0x1UL << GPIO_BRR_BR15_Pos) /*!< 0x00008000 */
#define GPIO_BRR_BR15 GPIO_BRR_BR15_Msk
/* Legacy defines */
#define GPIO_BRR_BR_0 GPIO_BRR_BR0
#define GPIO_BRR_BR_1 GPIO_BRR_BR1
#define GPIO_BRR_BR_2 GPIO_BRR_BR2
#define GPIO_BRR_BR_3 GPIO_BRR_BR3
#define GPIO_BRR_BR_4 GPIO_BRR_BR4
#define GPIO_BRR_BR_5 GPIO_BRR_BR5
#define GPIO_BRR_BR_6 GPIO_BRR_BR6
#define GPIO_BRR_BR_7 GPIO_BRR_BR7
#define GPIO_BRR_BR_8 GPIO_BRR_BR8
#define GPIO_BRR_BR_9 GPIO_BRR_BR9
#define GPIO_BRR_BR_10 GPIO_BRR_BR10
#define GPIO_BRR_BR_11 GPIO_BRR_BR11
#define GPIO_BRR_BR_12 GPIO_BRR_BR12
#define GPIO_BRR_BR_13 GPIO_BRR_BR13
#define GPIO_BRR_BR_14 GPIO_BRR_BR14
#define GPIO_BRR_BR_15 GPIO_BRR_BR15
/******************************************************************************/
/* */
/* Inter-integrated Circuit Interface (I2C) */
/* */
/******************************************************************************/
/******************* Bit definition for I2C_CR1 register *******************/
#define I2C_CR1_PE_Pos (0U)
#define I2C_CR1_PE_Msk (0x1UL << I2C_CR1_PE_Pos) /*!< 0x00000001 */
#define I2C_CR1_PE I2C_CR1_PE_Msk /*!< Peripheral enable */
#define I2C_CR1_TXIE_Pos (1U)
#define I2C_CR1_TXIE_Msk (0x1UL << I2C_CR1_TXIE_Pos) /*!< 0x00000002 */
#define I2C_CR1_TXIE I2C_CR1_TXIE_Msk /*!< TX interrupt enable */
#define I2C_CR1_RXIE_Pos (2U)
#define I2C_CR1_RXIE_Msk (0x1UL << I2C_CR1_RXIE_Pos) /*!< 0x00000004 */
#define I2C_CR1_RXIE I2C_CR1_RXIE_Msk /*!< RX interrupt enable */
#define I2C_CR1_ADDRIE_Pos (3U)
#define I2C_CR1_ADDRIE_Msk (0x1UL << I2C_CR1_ADDRIE_Pos) /*!< 0x00000008 */
#define I2C_CR1_ADDRIE I2C_CR1_ADDRIE_Msk /*!< Address match interrupt enable */
#define I2C_CR1_NACKIE_Pos (4U)
#define I2C_CR1_NACKIE_Msk (0x1UL << I2C_CR1_NACKIE_Pos) /*!< 0x00000010 */
#define I2C_CR1_NACKIE I2C_CR1_NACKIE_Msk /*!< NACK received interrupt enable */
#define I2C_CR1_STOPIE_Pos (5U)
#define I2C_CR1_STOPIE_Msk (0x1UL << I2C_CR1_STOPIE_Pos) /*!< 0x00000020 */
#define I2C_CR1_STOPIE I2C_CR1_STOPIE_Msk /*!< STOP detection interrupt enable */
#define I2C_CR1_TCIE_Pos (6U)
#define I2C_CR1_TCIE_Msk (0x1UL << I2C_CR1_TCIE_Pos) /*!< 0x00000040 */
#define I2C_CR1_TCIE I2C_CR1_TCIE_Msk /*!< Transfer complete interrupt enable */
#define I2C_CR1_ERRIE_Pos (7U)
#define I2C_CR1_ERRIE_Msk (0x1UL << I2C_CR1_ERRIE_Pos) /*!< 0x00000080 */
#define I2C_CR1_ERRIE I2C_CR1_ERRIE_Msk /*!< Errors interrupt enable */
#define I2C_CR1_DNF_Pos (8U)
#define I2C_CR1_DNF_Msk (0xFUL << I2C_CR1_DNF_Pos) /*!< 0x00000F00 */
#define I2C_CR1_DNF I2C_CR1_DNF_Msk /*!< Digital noise filter */
#define I2C_CR1_ANFOFF_Pos (12U)
#define I2C_CR1_ANFOFF_Msk (0x1UL << I2C_CR1_ANFOFF_Pos) /*!< 0x00001000 */
#define I2C_CR1_ANFOFF I2C_CR1_ANFOFF_Msk /*!< Analog noise filter OFF */
#define I2C_CR1_SWRST_Pos (13U)
#define I2C_CR1_SWRST_Msk (0x1UL << I2C_CR1_SWRST_Pos) /*!< 0x00002000 */
#define I2C_CR1_SWRST I2C_CR1_SWRST_Msk /*!< Software reset */
#define I2C_CR1_TXDMAEN_Pos (14U)
#define I2C_CR1_TXDMAEN_Msk (0x1UL << I2C_CR1_TXDMAEN_Pos) /*!< 0x00004000 */
#define I2C_CR1_TXDMAEN I2C_CR1_TXDMAEN_Msk /*!< DMA transmission requests enable */
#define I2C_CR1_RXDMAEN_Pos (15U)
#define I2C_CR1_RXDMAEN_Msk (0x1UL << I2C_CR1_RXDMAEN_Pos) /*!< 0x00008000 */
#define I2C_CR1_RXDMAEN I2C_CR1_RXDMAEN_Msk /*!< DMA reception requests enable */
#define I2C_CR1_SBC_Pos (16U)
#define I2C_CR1_SBC_Msk (0x1UL << I2C_CR1_SBC_Pos) /*!< 0x00010000 */
#define I2C_CR1_SBC I2C_CR1_SBC_Msk /*!< Slave byte control */
#define I2C_CR1_NOSTRETCH_Pos (17U)
#define I2C_CR1_NOSTRETCH_Msk (0x1UL << I2C_CR1_NOSTRETCH_Pos) /*!< 0x00020000 */
#define I2C_CR1_NOSTRETCH I2C_CR1_NOSTRETCH_Msk /*!< Clock stretching disable */
#define I2C_CR1_WUPEN_Pos (18U)
#define I2C_CR1_WUPEN_Msk (0x1UL << I2C_CR1_WUPEN_Pos) /*!< 0x00040000 */
#define I2C_CR1_WUPEN I2C_CR1_WUPEN_Msk /*!< Wakeup from STOP enable */
#define I2C_CR1_GCEN_Pos (19U)
#define I2C_CR1_GCEN_Msk (0x1UL << I2C_CR1_GCEN_Pos) /*!< 0x00080000 */
#define I2C_CR1_GCEN I2C_CR1_GCEN_Msk /*!< General call enable */
#define I2C_CR1_SMBHEN_Pos (20U)
#define I2C_CR1_SMBHEN_Msk (0x1UL << I2C_CR1_SMBHEN_Pos) /*!< 0x00100000 */
#define I2C_CR1_SMBHEN I2C_CR1_SMBHEN_Msk /*!< SMBus host address enable */
#define I2C_CR1_SMBDEN_Pos (21U)
#define I2C_CR1_SMBDEN_Msk (0x1UL << I2C_CR1_SMBDEN_Pos) /*!< 0x00200000 */
#define I2C_CR1_SMBDEN I2C_CR1_SMBDEN_Msk /*!< SMBus device default address enable */
#define I2C_CR1_ALERTEN_Pos (22U)
#define I2C_CR1_ALERTEN_Msk (0x1UL << I2C_CR1_ALERTEN_Pos) /*!< 0x00400000 */
#define I2C_CR1_ALERTEN I2C_CR1_ALERTEN_Msk /*!< SMBus alert enable */
#define I2C_CR1_PECEN_Pos (23U)
#define I2C_CR1_PECEN_Msk (0x1UL << I2C_CR1_PECEN_Pos) /*!< 0x00800000 */
#define I2C_CR1_PECEN I2C_CR1_PECEN_Msk /*!< PEC enable */
/****************** Bit definition for I2C_CR2 register ********************/
#define I2C_CR2_SADD_Pos (0U)
#define I2C_CR2_SADD_Msk (0x3FFUL << I2C_CR2_SADD_Pos) /*!< 0x000003FF */
#define I2C_CR2_SADD I2C_CR2_SADD_Msk /*!< Slave address (master mode) */
#define I2C_CR2_RD_WRN_Pos (10U)
#define I2C_CR2_RD_WRN_Msk (0x1UL << I2C_CR2_RD_WRN_Pos) /*!< 0x00000400 */
#define I2C_CR2_RD_WRN I2C_CR2_RD_WRN_Msk /*!< Transfer direction (master mode) */
#define I2C_CR2_ADD10_Pos (11U)
#define I2C_CR2_ADD10_Msk (0x1UL << I2C_CR2_ADD10_Pos) /*!< 0x00000800 */
#define I2C_CR2_ADD10 I2C_CR2_ADD10_Msk /*!< 10-bit addressing mode (master mode) */
#define I2C_CR2_HEAD10R_Pos (12U)
#define I2C_CR2_HEAD10R_Msk (0x1UL << I2C_CR2_HEAD10R_Pos) /*!< 0x00001000 */
#define I2C_CR2_HEAD10R I2C_CR2_HEAD10R_Msk /*!< 10-bit address header only read direction (master mode) */
#define I2C_CR2_START_Pos (13U)
#define I2C_CR2_START_Msk (0x1UL << I2C_CR2_START_Pos) /*!< 0x00002000 */
#define I2C_CR2_START I2C_CR2_START_Msk /*!< START generation */
#define I2C_CR2_STOP_Pos (14U)
#define I2C_CR2_STOP_Msk (0x1UL << I2C_CR2_STOP_Pos) /*!< 0x00004000 */
#define I2C_CR2_STOP I2C_CR2_STOP_Msk /*!< STOP generation (master mode) */
#define I2C_CR2_NACK_Pos (15U)
#define I2C_CR2_NACK_Msk (0x1UL << I2C_CR2_NACK_Pos) /*!< 0x00008000 */
#define I2C_CR2_NACK I2C_CR2_NACK_Msk /*!< NACK generation (slave mode) */
#define I2C_CR2_NBYTES_Pos (16U)
#define I2C_CR2_NBYTES_Msk (0xFFUL << I2C_CR2_NBYTES_Pos) /*!< 0x00FF0000 */
#define I2C_CR2_NBYTES I2C_CR2_NBYTES_Msk /*!< Number of bytes */
#define I2C_CR2_RELOAD_Pos (24U)
#define I2C_CR2_RELOAD_Msk (0x1UL << I2C_CR2_RELOAD_Pos) /*!< 0x01000000 */
#define I2C_CR2_RELOAD I2C_CR2_RELOAD_Msk /*!< NBYTES reload mode */
#define I2C_CR2_AUTOEND_Pos (25U)
#define I2C_CR2_AUTOEND_Msk (0x1UL << I2C_CR2_AUTOEND_Pos) /*!< 0x02000000 */
#define I2C_CR2_AUTOEND I2C_CR2_AUTOEND_Msk /*!< Automatic end mode (master mode) */
#define I2C_CR2_PECBYTE_Pos (26U)
#define I2C_CR2_PECBYTE_Msk (0x1UL << I2C_CR2_PECBYTE_Pos) /*!< 0x04000000 */
#define I2C_CR2_PECBYTE I2C_CR2_PECBYTE_Msk /*!< Packet error checking byte */
/******************* Bit definition for I2C_OAR1 register ******************/
#define I2C_OAR1_OA1_Pos (0U)
#define I2C_OAR1_OA1_Msk (0x3FFUL << I2C_OAR1_OA1_Pos) /*!< 0x000003FF */
#define I2C_OAR1_OA1 I2C_OAR1_OA1_Msk /*!< Interface own address 1 */
#define I2C_OAR1_OA1MODE_Pos (10U)
#define I2C_OAR1_OA1MODE_Msk (0x1UL << I2C_OAR1_OA1MODE_Pos) /*!< 0x00000400 */
#define I2C_OAR1_OA1MODE I2C_OAR1_OA1MODE_Msk /*!< Own address 1 10-bit mode */
#define I2C_OAR1_OA1EN_Pos (15U)
#define I2C_OAR1_OA1EN_Msk (0x1UL << I2C_OAR1_OA1EN_Pos) /*!< 0x00008000 */
#define I2C_OAR1_OA1EN I2C_OAR1_OA1EN_Msk /*!< Own address 1 enable */
/******************* Bit definition for I2C_OAR2 register ******************/
#define I2C_OAR2_OA2_Pos (1U)
#define I2C_OAR2_OA2_Msk (0x7FUL << I2C_OAR2_OA2_Pos) /*!< 0x000000FE */
#define I2C_OAR2_OA2 I2C_OAR2_OA2_Msk /*!< Interface own address 2 */
#define I2C_OAR2_OA2MSK_Pos (8U)
#define I2C_OAR2_OA2MSK_Msk (0x7UL << I2C_OAR2_OA2MSK_Pos) /*!< 0x00000700 */
#define I2C_OAR2_OA2MSK I2C_OAR2_OA2MSK_Msk /*!< Own address 2 masks */
#define I2C_OAR2_OA2NOMASK (0x00000000U) /*!< No mask */
#define I2C_OAR2_OA2MASK01_Pos (8U)
#define I2C_OAR2_OA2MASK01_Msk (0x1UL << I2C_OAR2_OA2MASK01_Pos) /*!< 0x00000100 */
#define I2C_OAR2_OA2MASK01 I2C_OAR2_OA2MASK01_Msk /*!< OA2[1] is masked, Only OA2[7:2] are compared */
#define I2C_OAR2_OA2MASK02_Pos (9U)
#define I2C_OAR2_OA2MASK02_Msk (0x1UL << I2C_OAR2_OA2MASK02_Pos) /*!< 0x00000200 */
#define I2C_OAR2_OA2MASK02 I2C_OAR2_OA2MASK02_Msk /*!< OA2[2:1] is masked, Only OA2[7:3] are compared */
#define I2C_OAR2_OA2MASK03_Pos (8U)
#define I2C_OAR2_OA2MASK03_Msk (0x3UL << I2C_OAR2_OA2MASK03_Pos) /*!< 0x00000300 */
#define I2C_OAR2_OA2MASK03 I2C_OAR2_OA2MASK03_Msk /*!< OA2[3:1] is masked, Only OA2[7:4] are compared */
#define I2C_OAR2_OA2MASK04_Pos (10U)
#define I2C_OAR2_OA2MASK04_Msk (0x1UL << I2C_OAR2_OA2MASK04_Pos) /*!< 0x00000400 */
#define I2C_OAR2_OA2MASK04 I2C_OAR2_OA2MASK04_Msk /*!< OA2[4:1] is masked, Only OA2[7:5] are compared */
#define I2C_OAR2_OA2MASK05_Pos (8U)
#define I2C_OAR2_OA2MASK05_Msk (0x5UL << I2C_OAR2_OA2MASK05_Pos) /*!< 0x00000500 */
#define I2C_OAR2_OA2MASK05 I2C_OAR2_OA2MASK05_Msk /*!< OA2[5:1] is masked, Only OA2[7:6] are compared */
#define I2C_OAR2_OA2MASK06_Pos (9U)
#define I2C_OAR2_OA2MASK06_Msk (0x3UL << I2C_OAR2_OA2MASK06_Pos) /*!< 0x00000600 */
#define I2C_OAR2_OA2MASK06 I2C_OAR2_OA2MASK06_Msk /*!< OA2[6:1] is masked, Only OA2[7] are compared */
#define I2C_OAR2_OA2MASK07_Pos (8U)
#define I2C_OAR2_OA2MASK07_Msk (0x7UL << I2C_OAR2_OA2MASK07_Pos) /*!< 0x00000700 */
#define I2C_OAR2_OA2MASK07 I2C_OAR2_OA2MASK07_Msk /*!< OA2[7:1] is masked, No comparison is done */
#define I2C_OAR2_OA2EN_Pos (15U)
#define I2C_OAR2_OA2EN_Msk (0x1UL << I2C_OAR2_OA2EN_Pos) /*!< 0x00008000 */
#define I2C_OAR2_OA2EN I2C_OAR2_OA2EN_Msk /*!< Own address 2 enable */
/******************* Bit definition for I2C_TIMINGR register *******************/
#define I2C_TIMINGR_SCLL_Pos (0U)
#define I2C_TIMINGR_SCLL_Msk (0xFFUL << I2C_TIMINGR_SCLL_Pos) /*!< 0x000000FF */
#define I2C_TIMINGR_SCLL I2C_TIMINGR_SCLL_Msk /*!< SCL low period (master mode) */
#define I2C_TIMINGR_SCLH_Pos (8U)
#define I2C_TIMINGR_SCLH_Msk (0xFFUL << I2C_TIMINGR_SCLH_Pos) /*!< 0x0000FF00 */
#define I2C_TIMINGR_SCLH I2C_TIMINGR_SCLH_Msk /*!< SCL high period (master mode) */
#define I2C_TIMINGR_SDADEL_Pos (16U)
#define I2C_TIMINGR_SDADEL_Msk (0xFUL << I2C_TIMINGR_SDADEL_Pos) /*!< 0x000F0000 */
#define I2C_TIMINGR_SDADEL I2C_TIMINGR_SDADEL_Msk /*!< Data hold time */
#define I2C_TIMINGR_SCLDEL_Pos (20U)
#define I2C_TIMINGR_SCLDEL_Msk (0xFUL << I2C_TIMINGR_SCLDEL_Pos) /*!< 0x00F00000 */
#define I2C_TIMINGR_SCLDEL I2C_TIMINGR_SCLDEL_Msk /*!< Data setup time */
#define I2C_TIMINGR_PRESC_Pos (28U)
#define I2C_TIMINGR_PRESC_Msk (0xFUL << I2C_TIMINGR_PRESC_Pos) /*!< 0xF0000000 */
#define I2C_TIMINGR_PRESC I2C_TIMINGR_PRESC_Msk /*!< Timings prescaler */
/******************* Bit definition for I2C_TIMEOUTR register *******************/
#define I2C_TIMEOUTR_TIMEOUTA_Pos (0U)
#define I2C_TIMEOUTR_TIMEOUTA_Msk (0xFFFUL << I2C_TIMEOUTR_TIMEOUTA_Pos) /*!< 0x00000FFF */
#define I2C_TIMEOUTR_TIMEOUTA I2C_TIMEOUTR_TIMEOUTA_Msk /*!< Bus timeout A */
#define I2C_TIMEOUTR_TIDLE_Pos (12U)
#define I2C_TIMEOUTR_TIDLE_Msk (0x1UL << I2C_TIMEOUTR_TIDLE_Pos) /*!< 0x00001000 */
#define I2C_TIMEOUTR_TIDLE I2C_TIMEOUTR_TIDLE_Msk /*!< Idle clock timeout detection */
#define I2C_TIMEOUTR_TIMOUTEN_Pos (15U)
#define I2C_TIMEOUTR_TIMOUTEN_Msk (0x1UL << I2C_TIMEOUTR_TIMOUTEN_Pos) /*!< 0x00008000 */
#define I2C_TIMEOUTR_TIMOUTEN I2C_TIMEOUTR_TIMOUTEN_Msk /*!< Clock timeout enable */
#define I2C_TIMEOUTR_TIMEOUTB_Pos (16U)
#define I2C_TIMEOUTR_TIMEOUTB_Msk (0xFFFUL << I2C_TIMEOUTR_TIMEOUTB_Pos) /*!< 0x0FFF0000 */
#define I2C_TIMEOUTR_TIMEOUTB I2C_TIMEOUTR_TIMEOUTB_Msk /*!< Bus timeout B */
#define I2C_TIMEOUTR_TEXTEN_Pos (31U)
#define I2C_TIMEOUTR_TEXTEN_Msk (0x1UL << I2C_TIMEOUTR_TEXTEN_Pos) /*!< 0x80000000 */
#define I2C_TIMEOUTR_TEXTEN I2C_TIMEOUTR_TEXTEN_Msk /*!< Extended clock timeout enable */
/****************** Bit definition for I2C_ISR register *********************/
#define I2C_ISR_TXE_Pos (0U)
#define I2C_ISR_TXE_Msk (0x1UL << I2C_ISR_TXE_Pos) /*!< 0x00000001 */
#define I2C_ISR_TXE I2C_ISR_TXE_Msk /*!< Transmit data register empty */
#define I2C_ISR_TXIS_Pos (1U)
#define I2C_ISR_TXIS_Msk (0x1UL << I2C_ISR_TXIS_Pos) /*!< 0x00000002 */
#define I2C_ISR_TXIS I2C_ISR_TXIS_Msk /*!< Transmit interrupt status */
#define I2C_ISR_RXNE_Pos (2U)
#define I2C_ISR_RXNE_Msk (0x1UL << I2C_ISR_RXNE_Pos) /*!< 0x00000004 */
#define I2C_ISR_RXNE I2C_ISR_RXNE_Msk /*!< Receive data register not empty */
#define I2C_ISR_ADDR_Pos (3U)
#define I2C_ISR_ADDR_Msk (0x1UL << I2C_ISR_ADDR_Pos) /*!< 0x00000008 */
#define I2C_ISR_ADDR I2C_ISR_ADDR_Msk /*!< Address matched (slave mode) */
#define I2C_ISR_NACKF_Pos (4U)
#define I2C_ISR_NACKF_Msk (0x1UL << I2C_ISR_NACKF_Pos) /*!< 0x00000010 */
#define I2C_ISR_NACKF I2C_ISR_NACKF_Msk /*!< NACK received flag */
#define I2C_ISR_STOPF_Pos (5U)
#define I2C_ISR_STOPF_Msk (0x1UL << I2C_ISR_STOPF_Pos) /*!< 0x00000020 */
#define I2C_ISR_STOPF I2C_ISR_STOPF_Msk /*!< STOP detection flag */
#define I2C_ISR_TC_Pos (6U)
#define I2C_ISR_TC_Msk (0x1UL << I2C_ISR_TC_Pos) /*!< 0x00000040 */
#define I2C_ISR_TC I2C_ISR_TC_Msk /*!< Transfer complete (master mode) */
#define I2C_ISR_TCR_Pos (7U)
#define I2C_ISR_TCR_Msk (0x1UL << I2C_ISR_TCR_Pos) /*!< 0x00000080 */
#define I2C_ISR_TCR I2C_ISR_TCR_Msk /*!< Transfer complete reload */
#define I2C_ISR_BERR_Pos (8U)
#define I2C_ISR_BERR_Msk (0x1UL << I2C_ISR_BERR_Pos) /*!< 0x00000100 */
#define I2C_ISR_BERR I2C_ISR_BERR_Msk /*!< Bus error */
#define I2C_ISR_ARLO_Pos (9U)
#define I2C_ISR_ARLO_Msk (0x1UL << I2C_ISR_ARLO_Pos) /*!< 0x00000200 */
#define I2C_ISR_ARLO I2C_ISR_ARLO_Msk /*!< Arbitration lost */
#define I2C_ISR_OVR_Pos (10U)
#define I2C_ISR_OVR_Msk (0x1UL << I2C_ISR_OVR_Pos) /*!< 0x00000400 */
#define I2C_ISR_OVR I2C_ISR_OVR_Msk /*!< Overrun/Underrun */
#define I2C_ISR_PECERR_Pos (11U)
#define I2C_ISR_PECERR_Msk (0x1UL << I2C_ISR_PECERR_Pos) /*!< 0x00000800 */
#define I2C_ISR_PECERR I2C_ISR_PECERR_Msk /*!< PEC error in reception */
#define I2C_ISR_TIMEOUT_Pos (12U)
#define I2C_ISR_TIMEOUT_Msk (0x1UL << I2C_ISR_TIMEOUT_Pos) /*!< 0x00001000 */
#define I2C_ISR_TIMEOUT I2C_ISR_TIMEOUT_Msk /*!< Timeout or Tlow detection flag */
#define I2C_ISR_ALERT_Pos (13U)
#define I2C_ISR_ALERT_Msk (0x1UL << I2C_ISR_ALERT_Pos) /*!< 0x00002000 */
#define I2C_ISR_ALERT I2C_ISR_ALERT_Msk /*!< SMBus alert */
#define I2C_ISR_BUSY_Pos (15U)
#define I2C_ISR_BUSY_Msk (0x1UL << I2C_ISR_BUSY_Pos) /*!< 0x00008000 */
#define I2C_ISR_BUSY I2C_ISR_BUSY_Msk /*!< Bus busy */
#define I2C_ISR_DIR_Pos (16U)
#define I2C_ISR_DIR_Msk (0x1UL << I2C_ISR_DIR_Pos) /*!< 0x00010000 */
#define I2C_ISR_DIR I2C_ISR_DIR_Msk /*!< Transfer direction (slave mode) */
#define I2C_ISR_ADDCODE_Pos (17U)
#define I2C_ISR_ADDCODE_Msk (0x7FUL << I2C_ISR_ADDCODE_Pos) /*!< 0x00FE0000 */
#define I2C_ISR_ADDCODE I2C_ISR_ADDCODE_Msk /*!< Address match code (slave mode) */
/****************** Bit definition for I2C_ICR register *********************/
#define I2C_ICR_ADDRCF_Pos (3U)
#define I2C_ICR_ADDRCF_Msk (0x1UL << I2C_ICR_ADDRCF_Pos) /*!< 0x00000008 */
#define I2C_ICR_ADDRCF I2C_ICR_ADDRCF_Msk /*!< Address matched clear flag */
#define I2C_ICR_NACKCF_Pos (4U)
#define I2C_ICR_NACKCF_Msk (0x1UL << I2C_ICR_NACKCF_Pos) /*!< 0x00000010 */
#define I2C_ICR_NACKCF I2C_ICR_NACKCF_Msk /*!< NACK clear flag */
#define I2C_ICR_STOPCF_Pos (5U)
#define I2C_ICR_STOPCF_Msk (0x1UL << I2C_ICR_STOPCF_Pos) /*!< 0x00000020 */
#define I2C_ICR_STOPCF I2C_ICR_STOPCF_Msk /*!< STOP detection clear flag */
#define I2C_ICR_BERRCF_Pos (8U)
#define I2C_ICR_BERRCF_Msk (0x1UL << I2C_ICR_BERRCF_Pos) /*!< 0x00000100 */
#define I2C_ICR_BERRCF I2C_ICR_BERRCF_Msk /*!< Bus error clear flag */
#define I2C_ICR_ARLOCF_Pos (9U)
#define I2C_ICR_ARLOCF_Msk (0x1UL << I2C_ICR_ARLOCF_Pos) /*!< 0x00000200 */
#define I2C_ICR_ARLOCF I2C_ICR_ARLOCF_Msk /*!< Arbitration lost clear flag */
#define I2C_ICR_OVRCF_Pos (10U)
#define I2C_ICR_OVRCF_Msk (0x1UL << I2C_ICR_OVRCF_Pos) /*!< 0x00000400 */
#define I2C_ICR_OVRCF I2C_ICR_OVRCF_Msk /*!< Overrun/Underrun clear flag */
#define I2C_ICR_PECCF_Pos (11U)
#define I2C_ICR_PECCF_Msk (0x1UL << I2C_ICR_PECCF_Pos) /*!< 0x00000800 */
#define I2C_ICR_PECCF I2C_ICR_PECCF_Msk /*!< PAC error clear flag */
#define I2C_ICR_TIMOUTCF_Pos (12U)
#define I2C_ICR_TIMOUTCF_Msk (0x1UL << I2C_ICR_TIMOUTCF_Pos) /*!< 0x00001000 */
#define I2C_ICR_TIMOUTCF I2C_ICR_TIMOUTCF_Msk /*!< Timeout clear flag */
#define I2C_ICR_ALERTCF_Pos (13U)
#define I2C_ICR_ALERTCF_Msk (0x1UL << I2C_ICR_ALERTCF_Pos) /*!< 0x00002000 */
#define I2C_ICR_ALERTCF I2C_ICR_ALERTCF_Msk /*!< Alert clear flag */
/****************** Bit definition for I2C_PECR register *********************/
#define I2C_PECR_PEC_Pos (0U)
#define I2C_PECR_PEC_Msk (0xFFUL << I2C_PECR_PEC_Pos) /*!< 0x000000FF */
#define I2C_PECR_PEC I2C_PECR_PEC_Msk /*!< PEC register */
/****************** Bit definition for I2C_RXDR register *********************/
#define I2C_RXDR_RXDATA_Pos (0U)
#define I2C_RXDR_RXDATA_Msk (0xFFUL << I2C_RXDR_RXDATA_Pos) /*!< 0x000000FF */
#define I2C_RXDR_RXDATA I2C_RXDR_RXDATA_Msk /*!< 8-bit receive data */
/****************** Bit definition for I2C_TXDR register *********************/
#define I2C_TXDR_TXDATA_Pos (0U)
#define I2C_TXDR_TXDATA_Msk (0xFFUL << I2C_TXDR_TXDATA_Pos) /*!< 0x000000FF */
#define I2C_TXDR_TXDATA I2C_TXDR_TXDATA_Msk /*!< 8-bit transmit data */
/******************************************************************************/
/* */
/* Independent WATCHDOG */
/* */
/******************************************************************************/
/******************* Bit definition for IWDG_KR register ********************/
#define IWDG_KR_KEY_Pos (0U)
#define IWDG_KR_KEY_Msk (0xFFFFUL << IWDG_KR_KEY_Pos) /*!< 0x0000FFFF */
#define IWDG_KR_KEY IWDG_KR_KEY_Msk /*!<Key value (write only, read 0000h) */
/******************* Bit definition for IWDG_PR register ********************/
#define IWDG_PR_PR_Pos (0U)
#define IWDG_PR_PR_Msk (0x7UL << IWDG_PR_PR_Pos) /*!< 0x00000007 */
#define IWDG_PR_PR IWDG_PR_PR_Msk /*!<PR[2:0] (Prescaler divider) */
#define IWDG_PR_PR_0 (0x1UL << IWDG_PR_PR_Pos) /*!< 0x00000001 */
#define IWDG_PR_PR_1 (0x2UL << IWDG_PR_PR_Pos) /*!< 0x00000002 */
#define IWDG_PR_PR_2 (0x4UL << IWDG_PR_PR_Pos) /*!< 0x00000004 */
/******************* Bit definition for IWDG_RLR register *******************/
#define IWDG_RLR_RL_Pos (0U)
#define IWDG_RLR_RL_Msk (0xFFFUL << IWDG_RLR_RL_Pos) /*!< 0x00000FFF */
#define IWDG_RLR_RL IWDG_RLR_RL_Msk /*!<Watchdog counter reload value */
/******************* Bit definition for IWDG_SR register ********************/
#define IWDG_SR_PVU_Pos (0U)
#define IWDG_SR_PVU_Msk (0x1UL << IWDG_SR_PVU_Pos) /*!< 0x00000001 */
#define IWDG_SR_PVU IWDG_SR_PVU_Msk /*!< Watchdog prescaler value update */
#define IWDG_SR_RVU_Pos (1U)
#define IWDG_SR_RVU_Msk (0x1UL << IWDG_SR_RVU_Pos) /*!< 0x00000002 */
#define IWDG_SR_RVU IWDG_SR_RVU_Msk /*!< Watchdog counter reload value update */
#define IWDG_SR_WVU_Pos (2U)
#define IWDG_SR_WVU_Msk (0x1UL << IWDG_SR_WVU_Pos) /*!< 0x00000004 */
#define IWDG_SR_WVU IWDG_SR_WVU_Msk /*!< Watchdog counter window value update */
/******************* Bit definition for IWDG_KR register ********************/
#define IWDG_WINR_WIN_Pos (0U)
#define IWDG_WINR_WIN_Msk (0xFFFUL << IWDG_WINR_WIN_Pos) /*!< 0x00000FFF */
#define IWDG_WINR_WIN IWDG_WINR_WIN_Msk /*!< Watchdog counter window value */
/******************************************************************************/
/* */
/* Operational Amplifier (OPAMP) */
/* */
/******************************************************************************/
/********************* Bit definition for OPAMPx_CSR register ***************/
#define OPAMP_CSR_OPAMPxEN_Pos (0U)
#define OPAMP_CSR_OPAMPxEN_Msk (0x1UL << OPAMP_CSR_OPAMPxEN_Pos) /*!< 0x00000001 */
#define OPAMP_CSR_OPAMPxEN OPAMP_CSR_OPAMPxEN_Msk /*!< OPAMP enable */
#define OPAMP_CSR_FORCEVP_Pos (1U)
#define OPAMP_CSR_FORCEVP_Msk (0x1UL << OPAMP_CSR_FORCEVP_Pos) /*!< 0x00000002 */
#define OPAMP_CSR_FORCEVP OPAMP_CSR_FORCEVP_Msk /*!< Connect the internal references to the plus input of the OPAMPX */
#define OPAMP_CSR_VPSEL_Pos (2U)
#define OPAMP_CSR_VPSEL_Msk (0x3UL << OPAMP_CSR_VPSEL_Pos) /*!< 0x0000000C */
#define OPAMP_CSR_VPSEL OPAMP_CSR_VPSEL_Msk /*!< Non inverting input selection */
#define OPAMP_CSR_VPSEL_0 (0x1UL << OPAMP_CSR_VPSEL_Pos) /*!< 0x00000004 */
#define OPAMP_CSR_VPSEL_1 (0x2UL << OPAMP_CSR_VPSEL_Pos) /*!< 0x00000008 */
#define OPAMP_CSR_USERTRIM_Pos (4U)
#define OPAMP_CSR_USERTRIM_Msk (0x1UL << OPAMP_CSR_USERTRIM_Pos) /*!< 0x00000010 */
#define OPAMP_CSR_USERTRIM OPAMP_CSR_USERTRIM_Msk /*!< User trimming enable */
#define OPAMP_CSR_VMSEL_Pos (5U)
#define OPAMP_CSR_VMSEL_Msk (0x3UL << OPAMP_CSR_VMSEL_Pos) /*!< 0x00000060 */
#define OPAMP_CSR_VMSEL OPAMP_CSR_VMSEL_Msk /*!< Inverting input selection */
#define OPAMP_CSR_VMSEL_0 (0x1UL << OPAMP_CSR_VMSEL_Pos) /*!< 0x00000020 */
#define OPAMP_CSR_VMSEL_1 (0x2UL << OPAMP_CSR_VMSEL_Pos) /*!< 0x00000040 */
#define OPAMP_CSR_HIGHSPEEDEN_Pos (7U)
#define OPAMP_CSR_HIGHSPEEDEN_Msk (0x1UL << OPAMP_CSR_HIGHSPEEDEN_Pos) /*!< 0x00000080 */
#define OPAMP_CSR_HIGHSPEEDEN OPAMP_CSR_HIGHSPEEDEN_Msk /*!< High speed mode enable */
#define OPAMP_CSR_OPAMPINTEN_Pos (8U)
#define OPAMP_CSR_OPAMPINTEN_Msk (0x1UL << OPAMP_CSR_OPAMPINTEN_Pos) /*!< 0x00000100 */
#define OPAMP_CSR_OPAMPINTEN OPAMP_CSR_OPAMPINTEN_Msk /*!< Internal output enable */
#define OPAMP_CSR_CALON_Pos (11U)
#define OPAMP_CSR_CALON_Msk (0x1UL << OPAMP_CSR_CALON_Pos) /*!< 0x00000800 */
#define OPAMP_CSR_CALON OPAMP_CSR_CALON_Msk /*!< Calibration mode enable */
#define OPAMP_CSR_CALSEL_Pos (12U)
#define OPAMP_CSR_CALSEL_Msk (0x3UL << OPAMP_CSR_CALSEL_Pos) /*!< 0x00003000 */
#define OPAMP_CSR_CALSEL OPAMP_CSR_CALSEL_Msk /*!< Calibration selection */
#define OPAMP_CSR_CALSEL_0 (0x1UL << OPAMP_CSR_CALSEL_Pos) /*!< 0x00001000 */
#define OPAMP_CSR_CALSEL_1 (0x2UL << OPAMP_CSR_CALSEL_Pos) /*!< 0x00002000 */
#define OPAMP_CSR_PGGAIN_Pos (14U)
#define OPAMP_CSR_PGGAIN_Msk (0x1FUL << OPAMP_CSR_PGGAIN_Pos) /*!< 0x0007C000 */
#define OPAMP_CSR_PGGAIN OPAMP_CSR_PGGAIN_Msk /*!< Gain in PGA mode */
#define OPAMP_CSR_PGGAIN_0 (0x1UL << OPAMP_CSR_PGGAIN_Pos) /*!< 0x00004000 */
#define OPAMP_CSR_PGGAIN_1 (0x2UL << OPAMP_CSR_PGGAIN_Pos) /*!< 0x00008000 */
#define OPAMP_CSR_PGGAIN_2 (0x4UL << OPAMP_CSR_PGGAIN_Pos) /*!< 0x00010000 */
#define OPAMP_CSR_PGGAIN_3 (0x8UL << OPAMP_CSR_PGGAIN_Pos) /*!< 0x00020000 */
#define OPAMP_CSR_PGGAIN_4 (0x10UL << OPAMP_CSR_PGGAIN_Pos) /*!< 0x00040000 */
#define OPAMP_CSR_TRIMOFFSETP_Pos (19U)
#define OPAMP_CSR_TRIMOFFSETP_Msk (0x1FUL << OPAMP_CSR_TRIMOFFSETP_Pos) /*!< 0x00F80000 */
#define OPAMP_CSR_TRIMOFFSETP OPAMP_CSR_TRIMOFFSETP_Msk /*!< Offset trimming value (PMOS) */
#define OPAMP_CSR_TRIMOFFSETN_Pos (24U)
#define OPAMP_CSR_TRIMOFFSETN_Msk (0x1FUL << OPAMP_CSR_TRIMOFFSETN_Pos) /*!< 0x1F000000 */
#define OPAMP_CSR_TRIMOFFSETN OPAMP_CSR_TRIMOFFSETN_Msk /*!< Offset trimming value (NMOS) */
#define OPAMP_CSR_OUTCAL_Pos (30U)
#define OPAMP_CSR_OUTCAL_Msk (0x1UL << OPAMP_CSR_OUTCAL_Pos) /*!< 0x40000000 */
#define OPAMP_CSR_OUTCAL OPAMP_CSR_OUTCAL_Msk /*!< OPAMP output status flag */
#define OPAMP_CSR_LOCK_Pos (31U)
#define OPAMP_CSR_LOCK_Msk (0x1UL << OPAMP_CSR_LOCK_Pos) /*!< 0x80000000 */
#define OPAMP_CSR_LOCK OPAMP_CSR_LOCK_Msk /*!< OPAMP control/status register lock */
/********************* Bit definition for OPAMPx_TCMR register ***************/
#define OPAMP_TCMR_VMSSEL_Pos (0U)
#define OPAMP_TCMR_VMSSEL_Msk (0x1UL << OPAMP_TCMR_VMSSEL_Pos) /*!< 0x00000001 */
#define OPAMP_TCMR_VMSSEL OPAMP_TCMR_VMSSEL_Msk /*!< Secondary inverting input selection */
#define OPAMP_TCMR_VPSSEL_Pos (1U)
#define OPAMP_TCMR_VPSSEL_Msk (0x3UL << OPAMP_TCMR_VPSSEL_Pos) /*!< 0x00000006 */
#define OPAMP_TCMR_VPSSEL OPAMP_TCMR_VPSSEL_Msk /*!< Secondary non inverting input selection */
#define OPAMP_TCMR_VPSSEL_0 (0x1UL << OPAMP_TCMR_VPSSEL_Pos) /*!< 0x00000002 */
#define OPAMP_TCMR_VPSSEL_1 (0x2UL << OPAMP_TCMR_VPSSEL_Pos) /*!< 0x00000004 */
#define OPAMP_TCMR_T1CMEN_Pos (3U)
#define OPAMP_TCMR_T1CMEN_Msk (0x1UL << OPAMP_TCMR_T1CMEN_Pos) /*!< 0x00000008 */
#define OPAMP_TCMR_T1CMEN OPAMP_TCMR_T1CMEN_Msk /*!< Timer 1 controlled mux mode enable */
#define OPAMP_TCMR_T8CMEN_Pos (4U)
#define OPAMP_TCMR_T8CMEN_Msk (0x1UL << OPAMP_TCMR_T8CMEN_Pos) /*!< 0x00000010 */
#define OPAMP_TCMR_T8CMEN OPAMP_TCMR_T8CMEN_Msk /*!< Timer 8 controlled mux mode enable */
#define OPAMP_TCMR_T20CMEN_Pos (5U)
#define OPAMP_TCMR_T20CMEN_Msk (0x1UL << OPAMP_TCMR_T20CMEN_Pos) /*!< 0x00000020 */
#define OPAMP_TCMR_T20CMEN OPAMP_TCMR_T20CMEN_Msk /*!< Timer 20 controlled mux mode enable */
#define OPAMP_TCMR_LOCK_Pos (31U)
#define OPAMP_TCMR_LOCK_Msk (0x1UL << OPAMP_TCMR_LOCK_Pos) /*!< 0x80000000 */
#define OPAMP_TCMR_LOCK OPAMP_TCMR_LOCK_Msk /*!< OPAMP SW control register lock */
/******************************************************************************/
/* */
/* Power Control */
/* */
/******************************************************************************/
/******************** Bit definition for PWR_CR1 register ********************/
#define PWR_CR1_LPR_Pos (14U)
#define PWR_CR1_LPR_Msk (0x1UL << PWR_CR1_LPR_Pos) /*!< 0x00004000 */
#define PWR_CR1_LPR PWR_CR1_LPR_Msk /*!< Regulator low-power mode */
#define PWR_CR1_VOS_Pos (9U)
#define PWR_CR1_VOS_Msk (0x3UL << PWR_CR1_VOS_Pos) /*!< 0x00000600 */
#define PWR_CR1_VOS PWR_CR1_VOS_Msk /*!< VOS[1:0] bits (Regulator voltage scaling output selection) */
#define PWR_CR1_VOS_0 (0x1UL << PWR_CR1_VOS_Pos) /*!< 0x00000200 */
#define PWR_CR1_VOS_1 (0x2UL << PWR_CR1_VOS_Pos) /*!< 0x00000400 */
#define PWR_CR1_DBP_Pos (8U)
#define PWR_CR1_DBP_Msk (0x1UL << PWR_CR1_DBP_Pos) /*!< 0x00000100 */
#define PWR_CR1_DBP PWR_CR1_DBP_Msk /*!< Disable Back-up domain Protection */
#define PWR_CR1_LPMS_Pos (0U)
#define PWR_CR1_LPMS_Msk (0x7UL << PWR_CR1_LPMS_Pos) /*!< 0x00000007 */
#define PWR_CR1_LPMS PWR_CR1_LPMS_Msk /*!< Low-power mode selection field */
#define PWR_CR1_LPMS_STOP0 (0x00000000U) /*!< Stop 0 mode */
#define PWR_CR1_LPMS_STOP1_Pos (0U)
#define PWR_CR1_LPMS_STOP1_Msk (0x1UL << PWR_CR1_LPMS_STOP1_Pos) /*!< 0x00000001 */
#define PWR_CR1_LPMS_STOP1 PWR_CR1_LPMS_STOP1_Msk /*!< Stop 1 mode */
#define PWR_CR1_LPMS_STANDBY_Pos (0U)
#define PWR_CR1_LPMS_STANDBY_Msk (0x3UL << PWR_CR1_LPMS_STANDBY_Pos) /*!< 0x00000003 */
#define PWR_CR1_LPMS_STANDBY PWR_CR1_LPMS_STANDBY_Msk /*!< Stand-by mode */
#define PWR_CR1_LPMS_SHUTDOWN_Pos (2U)
#define PWR_CR1_LPMS_SHUTDOWN_Msk (0x1UL << PWR_CR1_LPMS_SHUTDOWN_Pos) /*!< 0x00000004 */
#define PWR_CR1_LPMS_SHUTDOWN PWR_CR1_LPMS_SHUTDOWN_Msk /*!< Shut-down mode */
/******************** Bit definition for PWR_CR2 register ********************/
/*!< PVME Peripheral Voltage Monitor Enable */
#define PWR_CR2_PVME_Pos (4U)
#define PWR_CR2_PVME_Msk (0xFUL << PWR_CR2_PVME_Pos) /*!< 0x000000F0 */
#define PWR_CR2_PVME PWR_CR2_PVME_Msk /*!< PVM bits field */
#define PWR_CR2_PVME4_Pos (7U)
#define PWR_CR2_PVME4_Msk (0x1UL << PWR_CR2_PVME4_Pos) /*!< 0x00000080 */
#define PWR_CR2_PVME4 PWR_CR2_PVME4_Msk /*!< PVM 4 Enable */
#define PWR_CR2_PVME3_Pos (6U)
#define PWR_CR2_PVME3_Msk (0x1UL << PWR_CR2_PVME3_Pos) /*!< 0x00000040 */
#define PWR_CR2_PVME3 PWR_CR2_PVME3_Msk /*!< PVM 3 Enable */
#define PWR_CR2_PVME2_Pos (5U)
#define PWR_CR2_PVME2_Msk (0x1UL << PWR_CR2_PVME2_Pos) /*!< 0x00000020 */
#define PWR_CR2_PVME2 PWR_CR2_PVME2_Msk /*!< PVM 2 Enable */
#define PWR_CR2_PVME1_Pos (4U)
#define PWR_CR2_PVME1_Msk (0x1UL << PWR_CR2_PVME1_Pos) /*!< 0x00000010 */
#define PWR_CR2_PVME1 PWR_CR2_PVME1_Msk /*!< PVM 1 Enable */
/*!< PVD level configuration */
#define PWR_CR2_PLS_Pos (1U)
#define PWR_CR2_PLS_Msk (0x7UL << PWR_CR2_PLS_Pos) /*!< 0x0000000E */
#define PWR_CR2_PLS PWR_CR2_PLS_Msk /*!< PVD level selection */
#define PWR_CR2_PLS_LEV0 (0x00000000U) /*!< PVD level 0 */
#define PWR_CR2_PLS_LEV1_Pos (1U)
#define PWR_CR2_PLS_LEV1_Msk (0x1UL << PWR_CR2_PLS_LEV1_Pos) /*!< 0x00000002 */
#define PWR_CR2_PLS_LEV1 PWR_CR2_PLS_LEV1_Msk /*!< PVD level 1 */
#define PWR_CR2_PLS_LEV2_Pos (2U)
#define PWR_CR2_PLS_LEV2_Msk (0x1UL << PWR_CR2_PLS_LEV2_Pos) /*!< 0x00000004 */
#define PWR_CR2_PLS_LEV2 PWR_CR2_PLS_LEV2_Msk /*!< PVD level 2 */
#define PWR_CR2_PLS_LEV3_Pos (1U)
#define PWR_CR2_PLS_LEV3_Msk (0x3UL << PWR_CR2_PLS_LEV3_Pos) /*!< 0x00000006 */
#define PWR_CR2_PLS_LEV3 PWR_CR2_PLS_LEV3_Msk /*!< PVD level 3 */
#define PWR_CR2_PLS_LEV4_Pos (3U)
#define PWR_CR2_PLS_LEV4_Msk (0x1UL << PWR_CR2_PLS_LEV4_Pos) /*!< 0x00000008 */
#define PWR_CR2_PLS_LEV4 PWR_CR2_PLS_LEV4_Msk /*!< PVD level 4 */
#define PWR_CR2_PLS_LEV5_Pos (1U)
#define PWR_CR2_PLS_LEV5_Msk (0x5UL << PWR_CR2_PLS_LEV5_Pos) /*!< 0x0000000A */
#define PWR_CR2_PLS_LEV5 PWR_CR2_PLS_LEV5_Msk /*!< PVD level 5 */
#define PWR_CR2_PLS_LEV6_Pos (2U)
#define PWR_CR2_PLS_LEV6_Msk (0x3UL << PWR_CR2_PLS_LEV6_Pos) /*!< 0x0000000C */
#define PWR_CR2_PLS_LEV6 PWR_CR2_PLS_LEV6_Msk /*!< PVD level 6 */
#define PWR_CR2_PLS_LEV7_Pos (1U)
#define PWR_CR2_PLS_LEV7_Msk (0x7UL << PWR_CR2_PLS_LEV7_Pos) /*!< 0x0000000E */
#define PWR_CR2_PLS_LEV7 PWR_CR2_PLS_LEV7_Msk /*!< PVD level 7 */
#define PWR_CR2_PVDE_Pos (0U)
#define PWR_CR2_PVDE_Msk (0x1UL << PWR_CR2_PVDE_Pos) /*!< 0x00000001 */
#define PWR_CR2_PVDE PWR_CR2_PVDE_Msk /*!< Power Voltage Detector Enable */
/******************** Bit definition for PWR_CR3 register ********************/
#define PWR_CR3_EIWF_Pos (15U)
#define PWR_CR3_EIWF_Msk (0x1UL << PWR_CR3_EIWF_Pos) /*!< 0x00008000 */
#define PWR_CR3_EIWF PWR_CR3_EIWF_Msk /*!< Enable Internal Wake-up line */
#define PWR_CR3_UCPD_DBDIS_Pos (14U)
#define PWR_CR3_UCPD_DBDIS_Msk (0x1UL << PWR_CR3_UCPD_DBDIS_Pos) /*!< 0x00004000 */
#define PWR_CR3_UCPD_DBDIS PWR_CR3_UCPD_DBDIS_Msk /*!< USB Type-C and Power Delivery Dead Battery disable. */
#define PWR_CR3_UCPD_STDBY_Pos (13U)
#define PWR_CR3_UCPD_STDBY_Msk (0x1UL << PWR_CR3_UCPD_STDBY_Pos) /*!< 0x00002000 */
#define PWR_CR3_UCPD_STDBY PWR_CR3_UCPD_STDBY_Msk /*!< USB Type-C and Power Delivery standby mode. */
#define PWR_CR3_APC_Pos (10U)
#define PWR_CR3_APC_Msk (0x1UL << PWR_CR3_APC_Pos) /*!< 0x00000400 */
#define PWR_CR3_APC PWR_CR3_APC_Msk /*!< Apply pull-up and pull-down configuration */
#define PWR_CR3_RRS_Pos (8U)
#define PWR_CR3_RRS_Msk (0x1UL << PWR_CR3_RRS_Pos) /*!< 0x00000100 */
#define PWR_CR3_RRS PWR_CR3_RRS_Msk /*!< SRAM2 Retention in Stand-by mode */
#define PWR_CR3_EWUP5_Pos (4U)
#define PWR_CR3_EWUP5_Msk (0x1UL << PWR_CR3_EWUP5_Pos) /*!< 0x00000010 */
#define PWR_CR3_EWUP5 PWR_CR3_EWUP5_Msk /*!< Enable Wake-Up Pin 5 */
#define PWR_CR3_EWUP4_Pos (3U)
#define PWR_CR3_EWUP4_Msk (0x1UL << PWR_CR3_EWUP4_Pos) /*!< 0x00000008 */
#define PWR_CR3_EWUP4 PWR_CR3_EWUP4_Msk /*!< Enable Wake-Up Pin 4 */
#define PWR_CR3_EWUP3_Pos (2U)
#define PWR_CR3_EWUP3_Msk (0x1UL << PWR_CR3_EWUP3_Pos) /*!< 0x00000004 */
#define PWR_CR3_EWUP3 PWR_CR3_EWUP3_Msk /*!< Enable Wake-Up Pin 3 */
#define PWR_CR3_EWUP2_Pos (1U)
#define PWR_CR3_EWUP2_Msk (0x1UL << PWR_CR3_EWUP2_Pos) /*!< 0x00000002 */
#define PWR_CR3_EWUP2 PWR_CR3_EWUP2_Msk /*!< Enable Wake-Up Pin 2 */
#define PWR_CR3_EWUP1_Pos (0U)
#define PWR_CR3_EWUP1_Msk (0x1UL << PWR_CR3_EWUP1_Pos) /*!< 0x00000001 */
#define PWR_CR3_EWUP1 PWR_CR3_EWUP1_Msk /*!< Enable Wake-Up Pin 1 */
#define PWR_CR3_EWUP_Pos (0U)
#define PWR_CR3_EWUP_Msk (0x1FUL << PWR_CR3_EWUP_Pos) /*!< 0x0000001F */
#define PWR_CR3_EWUP PWR_CR3_EWUP_Msk /*!< Enable Wake-Up Pins */
/******************** Bit definition for PWR_CR4 register ********************/
#define PWR_CR4_VBRS_Pos (9U)
#define PWR_CR4_VBRS_Msk (0x1UL << PWR_CR4_VBRS_Pos) /*!< 0x00000200 */
#define PWR_CR4_VBRS PWR_CR4_VBRS_Msk /*!< VBAT Battery charging Resistor Selection */
#define PWR_CR4_VBE_Pos (8U)
#define PWR_CR4_VBE_Msk (0x1UL << PWR_CR4_VBE_Pos) /*!< 0x00000100 */
#define PWR_CR4_VBE PWR_CR4_VBE_Msk /*!< VBAT Battery charging Enable */
#define PWR_CR4_WP5_Pos (4U)
#define PWR_CR4_WP5_Msk (0x1UL << PWR_CR4_WP5_Pos) /*!< 0x00000010 */
#define PWR_CR4_WP5 PWR_CR4_WP5_Msk /*!< Wake-Up Pin 5 polarity */
#define PWR_CR4_WP4_Pos (3U)
#define PWR_CR4_WP4_Msk (0x1UL << PWR_CR4_WP4_Pos) /*!< 0x00000008 */
#define PWR_CR4_WP4 PWR_CR4_WP4_Msk /*!< Wake-Up Pin 4 polarity */
#define PWR_CR4_WP3_Pos (2U)
#define PWR_CR4_WP3_Msk (0x1UL << PWR_CR4_WP3_Pos) /*!< 0x00000004 */
#define PWR_CR4_WP3 PWR_CR4_WP3_Msk /*!< Wake-Up Pin 3 polarity */
#define PWR_CR4_WP2_Pos (1U)
#define PWR_CR4_WP2_Msk (0x1UL << PWR_CR4_WP2_Pos) /*!< 0x00000002 */
#define PWR_CR4_WP2 PWR_CR4_WP2_Msk /*!< Wake-Up Pin 2 polarity */
#define PWR_CR4_WP1_Pos (0U)
#define PWR_CR4_WP1_Msk (0x1UL << PWR_CR4_WP1_Pos) /*!< 0x00000001 */
#define PWR_CR4_WP1 PWR_CR4_WP1_Msk /*!< Wake-Up Pin 1 polarity */
/******************** Bit definition for PWR_SR1 register ********************/
#define PWR_SR1_WUFI_Pos (15U)
#define PWR_SR1_WUFI_Msk (0x1UL << PWR_SR1_WUFI_Pos) /*!< 0x00008000 */
#define PWR_SR1_WUFI PWR_SR1_WUFI_Msk /*!< Wake-Up Flag Internal */
#define PWR_SR1_SBF_Pos (8U)
#define PWR_SR1_SBF_Msk (0x1UL << PWR_SR1_SBF_Pos) /*!< 0x00000100 */
#define PWR_SR1_SBF PWR_SR1_SBF_Msk /*!< Stand-By Flag */
#define PWR_SR1_WUF_Pos (0U)
#define PWR_SR1_WUF_Msk (0x1FUL << PWR_SR1_WUF_Pos) /*!< 0x0000001F */
#define PWR_SR1_WUF PWR_SR1_WUF_Msk /*!< Wake-up Flags */
#define PWR_SR1_WUF5_Pos (4U)
#define PWR_SR1_WUF5_Msk (0x1UL << PWR_SR1_WUF5_Pos) /*!< 0x00000010 */
#define PWR_SR1_WUF5 PWR_SR1_WUF5_Msk /*!< Wake-up Flag 5 */
#define PWR_SR1_WUF4_Pos (3U)
#define PWR_SR1_WUF4_Msk (0x1UL << PWR_SR1_WUF4_Pos) /*!< 0x00000008 */
#define PWR_SR1_WUF4 PWR_SR1_WUF4_Msk /*!< Wake-up Flag 4 */
#define PWR_SR1_WUF3_Pos (2U)
#define PWR_SR1_WUF3_Msk (0x1UL << PWR_SR1_WUF3_Pos) /*!< 0x00000004 */
#define PWR_SR1_WUF3 PWR_SR1_WUF3_Msk /*!< Wake-up Flag 3 */
#define PWR_SR1_WUF2_Pos (1U)
#define PWR_SR1_WUF2_Msk (0x1UL << PWR_SR1_WUF2_Pos) /*!< 0x00000002 */
#define PWR_SR1_WUF2 PWR_SR1_WUF2_Msk /*!< Wake-up Flag 2 */
#define PWR_SR1_WUF1_Pos (0U)
#define PWR_SR1_WUF1_Msk (0x1UL << PWR_SR1_WUF1_Pos) /*!< 0x00000001 */
#define PWR_SR1_WUF1 PWR_SR1_WUF1_Msk /*!< Wake-up Flag 1 */
/******************** Bit definition for PWR_SR2 register ********************/
#define PWR_SR2_PVMO4_Pos (15U)
#define PWR_SR2_PVMO4_Msk (0x1UL << PWR_SR2_PVMO4_Pos) /*!< 0x00008000 */
#define PWR_SR2_PVMO4 PWR_SR2_PVMO4_Msk /*!< Peripheral Voltage Monitoring Output 4 */
#define PWR_SR2_PVMO3_Pos (14U)
#define PWR_SR2_PVMO3_Msk (0x1UL << PWR_SR2_PVMO3_Pos) /*!< 0x00004000 */
#define PWR_SR2_PVMO3 PWR_SR2_PVMO3_Msk /*!< Peripheral Voltage Monitoring Output 3 */
#define PWR_SR2_PVMO2_Pos (13U)
#define PWR_SR2_PVMO2_Msk (0x1UL << PWR_SR2_PVMO2_Pos) /*!< 0x00002000 */
#define PWR_SR2_PVMO2 PWR_SR2_PVMO2_Msk /*!< Peripheral Voltage Monitoring Output 2 */
#define PWR_SR2_PVMO1_Pos (12U)
#define PWR_SR2_PVMO1_Msk (0x1UL << PWR_SR2_PVMO1_Pos) /*!< 0x00001000 */
#define PWR_SR2_PVMO1 PWR_SR2_PVMO1_Msk /*!< Peripheral Voltage Monitoring Output 1 */
#define PWR_SR2_PVDO_Pos (11U)
#define PWR_SR2_PVDO_Msk (0x1UL << PWR_SR2_PVDO_Pos) /*!< 0x00000800 */
#define PWR_SR2_PVDO PWR_SR2_PVDO_Msk /*!< Power Voltage Detector Output */
#define PWR_SR2_VOSF_Pos (10U)
#define PWR_SR2_VOSF_Msk (0x1UL << PWR_SR2_VOSF_Pos) /*!< 0x00000400 */
#define PWR_SR2_VOSF PWR_SR2_VOSF_Msk /*!< Voltage Scaling Flag */
#define PWR_SR2_REGLPF_Pos (9U)
#define PWR_SR2_REGLPF_Msk (0x1UL << PWR_SR2_REGLPF_Pos) /*!< 0x00000200 */
#define PWR_SR2_REGLPF PWR_SR2_REGLPF_Msk /*!< Low-power Regulator Flag */
#define PWR_SR2_REGLPS_Pos (8U)
#define PWR_SR2_REGLPS_Msk (0x1UL << PWR_SR2_REGLPS_Pos) /*!< 0x00000100 */
#define PWR_SR2_REGLPS PWR_SR2_REGLPS_Msk /*!< Low-power Regulator Started */
/******************** Bit definition for PWR_SCR register ********************/
#define PWR_SCR_CSBF_Pos (8U)
#define PWR_SCR_CSBF_Msk (0x1UL << PWR_SCR_CSBF_Pos) /*!< 0x00000100 */
#define PWR_SCR_CSBF PWR_SCR_CSBF_Msk /*!< Clear Stand-By Flag */
#define PWR_SCR_CWUF_Pos (0U)
#define PWR_SCR_CWUF_Msk (0x1FUL << PWR_SCR_CWUF_Pos) /*!< 0x0000001F */
#define PWR_SCR_CWUF PWR_SCR_CWUF_Msk /*!< Clear Wake-up Flags */
#define PWR_SCR_CWUF5_Pos (4U)
#define PWR_SCR_CWUF5_Msk (0x1UL << PWR_SCR_CWUF5_Pos) /*!< 0x00000010 */
#define PWR_SCR_CWUF5 PWR_SCR_CWUF5_Msk /*!< Clear Wake-up Flag 5 */
#define PWR_SCR_CWUF4_Pos (3U)
#define PWR_SCR_CWUF4_Msk (0x1UL << PWR_SCR_CWUF4_Pos) /*!< 0x00000008 */
#define PWR_SCR_CWUF4 PWR_SCR_CWUF4_Msk /*!< Clear Wake-up Flag 4 */
#define PWR_SCR_CWUF3_Pos (2U)
#define PWR_SCR_CWUF3_Msk (0x1UL << PWR_SCR_CWUF3_Pos) /*!< 0x00000004 */
#define PWR_SCR_CWUF3 PWR_SCR_CWUF3_Msk /*!< Clear Wake-up Flag 3 */
#define PWR_SCR_CWUF2_Pos (1U)
#define PWR_SCR_CWUF2_Msk (0x1UL << PWR_SCR_CWUF2_Pos) /*!< 0x00000002 */
#define PWR_SCR_CWUF2 PWR_SCR_CWUF2_Msk /*!< Clear Wake-up Flag 2 */
#define PWR_SCR_CWUF1_Pos (0U)
#define PWR_SCR_CWUF1_Msk (0x1UL << PWR_SCR_CWUF1_Pos) /*!< 0x00000001 */
#define PWR_SCR_CWUF1 PWR_SCR_CWUF1_Msk /*!< Clear Wake-up Flag 1 */
/******************** Bit definition for PWR_PUCRA register ********************/
#define PWR_PUCRA_PA15_Pos (15U)
#define PWR_PUCRA_PA15_Msk (0x1UL << PWR_PUCRA_PA15_Pos) /*!< 0x00008000 */
#define PWR_PUCRA_PA15 PWR_PUCRA_PA15_Msk /*!< Port PA15 Pull-Up set */
#define PWR_PUCRA_PA13_Pos (13U)
#define PWR_PUCRA_PA13_Msk (0x1UL << PWR_PUCRA_PA13_Pos) /*!< 0x00002000 */
#define PWR_PUCRA_PA13 PWR_PUCRA_PA13_Msk /*!< Port PA13 Pull-Up set */
#define PWR_PUCRA_PA12_Pos (12U)
#define PWR_PUCRA_PA12_Msk (0x1UL << PWR_PUCRA_PA12_Pos) /*!< 0x00001000 */
#define PWR_PUCRA_PA12 PWR_PUCRA_PA12_Msk /*!< Port PA12 Pull-Up set */
#define PWR_PUCRA_PA11_Pos (11U)
#define PWR_PUCRA_PA11_Msk (0x1UL << PWR_PUCRA_PA11_Pos) /*!< 0x00000800 */
#define PWR_PUCRA_PA11 PWR_PUCRA_PA11_Msk /*!< Port PA11 Pull-Up set */
#define PWR_PUCRA_PA10_Pos (10U)
#define PWR_PUCRA_PA10_Msk (0x1UL << PWR_PUCRA_PA10_Pos) /*!< 0x00000400 */
#define PWR_PUCRA_PA10 PWR_PUCRA_PA10_Msk /*!< Port PA10 Pull-Up set */
#define PWR_PUCRA_PA9_Pos (9U)
#define PWR_PUCRA_PA9_Msk (0x1UL << PWR_PUCRA_PA9_Pos) /*!< 0x00000200 */
#define PWR_PUCRA_PA9 PWR_PUCRA_PA9_Msk /*!< Port PA9 Pull-Up set */
#define PWR_PUCRA_PA8_Pos (8U)
#define PWR_PUCRA_PA8_Msk (0x1UL << PWR_PUCRA_PA8_Pos) /*!< 0x00000100 */
#define PWR_PUCRA_PA8 PWR_PUCRA_PA8_Msk /*!< Port PA8 Pull-Up set */
#define PWR_PUCRA_PA7_Pos (7U)
#define PWR_PUCRA_PA7_Msk (0x1UL << PWR_PUCRA_PA7_Pos) /*!< 0x00000080 */
#define PWR_PUCRA_PA7 PWR_PUCRA_PA7_Msk /*!< Port PA7 Pull-Up set */
#define PWR_PUCRA_PA6_Pos (6U)
#define PWR_PUCRA_PA6_Msk (0x1UL << PWR_PUCRA_PA6_Pos) /*!< 0x00000040 */
#define PWR_PUCRA_PA6 PWR_PUCRA_PA6_Msk /*!< Port PA6 Pull-Up set */
#define PWR_PUCRA_PA5_Pos (5U)
#define PWR_PUCRA_PA5_Msk (0x1UL << PWR_PUCRA_PA5_Pos) /*!< 0x00000020 */
#define PWR_PUCRA_PA5 PWR_PUCRA_PA5_Msk /*!< Port PA5 Pull-Up set */
#define PWR_PUCRA_PA4_Pos (4U)
#define PWR_PUCRA_PA4_Msk (0x1UL << PWR_PUCRA_PA4_Pos) /*!< 0x00000010 */
#define PWR_PUCRA_PA4 PWR_PUCRA_PA4_Msk /*!< Port PA4 Pull-Up set */
#define PWR_PUCRA_PA3_Pos (3U)
#define PWR_PUCRA_PA3_Msk (0x1UL << PWR_PUCRA_PA3_Pos) /*!< 0x00000008 */
#define PWR_PUCRA_PA3 PWR_PUCRA_PA3_Msk /*!< Port PA3 Pull-Up set */
#define PWR_PUCRA_PA2_Pos (2U)
#define PWR_PUCRA_PA2_Msk (0x1UL << PWR_PUCRA_PA2_Pos) /*!< 0x00000004 */
#define PWR_PUCRA_PA2 PWR_PUCRA_PA2_Msk /*!< Port PA2 Pull-Up set */
#define PWR_PUCRA_PA1_Pos (1U)
#define PWR_PUCRA_PA1_Msk (0x1UL << PWR_PUCRA_PA1_Pos) /*!< 0x00000002 */
#define PWR_PUCRA_PA1 PWR_PUCRA_PA1_Msk /*!< Port PA1 Pull-Up set */
#define PWR_PUCRA_PA0_Pos (0U)
#define PWR_PUCRA_PA0_Msk (0x1UL << PWR_PUCRA_PA0_Pos) /*!< 0x00000001 */
#define PWR_PUCRA_PA0 PWR_PUCRA_PA0_Msk /*!< Port PA0 Pull-Up set */
/******************** Bit definition for PWR_PDCRA register ********************/
#define PWR_PDCRA_PA14_Pos (14U)
#define PWR_PDCRA_PA14_Msk (0x1UL << PWR_PDCRA_PA14_Pos) /*!< 0x00004000 */
#define PWR_PDCRA_PA14 PWR_PDCRA_PA14_Msk /*!< Port PA14 Pull-Down set */
#define PWR_PDCRA_PA12_Pos (12U)
#define PWR_PDCRA_PA12_Msk (0x1UL << PWR_PDCRA_PA12_Pos) /*!< 0x00001000 */
#define PWR_PDCRA_PA12 PWR_PDCRA_PA12_Msk /*!< Port PA12 Pull-Down set */
#define PWR_PDCRA_PA11_Pos (11U)
#define PWR_PDCRA_PA11_Msk (0x1UL << PWR_PDCRA_PA11_Pos) /*!< 0x00000800 */
#define PWR_PDCRA_PA11 PWR_PDCRA_PA11_Msk /*!< Port PA11 Pull-Down set */
#define PWR_PDCRA_PA10_Pos (10U)
#define PWR_PDCRA_PA10_Msk (0x1UL << PWR_PDCRA_PA10_Pos) /*!< 0x00000400 */
#define PWR_PDCRA_PA10 PWR_PDCRA_PA10_Msk /*!< Port PA10 Pull-Down set */
#define PWR_PDCRA_PA9_Pos (9U)
#define PWR_PDCRA_PA9_Msk (0x1UL << PWR_PDCRA_PA9_Pos) /*!< 0x00000200 */
#define PWR_PDCRA_PA9 PWR_PDCRA_PA9_Msk /*!< Port PA9 Pull-Down set */
#define PWR_PDCRA_PA8_Pos (8U)
#define PWR_PDCRA_PA8_Msk (0x1UL << PWR_PDCRA_PA8_Pos) /*!< 0x00000100 */
#define PWR_PDCRA_PA8 PWR_PDCRA_PA8_Msk /*!< Port PA8 Pull-Down set */
#define PWR_PDCRA_PA7_Pos (7U)
#define PWR_PDCRA_PA7_Msk (0x1UL << PWR_PDCRA_PA7_Pos) /*!< 0x00000080 */
#define PWR_PDCRA_PA7 PWR_PDCRA_PA7_Msk /*!< Port PA7 Pull-Down set */
#define PWR_PDCRA_PA6_Pos (6U)
#define PWR_PDCRA_PA6_Msk (0x1UL << PWR_PDCRA_PA6_Pos) /*!< 0x00000040 */
#define PWR_PDCRA_PA6 PWR_PDCRA_PA6_Msk /*!< Port PA6 Pull-Down set */
#define PWR_PDCRA_PA5_Pos (5U)
#define PWR_PDCRA_PA5_Msk (0x1UL << PWR_PDCRA_PA5_Pos) /*!< 0x00000020 */
#define PWR_PDCRA_PA5 PWR_PDCRA_PA5_Msk /*!< Port PA5 Pull-Down set */
#define PWR_PDCRA_PA4_Pos (4U)
#define PWR_PDCRA_PA4_Msk (0x1UL << PWR_PDCRA_PA4_Pos) /*!< 0x00000010 */
#define PWR_PDCRA_PA4 PWR_PDCRA_PA4_Msk /*!< Port PA4 Pull-Down set */
#define PWR_PDCRA_PA3_Pos (3U)
#define PWR_PDCRA_PA3_Msk (0x1UL << PWR_PDCRA_PA3_Pos) /*!< 0x00000008 */
#define PWR_PDCRA_PA3 PWR_PDCRA_PA3_Msk /*!< Port PA3 Pull-Down set */
#define PWR_PDCRA_PA2_Pos (2U)
#define PWR_PDCRA_PA2_Msk (0x1UL << PWR_PDCRA_PA2_Pos) /*!< 0x00000004 */
#define PWR_PDCRA_PA2 PWR_PDCRA_PA2_Msk /*!< Port PA2 Pull-Down set */
#define PWR_PDCRA_PA1_Pos (1U)
#define PWR_PDCRA_PA1_Msk (0x1UL << PWR_PDCRA_PA1_Pos) /*!< 0x00000002 */
#define PWR_PDCRA_PA1 PWR_PDCRA_PA1_Msk /*!< Port PA1 Pull-Down set */
#define PWR_PDCRA_PA0_Pos (0U)
#define PWR_PDCRA_PA0_Msk (0x1UL << PWR_PDCRA_PA0_Pos) /*!< 0x00000001 */
#define PWR_PDCRA_PA0 PWR_PDCRA_PA0_Msk /*!< Port PA0 Pull-Down set */
/******************** Bit definition for PWR_PUCRB register ********************/
#define PWR_PUCRB_PB15_Pos (15U)
#define PWR_PUCRB_PB15_Msk (0x1UL << PWR_PUCRB_PB15_Pos) /*!< 0x00008000 */
#define PWR_PUCRB_PB15 PWR_PUCRB_PB15_Msk /*!< Port PB15 Pull-Up set */
#define PWR_PUCRB_PB14_Pos (14U)
#define PWR_PUCRB_PB14_Msk (0x1UL << PWR_PUCRB_PB14_Pos) /*!< 0x00004000 */
#define PWR_PUCRB_PB14 PWR_PUCRB_PB14_Msk /*!< Port PB14 Pull-Up set */
#define PWR_PUCRB_PB13_Pos (13U)
#define PWR_PUCRB_PB13_Msk (0x1UL << PWR_PUCRB_PB13_Pos) /*!< 0x00002000 */
#define PWR_PUCRB_PB13 PWR_PUCRB_PB13_Msk /*!< Port PB13 Pull-Up set */
#define PWR_PUCRB_PB12_Pos (12U)
#define PWR_PUCRB_PB12_Msk (0x1UL << PWR_PUCRB_PB12_Pos) /*!< 0x00001000 */
#define PWR_PUCRB_PB12 PWR_PUCRB_PB12_Msk /*!< Port PB12 Pull-Up set */
#define PWR_PUCRB_PB11_Pos (11U)
#define PWR_PUCRB_PB11_Msk (0x1UL << PWR_PUCRB_PB11_Pos) /*!< 0x00000800 */
#define PWR_PUCRB_PB11 PWR_PUCRB_PB11_Msk /*!< Port PB11 Pull-Up set */
#define PWR_PUCRB_PB10_Pos (10U)
#define PWR_PUCRB_PB10_Msk (0x1UL << PWR_PUCRB_PB10_Pos) /*!< 0x00000400 */
#define PWR_PUCRB_PB10 PWR_PUCRB_PB10_Msk /*!< Port PB10 Pull-Up set */
#define PWR_PUCRB_PB9_Pos (9U)
#define PWR_PUCRB_PB9_Msk (0x1UL << PWR_PUCRB_PB9_Pos) /*!< 0x00000200 */
#define PWR_PUCRB_PB9 PWR_PUCRB_PB9_Msk /*!< Port PB9 Pull-Up set */
#define PWR_PUCRB_PB8_Pos (8U)
#define PWR_PUCRB_PB8_Msk (0x1UL << PWR_PUCRB_PB8_Pos) /*!< 0x00000100 */
#define PWR_PUCRB_PB8 PWR_PUCRB_PB8_Msk /*!< Port PB8 Pull-Up set */
#define PWR_PUCRB_PB7_Pos (7U)
#define PWR_PUCRB_PB7_Msk (0x1UL << PWR_PUCRB_PB7_Pos) /*!< 0x00000080 */
#define PWR_PUCRB_PB7 PWR_PUCRB_PB7_Msk /*!< Port PB7 Pull-Up set */
#define PWR_PUCRB_PB6_Pos (6U)
#define PWR_PUCRB_PB6_Msk (0x1UL << PWR_PUCRB_PB6_Pos) /*!< 0x00000040 */
#define PWR_PUCRB_PB6 PWR_PUCRB_PB6_Msk /*!< Port PB6 Pull-Up set */
#define PWR_PUCRB_PB5_Pos (5U)
#define PWR_PUCRB_PB5_Msk (0x1UL << PWR_PUCRB_PB5_Pos) /*!< 0x00000020 */
#define PWR_PUCRB_PB5 PWR_PUCRB_PB5_Msk /*!< Port PB5 Pull-Up set */
#define PWR_PUCRB_PB4_Pos (4U)
#define PWR_PUCRB_PB4_Msk (0x1UL << PWR_PUCRB_PB4_Pos) /*!< 0x00000010 */
#define PWR_PUCRB_PB4 PWR_PUCRB_PB4_Msk /*!< Port PB4 Pull-Up set */
#define PWR_PUCRB_PB3_Pos (3U)
#define PWR_PUCRB_PB3_Msk (0x1UL << PWR_PUCRB_PB3_Pos) /*!< 0x00000008 */
#define PWR_PUCRB_PB3 PWR_PUCRB_PB3_Msk /*!< Port PB3 Pull-Up set */
#define PWR_PUCRB_PB2_Pos (2U)
#define PWR_PUCRB_PB2_Msk (0x1UL << PWR_PUCRB_PB2_Pos) /*!< 0x00000004 */
#define PWR_PUCRB_PB2 PWR_PUCRB_PB2_Msk /*!< Port PB2 Pull-Up set */
#define PWR_PUCRB_PB1_Pos (1U)
#define PWR_PUCRB_PB1_Msk (0x1UL << PWR_PUCRB_PB1_Pos) /*!< 0x00000002 */
#define PWR_PUCRB_PB1 PWR_PUCRB_PB1_Msk /*!< Port PB1 Pull-Up set */
#define PWR_PUCRB_PB0_Pos (0U)
#define PWR_PUCRB_PB0_Msk (0x1UL << PWR_PUCRB_PB0_Pos) /*!< 0x00000001 */
#define PWR_PUCRB_PB0 PWR_PUCRB_PB0_Msk /*!< Port PB0 Pull-Up set */
/******************** Bit definition for PWR_PDCRB register ********************/
#define PWR_PDCRB_PB15_Pos (15U)
#define PWR_PDCRB_PB15_Msk (0x1UL << PWR_PDCRB_PB15_Pos) /*!< 0x00008000 */
#define PWR_PDCRB_PB15 PWR_PDCRB_PB15_Msk /*!< Port PB15 Pull-Down set */
#define PWR_PDCRB_PB14_Pos (14U)
#define PWR_PDCRB_PB14_Msk (0x1UL << PWR_PDCRB_PB14_Pos) /*!< 0x00004000 */
#define PWR_PDCRB_PB14 PWR_PDCRB_PB14_Msk /*!< Port PB14 Pull-Down set */
#define PWR_PDCRB_PB13_Pos (13U)
#define PWR_PDCRB_PB13_Msk (0x1UL << PWR_PDCRB_PB13_Pos) /*!< 0x00002000 */
#define PWR_PDCRB_PB13 PWR_PDCRB_PB13_Msk /*!< Port PB13 Pull-Down set */
#define PWR_PDCRB_PB12_Pos (12U)
#define PWR_PDCRB_PB12_Msk (0x1UL << PWR_PDCRB_PB12_Pos) /*!< 0x00001000 */
#define PWR_PDCRB_PB12 PWR_PDCRB_PB12_Msk /*!< Port PB12 Pull-Down set */
#define PWR_PDCRB_PB11_Pos (11U)
#define PWR_PDCRB_PB11_Msk (0x1UL << PWR_PDCRB_PB11_Pos) /*!< 0x00000800 */
#define PWR_PDCRB_PB11 PWR_PDCRB_PB11_Msk /*!< Port PB11 Pull-Down set */
#define PWR_PDCRB_PB10_Pos (10U)
#define PWR_PDCRB_PB10_Msk (0x1UL << PWR_PDCRB_PB10_Pos) /*!< 0x00000400 */
#define PWR_PDCRB_PB10 PWR_PDCRB_PB10_Msk /*!< Port PB10 Pull-Down set */
#define PWR_PDCRB_PB9_Pos (9U)
#define PWR_PDCRB_PB9_Msk (0x1UL << PWR_PDCRB_PB9_Pos) /*!< 0x00000200 */
#define PWR_PDCRB_PB9 PWR_PDCRB_PB9_Msk /*!< Port PB9 Pull-Down set */
#define PWR_PDCRB_PB8_Pos (8U)
#define PWR_PDCRB_PB8_Msk (0x1UL << PWR_PDCRB_PB8_Pos) /*!< 0x00000100 */
#define PWR_PDCRB_PB8 PWR_PDCRB_PB8_Msk /*!< Port PB8 Pull-Down set */
#define PWR_PDCRB_PB7_Pos (7U)
#define PWR_PDCRB_PB7_Msk (0x1UL << PWR_PDCRB_PB7_Pos) /*!< 0x00000080 */
#define PWR_PDCRB_PB7 PWR_PDCRB_PB7_Msk /*!< Port PB7 Pull-Down set */
#define PWR_PDCRB_PB6_Pos (6U)
#define PWR_PDCRB_PB6_Msk (0x1UL << PWR_PDCRB_PB6_Pos) /*!< 0x00000040 */
#define PWR_PDCRB_PB6 PWR_PDCRB_PB6_Msk /*!< Port PB6 Pull-Down set */
#define PWR_PDCRB_PB5_Pos (5U)
#define PWR_PDCRB_PB5_Msk (0x1UL << PWR_PDCRB_PB5_Pos) /*!< 0x00000020 */
#define PWR_PDCRB_PB5 PWR_PDCRB_PB5_Msk /*!< Port PB5 Pull-Down set */
#define PWR_PDCRB_PB3_Pos (3U)
#define PWR_PDCRB_PB3_Msk (0x1UL << PWR_PDCRB_PB3_Pos) /*!< 0x00000008 */
#define PWR_PDCRB_PB3 PWR_PDCRB_PB3_Msk /*!< Port PB3 Pull-Down set */
#define PWR_PDCRB_PB2_Pos (2U)
#define PWR_PDCRB_PB2_Msk (0x1UL << PWR_PDCRB_PB2_Pos) /*!< 0x00000004 */
#define PWR_PDCRB_PB2 PWR_PDCRB_PB2_Msk /*!< Port PB2 Pull-Down set */
#define PWR_PDCRB_PB1_Pos (1U)
#define PWR_PDCRB_PB1_Msk (0x1UL << PWR_PDCRB_PB1_Pos) /*!< 0x00000002 */
#define PWR_PDCRB_PB1 PWR_PDCRB_PB1_Msk /*!< Port PB1 Pull-Down set */
#define PWR_PDCRB_PB0_Pos (0U)
#define PWR_PDCRB_PB0_Msk (0x1UL << PWR_PDCRB_PB0_Pos) /*!< 0x00000001 */
#define PWR_PDCRB_PB0 PWR_PDCRB_PB0_Msk /*!< Port PB0 Pull-Down set */
/******************** Bit definition for PWR_PUCRC register ********************/
#define PWR_PUCRC_PC15_Pos (15U)
#define PWR_PUCRC_PC15_Msk (0x1UL << PWR_PUCRC_PC15_Pos) /*!< 0x00008000 */
#define PWR_PUCRC_PC15 PWR_PUCRC_PC15_Msk /*!< Port PC15 Pull-Up set */
#define PWR_PUCRC_PC14_Pos (14U)
#define PWR_PUCRC_PC14_Msk (0x1UL << PWR_PUCRC_PC14_Pos) /*!< 0x00004000 */
#define PWR_PUCRC_PC14 PWR_PUCRC_PC14_Msk /*!< Port PC14 Pull-Up set */
#define PWR_PUCRC_PC13_Pos (13U)
#define PWR_PUCRC_PC13_Msk (0x1UL << PWR_PUCRC_PC13_Pos) /*!< 0x00002000 */
#define PWR_PUCRC_PC13 PWR_PUCRC_PC13_Msk /*!< Port PC13 Pull-Up set */
#define PWR_PUCRC_PC12_Pos (12U)
#define PWR_PUCRC_PC12_Msk (0x1UL << PWR_PUCRC_PC12_Pos) /*!< 0x00001000 */
#define PWR_PUCRC_PC12 PWR_PUCRC_PC12_Msk /*!< Port PC12 Pull-Up set */
#define PWR_PUCRC_PC11_Pos (11U)
#define PWR_PUCRC_PC11_Msk (0x1UL << PWR_PUCRC_PC11_Pos) /*!< 0x00000800 */
#define PWR_PUCRC_PC11 PWR_PUCRC_PC11_Msk /*!< Port PC11 Pull-Up set */
#define PWR_PUCRC_PC10_Pos (10U)
#define PWR_PUCRC_PC10_Msk (0x1UL << PWR_PUCRC_PC10_Pos) /*!< 0x00000400 */
#define PWR_PUCRC_PC10 PWR_PUCRC_PC10_Msk /*!< Port PC10 Pull-Up set */
#define PWR_PUCRC_PC9_Pos (9U)
#define PWR_PUCRC_PC9_Msk (0x1UL << PWR_PUCRC_PC9_Pos) /*!< 0x00000200 */
#define PWR_PUCRC_PC9 PWR_PUCRC_PC9_Msk /*!< Port PC9 Pull-Up set */
#define PWR_PUCRC_PC8_Pos (8U)
#define PWR_PUCRC_PC8_Msk (0x1UL << PWR_PUCRC_PC8_Pos) /*!< 0x00000100 */
#define PWR_PUCRC_PC8 PWR_PUCRC_PC8_Msk /*!< Port PC8 Pull-Up set */
#define PWR_PUCRC_PC7_Pos (7U)
#define PWR_PUCRC_PC7_Msk (0x1UL << PWR_PUCRC_PC7_Pos) /*!< 0x00000080 */
#define PWR_PUCRC_PC7 PWR_PUCRC_PC7_Msk /*!< Port PC7 Pull-Up set */
#define PWR_PUCRC_PC6_Pos (6U)
#define PWR_PUCRC_PC6_Msk (0x1UL << PWR_PUCRC_PC6_Pos) /*!< 0x00000040 */
#define PWR_PUCRC_PC6 PWR_PUCRC_PC6_Msk /*!< Port PC6 Pull-Up set */
#define PWR_PUCRC_PC5_Pos (5U)
#define PWR_PUCRC_PC5_Msk (0x1UL << PWR_PUCRC_PC5_Pos) /*!< 0x00000020 */
#define PWR_PUCRC_PC5 PWR_PUCRC_PC5_Msk /*!< Port PC5 Pull-Up set */
#define PWR_PUCRC_PC4_Pos (4U)
#define PWR_PUCRC_PC4_Msk (0x1UL << PWR_PUCRC_PC4_Pos) /*!< 0x00000010 */
#define PWR_PUCRC_PC4 PWR_PUCRC_PC4_Msk /*!< Port PC4 Pull-Up set */
#define PWR_PUCRC_PC3_Pos (3U)
#define PWR_PUCRC_PC3_Msk (0x1UL << PWR_PUCRC_PC3_Pos) /*!< 0x00000008 */
#define PWR_PUCRC_PC3 PWR_PUCRC_PC3_Msk /*!< Port PC3 Pull-Up set */
#define PWR_PUCRC_PC2_Pos (2U)
#define PWR_PUCRC_PC2_Msk (0x1UL << PWR_PUCRC_PC2_Pos) /*!< 0x00000004 */
#define PWR_PUCRC_PC2 PWR_PUCRC_PC2_Msk /*!< Port PC2 Pull-Up set */
#define PWR_PUCRC_PC1_Pos (1U)
#define PWR_PUCRC_PC1_Msk (0x1UL << PWR_PUCRC_PC1_Pos) /*!< 0x00000002 */
#define PWR_PUCRC_PC1 PWR_PUCRC_PC1_Msk /*!< Port PC1 Pull-Up set */
#define PWR_PUCRC_PC0_Pos (0U)
#define PWR_PUCRC_PC0_Msk (0x1UL << PWR_PUCRC_PC0_Pos) /*!< 0x00000001 */
#define PWR_PUCRC_PC0 PWR_PUCRC_PC0_Msk /*!< Port PC0 Pull-Up set */
/******************** Bit definition for PWR_PDCRC register ********************/
#define PWR_PDCRC_PC15_Pos (15U)
#define PWR_PDCRC_PC15_Msk (0x1UL << PWR_PDCRC_PC15_Pos) /*!< 0x00008000 */
#define PWR_PDCRC_PC15 PWR_PDCRC_PC15_Msk /*!< Port PC15 Pull-Down set */
#define PWR_PDCRC_PC14_Pos (14U)
#define PWR_PDCRC_PC14_Msk (0x1UL << PWR_PDCRC_PC14_Pos) /*!< 0x00004000 */
#define PWR_PDCRC_PC14 PWR_PDCRC_PC14_Msk /*!< Port PC14 Pull-Down set */
#define PWR_PDCRC_PC13_Pos (13U)
#define PWR_PDCRC_PC13_Msk (0x1UL << PWR_PDCRC_PC13_Pos) /*!< 0x00002000 */
#define PWR_PDCRC_PC13 PWR_PDCRC_PC13_Msk /*!< Port PC13 Pull-Down set */
#define PWR_PDCRC_PC12_Pos (12U)
#define PWR_PDCRC_PC12_Msk (0x1UL << PWR_PDCRC_PC12_Pos) /*!< 0x00001000 */
#define PWR_PDCRC_PC12 PWR_PDCRC_PC12_Msk /*!< Port PC12 Pull-Down set */
#define PWR_PDCRC_PC11_Pos (11U)
#define PWR_PDCRC_PC11_Msk (0x1UL << PWR_PDCRC_PC11_Pos) /*!< 0x00000800 */
#define PWR_PDCRC_PC11 PWR_PDCRC_PC11_Msk /*!< Port PC11 Pull-Down set */
#define PWR_PDCRC_PC10_Pos (10U)
#define PWR_PDCRC_PC10_Msk (0x1UL << PWR_PDCRC_PC10_Pos) /*!< 0x00000400 */
#define PWR_PDCRC_PC10 PWR_PDCRC_PC10_Msk /*!< Port PC10 Pull-Down set */
#define PWR_PDCRC_PC9_Pos (9U)
#define PWR_PDCRC_PC9_Msk (0x1UL << PWR_PDCRC_PC9_Pos) /*!< 0x00000200 */
#define PWR_PDCRC_PC9 PWR_PDCRC_PC9_Msk /*!< Port PC9 Pull-Down set */
#define PWR_PDCRC_PC8_Pos (8U)
#define PWR_PDCRC_PC8_Msk (0x1UL << PWR_PDCRC_PC8_Pos) /*!< 0x00000100 */
#define PWR_PDCRC_PC8 PWR_PDCRC_PC8_Msk /*!< Port PC8 Pull-Down set */
#define PWR_PDCRC_PC7_Pos (7U)
#define PWR_PDCRC_PC7_Msk (0x1UL << PWR_PDCRC_PC7_Pos) /*!< 0x00000080 */
#define PWR_PDCRC_PC7 PWR_PDCRC_PC7_Msk /*!< Port PC7 Pull-Down set */
#define PWR_PDCRC_PC6_Pos (6U)
#define PWR_PDCRC_PC6_Msk (0x1UL << PWR_PDCRC_PC6_Pos) /*!< 0x00000040 */
#define PWR_PDCRC_PC6 PWR_PDCRC_PC6_Msk /*!< Port PC6 Pull-Down set */
#define PWR_PDCRC_PC5_Pos (5U)
#define PWR_PDCRC_PC5_Msk (0x1UL << PWR_PDCRC_PC5_Pos) /*!< 0x00000020 */
#define PWR_PDCRC_PC5 PWR_PDCRC_PC5_Msk /*!< Port PC5 Pull-Down set */
#define PWR_PDCRC_PC4_Pos (4U)
#define PWR_PDCRC_PC4_Msk (0x1UL << PWR_PDCRC_PC4_Pos) /*!< 0x00000010 */
#define PWR_PDCRC_PC4 PWR_PDCRC_PC4_Msk /*!< Port PC4 Pull-Down set */
#define PWR_PDCRC_PC3_Pos (3U)
#define PWR_PDCRC_PC3_Msk (0x1UL << PWR_PDCRC_PC3_Pos) /*!< 0x00000008 */
#define PWR_PDCRC_PC3 PWR_PDCRC_PC3_Msk /*!< Port PC3 Pull-Down set */
#define PWR_PDCRC_PC2_Pos (2U)
#define PWR_PDCRC_PC2_Msk (0x1UL << PWR_PDCRC_PC2_Pos) /*!< 0x00000004 */
#define PWR_PDCRC_PC2 PWR_PDCRC_PC2_Msk /*!< Port PC2 Pull-Down set */
#define PWR_PDCRC_PC1_Pos (1U)
#define PWR_PDCRC_PC1_Msk (0x1UL << PWR_PDCRC_PC1_Pos) /*!< 0x00000002 */
#define PWR_PDCRC_PC1 PWR_PDCRC_PC1_Msk /*!< Port PC1 Pull-Down set */
#define PWR_PDCRC_PC0_Pos (0U)
#define PWR_PDCRC_PC0_Msk (0x1UL << PWR_PDCRC_PC0_Pos) /*!< 0x00000001 */
#define PWR_PDCRC_PC0 PWR_PDCRC_PC0_Msk /*!< Port PC0 Pull-Down set */
/******************** Bit definition for PWR_PUCRD register ********************/
#define PWR_PUCRD_PD15_Pos (15U)
#define PWR_PUCRD_PD15_Msk (0x1UL << PWR_PUCRD_PD15_Pos) /*!< 0x00008000 */
#define PWR_PUCRD_PD15 PWR_PUCRD_PD15_Msk /*!< Port PD15 Pull-Up set */
#define PWR_PUCRD_PD14_Pos (14U)
#define PWR_PUCRD_PD14_Msk (0x1UL << PWR_PUCRD_PD14_Pos) /*!< 0x00004000 */
#define PWR_PUCRD_PD14 PWR_PUCRD_PD14_Msk /*!< Port PD14 Pull-Up set */
#define PWR_PUCRD_PD13_Pos (13U)
#define PWR_PUCRD_PD13_Msk (0x1UL << PWR_PUCRD_PD13_Pos) /*!< 0x00002000 */
#define PWR_PUCRD_PD13 PWR_PUCRD_PD13_Msk /*!< Port PD13 Pull-Up set */
#define PWR_PUCRD_PD12_Pos (12U)
#define PWR_PUCRD_PD12_Msk (0x1UL << PWR_PUCRD_PD12_Pos) /*!< 0x00001000 */
#define PWR_PUCRD_PD12 PWR_PUCRD_PD12_Msk /*!< Port PD12 Pull-Up set */
#define PWR_PUCRD_PD11_Pos (11U)
#define PWR_PUCRD_PD11_Msk (0x1UL << PWR_PUCRD_PD11_Pos) /*!< 0x00000800 */
#define PWR_PUCRD_PD11 PWR_PUCRD_PD11_Msk /*!< Port PD11 Pull-Up set */
#define PWR_PUCRD_PD10_Pos (10U)
#define PWR_PUCRD_PD10_Msk (0x1UL << PWR_PUCRD_PD10_Pos) /*!< 0x00000400 */
#define PWR_PUCRD_PD10 PWR_PUCRD_PD10_Msk /*!< Port PD10 Pull-Up set */
#define PWR_PUCRD_PD9_Pos (9U)
#define PWR_PUCRD_PD9_Msk (0x1UL << PWR_PUCRD_PD9_Pos) /*!< 0x00000200 */
#define PWR_PUCRD_PD9 PWR_PUCRD_PD9_Msk /*!< Port PD9 Pull-Up set */
#define PWR_PUCRD_PD8_Pos (8U)
#define PWR_PUCRD_PD8_Msk (0x1UL << PWR_PUCRD_PD8_Pos) /*!< 0x00000100 */
#define PWR_PUCRD_PD8 PWR_PUCRD_PD8_Msk /*!< Port PD8 Pull-Up set */
#define PWR_PUCRD_PD7_Pos (7U)
#define PWR_PUCRD_PD7_Msk (0x1UL << PWR_PUCRD_PD7_Pos) /*!< 0x00000080 */
#define PWR_PUCRD_PD7 PWR_PUCRD_PD7_Msk /*!< Port PD7 Pull-Up set */
#define PWR_PUCRD_PD6_Pos (6U)
#define PWR_PUCRD_PD6_Msk (0x1UL << PWR_PUCRD_PD6_Pos) /*!< 0x00000040 */
#define PWR_PUCRD_PD6 PWR_PUCRD_PD6_Msk /*!< Port PD6 Pull-Up set */
#define PWR_PUCRD_PD5_Pos (5U)
#define PWR_PUCRD_PD5_Msk (0x1UL << PWR_PUCRD_PD5_Pos) /*!< 0x00000020 */
#define PWR_PUCRD_PD5 PWR_PUCRD_PD5_Msk /*!< Port PD5 Pull-Up set */
#define PWR_PUCRD_PD4_Pos (4U)
#define PWR_PUCRD_PD4_Msk (0x1UL << PWR_PUCRD_PD4_Pos) /*!< 0x00000010 */
#define PWR_PUCRD_PD4 PWR_PUCRD_PD4_Msk /*!< Port PD4 Pull-Up set */
#define PWR_PUCRD_PD3_Pos (3U)
#define PWR_PUCRD_PD3_Msk (0x1UL << PWR_PUCRD_PD3_Pos) /*!< 0x00000008 */
#define PWR_PUCRD_PD3 PWR_PUCRD_PD3_Msk /*!< Port PD3 Pull-Up set */
#define PWR_PUCRD_PD2_Pos (2U)
#define PWR_PUCRD_PD2_Msk (0x1UL << PWR_PUCRD_PD2_Pos) /*!< 0x00000004 */
#define PWR_PUCRD_PD2 PWR_PUCRD_PD2_Msk /*!< Port PD2 Pull-Up set */
#define PWR_PUCRD_PD1_Pos (1U)
#define PWR_PUCRD_PD1_Msk (0x1UL << PWR_PUCRD_PD1_Pos) /*!< 0x00000002 */
#define PWR_PUCRD_PD1 PWR_PUCRD_PD1_Msk /*!< Port PD1 Pull-Up set */
#define PWR_PUCRD_PD0_Pos (0U)
#define PWR_PUCRD_PD0_Msk (0x1UL << PWR_PUCRD_PD0_Pos) /*!< 0x00000001 */
#define PWR_PUCRD_PD0 PWR_PUCRD_PD0_Msk /*!< Port PD0 Pull-Up set */
/******************** Bit definition for PWR_PDCRD register ********************/
#define PWR_PDCRD_PD15_Pos (15U)
#define PWR_PDCRD_PD15_Msk (0x1UL << PWR_PDCRD_PD15_Pos) /*!< 0x00008000 */
#define PWR_PDCRD_PD15 PWR_PDCRD_PD15_Msk /*!< Port PD15 Pull-Down set */
#define PWR_PDCRD_PD14_Pos (14U)
#define PWR_PDCRD_PD14_Msk (0x1UL << PWR_PDCRD_PD14_Pos) /*!< 0x00004000 */
#define PWR_PDCRD_PD14 PWR_PDCRD_PD14_Msk /*!< Port PD14 Pull-Down set */
#define PWR_PDCRD_PD13_Pos (13U)
#define PWR_PDCRD_PD13_Msk (0x1UL << PWR_PDCRD_PD13_Pos) /*!< 0x00002000 */
#define PWR_PDCRD_PD13 PWR_PDCRD_PD13_Msk /*!< Port PD13 Pull-Down set */
#define PWR_PDCRD_PD12_Pos (12U)
#define PWR_PDCRD_PD12_Msk (0x1UL << PWR_PDCRD_PD12_Pos) /*!< 0x00001000 */
#define PWR_PDCRD_PD12 PWR_PDCRD_PD12_Msk /*!< Port PD12 Pull-Down set */
#define PWR_PDCRD_PD11_Pos (11U)
#define PWR_PDCRD_PD11_Msk (0x1UL << PWR_PDCRD_PD11_Pos) /*!< 0x00000800 */
#define PWR_PDCRD_PD11 PWR_PDCRD_PD11_Msk /*!< Port PD11 Pull-Down set */
#define PWR_PDCRD_PD10_Pos (10U)
#define PWR_PDCRD_PD10_Msk (0x1UL << PWR_PDCRD_PD10_Pos) /*!< 0x00000400 */
#define PWR_PDCRD_PD10 PWR_PDCRD_PD10_Msk /*!< Port PD10 Pull-Down set */
#define PWR_PDCRD_PD9_Pos (9U)
#define PWR_PDCRD_PD9_Msk (0x1UL << PWR_PDCRD_PD9_Pos) /*!< 0x00000200 */
#define PWR_PDCRD_PD9 PWR_PDCRD_PD9_Msk /*!< Port PD9 Pull-Down set */
#define PWR_PDCRD_PD8_Pos (8U)
#define PWR_PDCRD_PD8_Msk (0x1UL << PWR_PDCRD_PD8_Pos) /*!< 0x00000100 */
#define PWR_PDCRD_PD8 PWR_PDCRD_PD8_Msk /*!< Port PD8 Pull-Down set */
#define PWR_PDCRD_PD7_Pos (7U)
#define PWR_PDCRD_PD7_Msk (0x1UL << PWR_PDCRD_PD7_Pos) /*!< 0x00000080 */
#define PWR_PDCRD_PD7 PWR_PDCRD_PD7_Msk /*!< Port PD7 Pull-Down set */
#define PWR_PDCRD_PD6_Pos (6U)
#define PWR_PDCRD_PD6_Msk (0x1UL << PWR_PDCRD_PD6_Pos) /*!< 0x00000040 */
#define PWR_PDCRD_PD6 PWR_PDCRD_PD6_Msk /*!< Port PD6 Pull-Down set */
#define PWR_PDCRD_PD5_Pos (5U)
#define PWR_PDCRD_PD5_Msk (0x1UL << PWR_PDCRD_PD5_Pos) /*!< 0x00000020 */
#define PWR_PDCRD_PD5 PWR_PDCRD_PD5_Msk /*!< Port PD5 Pull-Down set */
#define PWR_PDCRD_PD4_Pos (4U)
#define PWR_PDCRD_PD4_Msk (0x1UL << PWR_PDCRD_PD4_Pos) /*!< 0x00000010 */
#define PWR_PDCRD_PD4 PWR_PDCRD_PD4_Msk /*!< Port PD4 Pull-Down set */
#define PWR_PDCRD_PD3_Pos (3U)
#define PWR_PDCRD_PD3_Msk (0x1UL << PWR_PDCRD_PD3_Pos) /*!< 0x00000008 */
#define PWR_PDCRD_PD3 PWR_PDCRD_PD3_Msk /*!< Port PD3 Pull-Down set */
#define PWR_PDCRD_PD2_Pos (2U)
#define PWR_PDCRD_PD2_Msk (0x1UL << PWR_PDCRD_PD2_Pos) /*!< 0x00000004 */
#define PWR_PDCRD_PD2 PWR_PDCRD_PD2_Msk /*!< Port PD2 Pull-Down set */
#define PWR_PDCRD_PD1_Pos (1U)
#define PWR_PDCRD_PD1_Msk (0x1UL << PWR_PDCRD_PD1_Pos) /*!< 0x00000002 */
#define PWR_PDCRD_PD1 PWR_PDCRD_PD1_Msk /*!< Port PD1 Pull-Down set */
#define PWR_PDCRD_PD0_Pos (0U)
#define PWR_PDCRD_PD0_Msk (0x1UL << PWR_PDCRD_PD0_Pos) /*!< 0x00000001 */
#define PWR_PDCRD_PD0 PWR_PDCRD_PD0_Msk /*!< Port PD0 Pull-Down set */
/******************** Bit definition for PWR_PUCRE register ********************/
#define PWR_PUCRE_PE15_Pos (15U)
#define PWR_PUCRE_PE15_Msk (0x1UL << PWR_PUCRE_PE15_Pos) /*!< 0x00008000 */
#define PWR_PUCRE_PE15 PWR_PUCRE_PE15_Msk /*!< Port PE15 Pull-Up set */
#define PWR_PUCRE_PE14_Pos (14U)
#define PWR_PUCRE_PE14_Msk (0x1UL << PWR_PUCRE_PE14_Pos) /*!< 0x00004000 */
#define PWR_PUCRE_PE14 PWR_PUCRE_PE14_Msk /*!< Port PE14 Pull-Up set */
#define PWR_PUCRE_PE13_Pos (13U)
#define PWR_PUCRE_PE13_Msk (0x1UL << PWR_PUCRE_PE13_Pos) /*!< 0x00002000 */
#define PWR_PUCRE_PE13 PWR_PUCRE_PE13_Msk /*!< Port PE13 Pull-Up set */
#define PWR_PUCRE_PE12_Pos (12U)
#define PWR_PUCRE_PE12_Msk (0x1UL << PWR_PUCRE_PE12_Pos) /*!< 0x00001000 */
#define PWR_PUCRE_PE12 PWR_PUCRE_PE12_Msk /*!< Port PE12 Pull-Up set */
#define PWR_PUCRE_PE11_Pos (11U)
#define PWR_PUCRE_PE11_Msk (0x1UL << PWR_PUCRE_PE11_Pos) /*!< 0x00000800 */
#define PWR_PUCRE_PE11 PWR_PUCRE_PE11_Msk /*!< Port PE11 Pull-Up set */
#define PWR_PUCRE_PE10_Pos (10U)
#define PWR_PUCRE_PE10_Msk (0x1UL << PWR_PUCRE_PE10_Pos) /*!< 0x00000400 */
#define PWR_PUCRE_PE10 PWR_PUCRE_PE10_Msk /*!< Port PE10 Pull-Up set */
#define PWR_PUCRE_PE9_Pos (9U)
#define PWR_PUCRE_PE9_Msk (0x1UL << PWR_PUCRE_PE9_Pos) /*!< 0x00000200 */
#define PWR_PUCRE_PE9 PWR_PUCRE_PE9_Msk /*!< Port PE9 Pull-Up set */
#define PWR_PUCRE_PE8_Pos (8U)
#define PWR_PUCRE_PE8_Msk (0x1UL << PWR_PUCRE_PE8_Pos) /*!< 0x00000100 */
#define PWR_PUCRE_PE8 PWR_PUCRE_PE8_Msk /*!< Port PE8 Pull-Up set */
#define PWR_PUCRE_PE7_Pos (7U)
#define PWR_PUCRE_PE7_Msk (0x1UL << PWR_PUCRE_PE7_Pos) /*!< 0x00000080 */
#define PWR_PUCRE_PE7 PWR_PUCRE_PE7_Msk /*!< Port PE7 Pull-Up set */
#define PWR_PUCRE_PE6_Pos (6U)
#define PWR_PUCRE_PE6_Msk (0x1UL << PWR_PUCRE_PE6_Pos) /*!< 0x00000040 */
#define PWR_PUCRE_PE6 PWR_PUCRE_PE6_Msk /*!< Port PE6 Pull-Up set */
#define PWR_PUCRE_PE5_Pos (5U)
#define PWR_PUCRE_PE5_Msk (0x1UL << PWR_PUCRE_PE5_Pos) /*!< 0x00000020 */
#define PWR_PUCRE_PE5 PWR_PUCRE_PE5_Msk /*!< Port PE5 Pull-Up set */
#define PWR_PUCRE_PE4_Pos (4U)
#define PWR_PUCRE_PE4_Msk (0x1UL << PWR_PUCRE_PE4_Pos) /*!< 0x00000010 */
#define PWR_PUCRE_PE4 PWR_PUCRE_PE4_Msk /*!< Port PE4 Pull-Up set */
#define PWR_PUCRE_PE3_Pos (3U)
#define PWR_PUCRE_PE3_Msk (0x1UL << PWR_PUCRE_PE3_Pos) /*!< 0x00000008 */
#define PWR_PUCRE_PE3 PWR_PUCRE_PE3_Msk /*!< Port PE3 Pull-Up set */
#define PWR_PUCRE_PE2_Pos (2U)
#define PWR_PUCRE_PE2_Msk (0x1UL << PWR_PUCRE_PE2_Pos) /*!< 0x00000004 */
#define PWR_PUCRE_PE2 PWR_PUCRE_PE2_Msk /*!< Port PE2 Pull-Up set */
#define PWR_PUCRE_PE1_Pos (1U)
#define PWR_PUCRE_PE1_Msk (0x1UL << PWR_PUCRE_PE1_Pos) /*!< 0x00000002 */
#define PWR_PUCRE_PE1 PWR_PUCRE_PE1_Msk /*!< Port PE1 Pull-Up set */
#define PWR_PUCRE_PE0_Pos (0U)
#define PWR_PUCRE_PE0_Msk (0x1UL << PWR_PUCRE_PE0_Pos) /*!< 0x00000001 */
#define PWR_PUCRE_PE0 PWR_PUCRE_PE0_Msk /*!< Port PE0 Pull-Up set */
/******************** Bit definition for PWR_PDCRE register ********************/
#define PWR_PDCRE_PE15_Pos (15U)
#define PWR_PDCRE_PE15_Msk (0x1UL << PWR_PDCRE_PE15_Pos) /*!< 0x00008000 */
#define PWR_PDCRE_PE15 PWR_PDCRE_PE15_Msk /*!< Port PE15 Pull-Down set */
#define PWR_PDCRE_PE14_Pos (14U)
#define PWR_PDCRE_PE14_Msk (0x1UL << PWR_PDCRE_PE14_Pos) /*!< 0x00004000 */
#define PWR_PDCRE_PE14 PWR_PDCRE_PE14_Msk /*!< Port PE14 Pull-Down set */
#define PWR_PDCRE_PE13_Pos (13U)
#define PWR_PDCRE_PE13_Msk (0x1UL << PWR_PDCRE_PE13_Pos) /*!< 0x00002000 */
#define PWR_PDCRE_PE13 PWR_PDCRE_PE13_Msk /*!< Port PE13 Pull-Down set */
#define PWR_PDCRE_PE12_Pos (12U)
#define PWR_PDCRE_PE12_Msk (0x1UL << PWR_PDCRE_PE12_Pos) /*!< 0x00001000 */
#define PWR_PDCRE_PE12 PWR_PDCRE_PE12_Msk /*!< Port PE12 Pull-Down set */
#define PWR_PDCRE_PE11_Pos (11U)
#define PWR_PDCRE_PE11_Msk (0x1UL << PWR_PDCRE_PE11_Pos) /*!< 0x00000800 */
#define PWR_PDCRE_PE11 PWR_PDCRE_PE11_Msk /*!< Port PE11 Pull-Down set */
#define PWR_PDCRE_PE10_Pos (10U)
#define PWR_PDCRE_PE10_Msk (0x1UL << PWR_PDCRE_PE10_Pos) /*!< 0x00000400 */
#define PWR_PDCRE_PE10 PWR_PDCRE_PE10_Msk /*!< Port PE10 Pull-Down set */
#define PWR_PDCRE_PE9_Pos (9U)
#define PWR_PDCRE_PE9_Msk (0x1UL << PWR_PDCRE_PE9_Pos) /*!< 0x00000200 */
#define PWR_PDCRE_PE9 PWR_PDCRE_PE9_Msk /*!< Port PE9 Pull-Down set */
#define PWR_PDCRE_PE8_Pos (8U)
#define PWR_PDCRE_PE8_Msk (0x1UL << PWR_PDCRE_PE8_Pos) /*!< 0x00000100 */
#define PWR_PDCRE_PE8 PWR_PDCRE_PE8_Msk /*!< Port PE8 Pull-Down set */
#define PWR_PDCRE_PE7_Pos (7U)
#define PWR_PDCRE_PE7_Msk (0x1UL << PWR_PDCRE_PE7_Pos) /*!< 0x00000080 */
#define PWR_PDCRE_PE7 PWR_PDCRE_PE7_Msk /*!< Port PE7 Pull-Down set */
#define PWR_PDCRE_PE6_Pos (6U)
#define PWR_PDCRE_PE6_Msk (0x1UL << PWR_PDCRE_PE6_Pos) /*!< 0x00000040 */
#define PWR_PDCRE_PE6 PWR_PDCRE_PE6_Msk /*!< Port PE6 Pull-Down set */
#define PWR_PDCRE_PE5_Pos (5U)
#define PWR_PDCRE_PE5_Msk (0x1UL << PWR_PDCRE_PE5_Pos) /*!< 0x00000020 */
#define PWR_PDCRE_PE5 PWR_PDCRE_PE5_Msk /*!< Port PE5 Pull-Down set */
#define PWR_PDCRE_PE4_Pos (4U)
#define PWR_PDCRE_PE4_Msk (0x1UL << PWR_PDCRE_PE4_Pos) /*!< 0x00000010 */
#define PWR_PDCRE_PE4 PWR_PDCRE_PE4_Msk /*!< Port PE4 Pull-Down set */
#define PWR_PDCRE_PE3_Pos (3U)
#define PWR_PDCRE_PE3_Msk (0x1UL << PWR_PDCRE_PE3_Pos) /*!< 0x00000008 */
#define PWR_PDCRE_PE3 PWR_PDCRE_PE3_Msk /*!< Port PE3 Pull-Down set */
#define PWR_PDCRE_PE2_Pos (2U)
#define PWR_PDCRE_PE2_Msk (0x1UL << PWR_PDCRE_PE2_Pos) /*!< 0x00000004 */
#define PWR_PDCRE_PE2 PWR_PDCRE_PE2_Msk /*!< Port PE2 Pull-Down set */
#define PWR_PDCRE_PE1_Pos (1U)
#define PWR_PDCRE_PE1_Msk (0x1UL << PWR_PDCRE_PE1_Pos) /*!< 0x00000002 */
#define PWR_PDCRE_PE1 PWR_PDCRE_PE1_Msk /*!< Port PE1 Pull-Down set */
#define PWR_PDCRE_PE0_Pos (0U)
#define PWR_PDCRE_PE0_Msk (0x1UL << PWR_PDCRE_PE0_Pos) /*!< 0x00000001 */
#define PWR_PDCRE_PE0 PWR_PDCRE_PE0_Msk /*!< Port PE0 Pull-Down set */
/******************** Bit definition for PWR_PUCRF register ********************/
#define PWR_PUCRF_PF15_Pos (15U)
#define PWR_PUCRF_PF15_Msk (0x1UL << PWR_PUCRF_PF15_Pos) /*!< 0x00008000 */
#define PWR_PUCRF_PF15 PWR_PUCRF_PF15_Msk /*!< Port PF15 Pull-Up set */
#define PWR_PUCRF_PF14_Pos (14U)
#define PWR_PUCRF_PF14_Msk (0x1UL << PWR_PUCRF_PF14_Pos) /*!< 0x00004000 */
#define PWR_PUCRF_PF14 PWR_PUCRF_PF14_Msk /*!< Port PF14 Pull-Up set */
#define PWR_PUCRF_PF13_Pos (13U)
#define PWR_PUCRF_PF13_Msk (0x1UL << PWR_PUCRF_PF13_Pos) /*!< 0x00002000 */
#define PWR_PUCRF_PF13 PWR_PUCRF_PF13_Msk /*!< Port PF13 Pull-Up set */
#define PWR_PUCRF_PF12_Pos (12U)
#define PWR_PUCRF_PF12_Msk (0x1UL << PWR_PUCRF_PF12_Pos) /*!< 0x00001000 */
#define PWR_PUCRF_PF12 PWR_PUCRF_PF12_Msk /*!< Port PF12 Pull-Up set */
#define PWR_PUCRF_PF11_Pos (11U)
#define PWR_PUCRF_PF11_Msk (0x1UL << PWR_PUCRF_PF11_Pos) /*!< 0x00000800 */
#define PWR_PUCRF_PF11 PWR_PUCRF_PF11_Msk /*!< Port PF11 Pull-Up set */
#define PWR_PUCRF_PF10_Pos (10U)
#define PWR_PUCRF_PF10_Msk (0x1UL << PWR_PUCRF_PF10_Pos) /*!< 0x00000400 */
#define PWR_PUCRF_PF10 PWR_PUCRF_PF10_Msk /*!< Port PF10 Pull-Up set */
#define PWR_PUCRF_PF9_Pos (9U)
#define PWR_PUCRF_PF9_Msk (0x1UL << PWR_PUCRF_PF9_Pos) /*!< 0x00000200 */
#define PWR_PUCRF_PF9 PWR_PUCRF_PF9_Msk /*!< Port PF9 Pull-Up set */
#define PWR_PUCRF_PF8_Pos (8U)
#define PWR_PUCRF_PF8_Msk (0x1UL << PWR_PUCRF_PF8_Pos) /*!< 0x00000100 */
#define PWR_PUCRF_PF8 PWR_PUCRF_PF8_Msk /*!< Port PF8 Pull-Up set */
#define PWR_PUCRF_PF7_Pos (7U)
#define PWR_PUCRF_PF7_Msk (0x1UL << PWR_PUCRF_PF7_Pos) /*!< 0x00000080 */
#define PWR_PUCRF_PF7 PWR_PUCRF_PF7_Msk /*!< Port PF7 Pull-Up set */
#define PWR_PUCRF_PF6_Pos (6U)
#define PWR_PUCRF_PF6_Msk (0x1UL << PWR_PUCRF_PF6_Pos) /*!< 0x00000040 */
#define PWR_PUCRF_PF6 PWR_PUCRF_PF6_Msk /*!< Port PF6 Pull-Up set */
#define PWR_PUCRF_PF5_Pos (5U)
#define PWR_PUCRF_PF5_Msk (0x1UL << PWR_PUCRF_PF5_Pos) /*!< 0x00000020 */
#define PWR_PUCRF_PF5 PWR_PUCRF_PF5_Msk /*!< Port PF5 Pull-Up set */
#define PWR_PUCRF_PF4_Pos (4U)
#define PWR_PUCRF_PF4_Msk (0x1UL << PWR_PUCRF_PF4_Pos) /*!< 0x00000010 */
#define PWR_PUCRF_PF4 PWR_PUCRF_PF4_Msk /*!< Port PF4 Pull-Up set */
#define PWR_PUCRF_PF3_Pos (3U)
#define PWR_PUCRF_PF3_Msk (0x1UL << PWR_PUCRF_PF3_Pos) /*!< 0x00000008 */
#define PWR_PUCRF_PF3 PWR_PUCRF_PF3_Msk /*!< Port PF3 Pull-Up set */
#define PWR_PUCRF_PF2_Pos (2U)
#define PWR_PUCRF_PF2_Msk (0x1UL << PWR_PUCRF_PF2_Pos) /*!< 0x00000004 */
#define PWR_PUCRF_PF2 PWR_PUCRF_PF2_Msk /*!< Port PF2 Pull-Up set */
#define PWR_PUCRF_PF1_Pos (1U)
#define PWR_PUCRF_PF1_Msk (0x1UL << PWR_PUCRF_PF1_Pos) /*!< 0x00000002 */
#define PWR_PUCRF_PF1 PWR_PUCRF_PF1_Msk /*!< Port PF1 Pull-Up set */
#define PWR_PUCRF_PF0_Pos (0U)
#define PWR_PUCRF_PF0_Msk (0x1UL << PWR_PUCRF_PF0_Pos) /*!< 0x00000001 */
#define PWR_PUCRF_PF0 PWR_PUCRF_PF0_Msk /*!< Port PF0 Pull-Up set */
/******************** Bit definition for PWR_PDCRF register ********************/
#define PWR_PDCRF_PF10_Pos (10U)
#define PWR_PDCRF_PF10_Msk (0x1UL << PWR_PDCRF_PF10_Pos) /*!< 0x00000400 */
#define PWR_PDCRF_PF10 PWR_PDCRF_PF10_Msk /*!< Port PF10 Pull-Down set */
#define PWR_PDCRF_PF9_Pos (9U)
#define PWR_PDCRF_PF9_Msk (0x1UL << PWR_PDCRF_PF9_Pos) /*!< 0x00000200 */
#define PWR_PDCRF_PF9 PWR_PDCRF_PF9_Msk /*!< Port PF9 Pull-Down set */
#define PWR_PDCRF_PF2_Pos (2U)
#define PWR_PDCRF_PF2_Msk (0x1UL << PWR_PDCRF_PF2_Pos) /*!< 0x00000004 */
#define PWR_PDCRF_PF2 PWR_PDCRF_PF2_Msk /*!< Port PF2 Pull-Down set */
#define PWR_PDCRF_PF1_Pos (1U)
#define PWR_PDCRF_PF1_Msk (0x1UL << PWR_PDCRF_PF1_Pos) /*!< 0x00000002 */
#define PWR_PDCRF_PF1 PWR_PDCRF_PF1_Msk /*!< Port PF1 Pull-Down set */
#define PWR_PDCRF_PF0_Pos (0U)
#define PWR_PDCRF_PF0_Msk (0x1UL << PWR_PDCRF_PF0_Pos) /*!< 0x00000001 */
#define PWR_PDCRF_PF0 PWR_PDCRF_PF0_Msk /*!< Port PF0 Pull-Down set */
/******************** Bit definition for PWR_PUCRG register ********************/
#define PWR_PUCRG_PG10_Pos (10U)
#define PWR_PUCRG_PG10_Msk (0x1UL << PWR_PUCRG_PG10_Pos) /*!< 0x00000400 */
#define PWR_PUCRG_PG10 PWR_PUCRG_PG10_Msk /*!< Port PG10 Pull-Up set */
/******************** Bit definition for PWR_PDCRG register ********************/
#define PWR_PDCRG_PG10_Pos (10U)
#define PWR_PDCRG_PG10_Msk (0x1UL << PWR_PDCRG_PG10_Pos) /*!< 0x00000400 */
#define PWR_PDCRG_PG10 PWR_PDCRG_PG10_Msk /*!< Port PG10 Pull-Down set */
#define PWR_PDCRG_PG9_Pos (9U)
#define PWR_PDCRG_PG9_Msk (0x1UL << PWR_PDCRG_PG9_Pos) /*!< 0x00000200 */
#define PWR_PDCRG_PG9 PWR_PDCRG_PG9_Msk /*!< Port PG9 Pull-Down set */
#define PWR_PDCRG_PG8_Pos (8U)
#define PWR_PDCRG_PG8_Msk (0x1UL << PWR_PDCRG_PG8_Pos) /*!< 0x00000100 */
#define PWR_PDCRG_PG8 PWR_PDCRG_PG8_Msk /*!< Port PG8 Pull-Down set */
#define PWR_PDCRG_PG7_Pos (7U)
#define PWR_PDCRG_PG7_Msk (0x1UL << PWR_PDCRG_PG7_Pos) /*!< 0x00000080 */
#define PWR_PDCRG_PG7 PWR_PDCRG_PG7_Msk /*!< Port PG7 Pull-Down set */
#define PWR_PDCRG_PG6_Pos (6U)
#define PWR_PDCRG_PG6_Msk (0x1UL << PWR_PDCRG_PG6_Pos) /*!< 0x00000040 */
#define PWR_PDCRG_PG6 PWR_PDCRG_PG6_Msk /*!< Port PG6 Pull-Down set */
#define PWR_PDCRG_PG5_Pos (5U)
#define PWR_PDCRG_PG5_Msk (0x1UL << PWR_PDCRG_PG5_Pos) /*!< 0x00000020 */
#define PWR_PDCRG_PG5 PWR_PDCRG_PG5_Msk /*!< Port PG5 Pull-Down set */
#define PWR_PDCRG_PG4_Pos (4U)
#define PWR_PDCRG_PG4_Msk (0x1UL << PWR_PDCRG_PG4_Pos) /*!< 0x00000010 */
#define PWR_PDCRG_PG4 PWR_PDCRG_PG4_Msk /*!< Port PG4 Pull-Down set */
#define PWR_PDCRG_PG3_Pos (3U)
#define PWR_PDCRG_PG3_Msk (0x1UL << PWR_PDCRG_PG3_Pos) /*!< 0x00000008 */
#define PWR_PDCRG_PG3 PWR_PDCRG_PG3_Msk /*!< Port PG3 Pull-Down set */
#define PWR_PDCRG_PG2_Pos (2U)
#define PWR_PDCRG_PG2_Msk (0x1UL << PWR_PDCRG_PG2_Pos) /*!< 0x00000004 */
#define PWR_PDCRG_PG2 PWR_PDCRG_PG2_Msk /*!< Port PG2 Pull-Down set */
#define PWR_PDCRG_PG1_Pos (1U)
#define PWR_PDCRG_PG1_Msk (0x1UL << PWR_PDCRG_PG1_Pos) /*!< 0x00000002 */
#define PWR_PDCRG_PG1 PWR_PDCRG_PG1_Msk /*!< Port PG1 Pull-Down set */
#define PWR_PDCRG_PG0_Pos (0U)
#define PWR_PDCRG_PG0_Msk (0x1UL << PWR_PDCRG_PG0_Pos) /*!< 0x00000001 */
#define PWR_PDCRG_PG0 PWR_PDCRG_PG0_Msk /*!< Port PG0 Pull-Down set */
/******************** Bit definition for PWR_CR5 register ********************/
#define PWR_CR5_R1MODE_Pos (8U)
#define PWR_CR5_R1MODE_Msk (0x1U << PWR_CR5_R1MODE_Pos) /*!< 0x00000100 */
#define PWR_CR5_R1MODE PWR_CR5_R1MODE_Msk /*!< selection for Main Regulator in Range1 */
/******************************************************************************/
/* */
/* Reset and Clock Control */
/* */
/******************************************************************************/
/*
* @brief Specific device feature definitions (not present on all devices in the STM32G4 series)
*/
#define RCC_HSI48_SUPPORT
#define RCC_PLLP_DIV_2_31_SUPPORT
/******************** Bit definition for RCC_CR register ********************/
#define RCC_CR_HSION_Pos (8U)
#define RCC_CR_HSION_Msk (0x1UL << RCC_CR_HSION_Pos) /*!< 0x00000100 */
#define RCC_CR_HSION RCC_CR_HSION_Msk /*!< Internal High Speed oscillator (HSI16) clock enable */
#define RCC_CR_HSIKERON_Pos (9U)
#define RCC_CR_HSIKERON_Msk (0x1UL << RCC_CR_HSIKERON_Pos) /*!< 0x00000200 */
#define RCC_CR_HSIKERON RCC_CR_HSIKERON_Msk /*!< Internal High Speed oscillator (HSI16) clock enable for some IPs Kernel */
#define RCC_CR_HSIRDY_Pos (10U)
#define RCC_CR_HSIRDY_Msk (0x1UL << RCC_CR_HSIRDY_Pos) /*!< 0x00000400 */
#define RCC_CR_HSIRDY RCC_CR_HSIRDY_Msk /*!< Internal High Speed oscillator (HSI16) clock ready flag */
#define RCC_CR_HSEON_Pos (16U)
#define RCC_CR_HSEON_Msk (0x1UL << RCC_CR_HSEON_Pos) /*!< 0x00010000 */
#define RCC_CR_HSEON RCC_CR_HSEON_Msk /*!< External High Speed oscillator (HSE) clock enable */
#define RCC_CR_HSERDY_Pos (17U)
#define RCC_CR_HSERDY_Msk (0x1UL << RCC_CR_HSERDY_Pos) /*!< 0x00020000 */
#define RCC_CR_HSERDY RCC_CR_HSERDY_Msk /*!< External High Speed oscillator (HSE) clock ready */
#define RCC_CR_HSEBYP_Pos (18U)
#define RCC_CR_HSEBYP_Msk (0x1UL << RCC_CR_HSEBYP_Pos) /*!< 0x00040000 */
#define RCC_CR_HSEBYP RCC_CR_HSEBYP_Msk /*!< External High Speed oscillator (HSE) clock bypass */
#define RCC_CR_CSSON_Pos (19U)
#define RCC_CR_CSSON_Msk (0x1UL << RCC_CR_CSSON_Pos) /*!< 0x00080000 */
#define RCC_CR_CSSON RCC_CR_CSSON_Msk /*!< HSE Clock Security System enable */
#define RCC_CR_PLLON_Pos (24U)
#define RCC_CR_PLLON_Msk (0x1UL << RCC_CR_PLLON_Pos) /*!< 0x01000000 */
#define RCC_CR_PLLON RCC_CR_PLLON_Msk /*!< System PLL clock enable */
#define RCC_CR_PLLRDY_Pos (25U)
#define RCC_CR_PLLRDY_Msk (0x1UL << RCC_CR_PLLRDY_Pos) /*!< 0x02000000 */
#define RCC_CR_PLLRDY RCC_CR_PLLRDY_Msk /*!< System PLL clock ready */
/******************** Bit definition for RCC_ICSCR register ***************/
/*!< HSICAL configuration */
#define RCC_ICSCR_HSICAL_Pos (16U)
#define RCC_ICSCR_HSICAL_Msk (0xFFUL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00FF0000 */
#define RCC_ICSCR_HSICAL RCC_ICSCR_HSICAL_Msk /*!< HSICAL[7:0] bits */
#define RCC_ICSCR_HSICAL_0 (0x01UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00010000 */
#define RCC_ICSCR_HSICAL_1 (0x02UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00020000 */
#define RCC_ICSCR_HSICAL_2 (0x04UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00040000 */
#define RCC_ICSCR_HSICAL_3 (0x08UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00080000 */
#define RCC_ICSCR_HSICAL_4 (0x10UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00100000 */
#define RCC_ICSCR_HSICAL_5 (0x20UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00200000 */
#define RCC_ICSCR_HSICAL_6 (0x40UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00400000 */
#define RCC_ICSCR_HSICAL_7 (0x80UL << RCC_ICSCR_HSICAL_Pos) /*!< 0x00800000 */
/*!< HSITRIM configuration */
#define RCC_ICSCR_HSITRIM_Pos (24U)
#define RCC_ICSCR_HSITRIM_Msk (0x7FUL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x7F000000 */
#define RCC_ICSCR_HSITRIM RCC_ICSCR_HSITRIM_Msk /*!< HSITRIM[6:0] bits */
#define RCC_ICSCR_HSITRIM_0 (0x01UL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x01000000 */
#define RCC_ICSCR_HSITRIM_1 (0x02UL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x02000000 */
#define RCC_ICSCR_HSITRIM_2 (0x04UL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x04000000 */
#define RCC_ICSCR_HSITRIM_3 (0x08UL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x08000000 */
#define RCC_ICSCR_HSITRIM_4 (0x10UL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x10000000 */
#define RCC_ICSCR_HSITRIM_5 (0x20UL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x20000000 */
#define RCC_ICSCR_HSITRIM_6 (0x40UL << RCC_ICSCR_HSITRIM_Pos) /*!< 0x40000000 */
/******************** Bit definition for RCC_CFGR register ******************/
/*!< SW configuration */
#define RCC_CFGR_SW_Pos (0U)
#define RCC_CFGR_SW_Msk (0x3UL << RCC_CFGR_SW_Pos) /*!< 0x00000003 */
#define RCC_CFGR_SW RCC_CFGR_SW_Msk /*!< SW[1:0] bits (System clock Switch) */
#define RCC_CFGR_SW_0 (0x1UL << RCC_CFGR_SW_Pos) /*!< 0x00000001 */
#define RCC_CFGR_SW_1 (0x2UL << RCC_CFGR_SW_Pos) /*!< 0x00000002 */
#define RCC_CFGR_SW_HSI (0x00000001U) /*!< HSI16 oscillator selection as system clock */
#define RCC_CFGR_SW_HSE (0x00000002U) /*!< HSE oscillator selection as system clock */
#define RCC_CFGR_SW_PLL (0x00000003U) /*!< PLL selection as system clock */
/*!< SWS configuration */
#define RCC_CFGR_SWS_Pos (2U)
#define RCC_CFGR_SWS_Msk (0x3UL << RCC_CFGR_SWS_Pos) /*!< 0x0000000C */
#define RCC_CFGR_SWS RCC_CFGR_SWS_Msk /*!< SWS[1:0] bits (System Clock Switch Status) */
#define RCC_CFGR_SWS_0 (0x1UL << RCC_CFGR_SWS_Pos) /*!< 0x00000004 */
#define RCC_CFGR_SWS_1 (0x2UL << RCC_CFGR_SWS_Pos) /*!< 0x00000008 */
#define RCC_CFGR_SWS_HSI (0x00000004U) /*!< HSI16 oscillator used as system clock */
#define RCC_CFGR_SWS_HSE (0x00000008U) /*!< HSE oscillator used as system clock */
#define RCC_CFGR_SWS_PLL (0x0000000CU) /*!< PLL used as system clock */
/*!< HPRE configuration */
#define RCC_CFGR_HPRE_Pos (4U)
#define RCC_CFGR_HPRE_Msk (0xFUL << RCC_CFGR_HPRE_Pos) /*!< 0x000000F0 */
#define RCC_CFGR_HPRE RCC_CFGR_HPRE_Msk /*!< HPRE[3:0] bits (AHB prescaler) */
#define RCC_CFGR_HPRE_0 (0x1UL << RCC_CFGR_HPRE_Pos) /*!< 0x00000010 */
#define RCC_CFGR_HPRE_1 (0x2UL << RCC_CFGR_HPRE_Pos) /*!< 0x00000020 */
#define RCC_CFGR_HPRE_2 (0x4UL << RCC_CFGR_HPRE_Pos) /*!< 0x00000040 */
#define RCC_CFGR_HPRE_3 (0x8UL << RCC_CFGR_HPRE_Pos) /*!< 0x00000080 */
#define RCC_CFGR_HPRE_DIV1 (0x00000000U) /*!< SYSCLK not divided */
#define RCC_CFGR_HPRE_DIV2 (0x00000080U) /*!< SYSCLK divided by 2 */
#define RCC_CFGR_HPRE_DIV4 (0x00000090U) /*!< SYSCLK divided by 4 */
#define RCC_CFGR_HPRE_DIV8 (0x000000A0U) /*!< SYSCLK divided by 8 */
#define RCC_CFGR_HPRE_DIV16 (0x000000B0U) /*!< SYSCLK divided by 16 */
#define RCC_CFGR_HPRE_DIV64 (0x000000C0U) /*!< SYSCLK divided by 64 */
#define RCC_CFGR_HPRE_DIV128 (0x000000D0U) /*!< SYSCLK divided by 128 */
#define RCC_CFGR_HPRE_DIV256 (0x000000E0U) /*!< SYSCLK divided by 256 */
#define RCC_CFGR_HPRE_DIV512 (0x000000F0U) /*!< SYSCLK divided by 512 */
/*!< PPRE1 configuration */
#define RCC_CFGR_PPRE1_Pos (8U)
#define RCC_CFGR_PPRE1_Msk (0x7UL << RCC_CFGR_PPRE1_Pos) /*!< 0x00000700 */
#define RCC_CFGR_PPRE1 RCC_CFGR_PPRE1_Msk /*!< PRE1[2:0] bits (APB2 prescaler) */
#define RCC_CFGR_PPRE1_0 (0x1UL << RCC_CFGR_PPRE1_Pos) /*!< 0x00000100 */
#define RCC_CFGR_PPRE1_1 (0x2UL << RCC_CFGR_PPRE1_Pos) /*!< 0x00000200 */
#define RCC_CFGR_PPRE1_2 (0x4UL << RCC_CFGR_PPRE1_Pos) /*!< 0x00000400 */
#define RCC_CFGR_PPRE1_DIV1 (0x00000000U) /*!< HCLK not divided */
#define RCC_CFGR_PPRE1_DIV2 (0x00000400U) /*!< HCLK divided by 2 */
#define RCC_CFGR_PPRE1_DIV4 (0x00000500U) /*!< HCLK divided by 4 */
#define RCC_CFGR_PPRE1_DIV8 (0x00000600U) /*!< HCLK divided by 8 */
#define RCC_CFGR_PPRE1_DIV16 (0x00000700U) /*!< HCLK divided by 16 */
/*!< PPRE2 configuration */
#define RCC_CFGR_PPRE2_Pos (11U)
#define RCC_CFGR_PPRE2_Msk (0x7UL << RCC_CFGR_PPRE2_Pos) /*!< 0x00003800 */
#define RCC_CFGR_PPRE2 RCC_CFGR_PPRE2_Msk /*!< PRE2[2:0] bits (APB2 prescaler) */
#define RCC_CFGR_PPRE2_0 (0x1UL << RCC_CFGR_PPRE2_Pos) /*!< 0x00000800 */
#define RCC_CFGR_PPRE2_1 (0x2UL << RCC_CFGR_PPRE2_Pos) /*!< 0x00001000 */
#define RCC_CFGR_PPRE2_2 (0x4UL << RCC_CFGR_PPRE2_Pos) /*!< 0x00002000 */
#define RCC_CFGR_PPRE2_DIV1 (0x00000000U) /*!< HCLK not divided */
#define RCC_CFGR_PPRE2_DIV2 (0x00002000U) /*!< HCLK divided by 2 */
#define RCC_CFGR_PPRE2_DIV4 (0x00002800U) /*!< HCLK divided by 4 */
#define RCC_CFGR_PPRE2_DIV8 (0x00003000U) /*!< HCLK divided by 8 */
#define RCC_CFGR_PPRE2_DIV16 (0x00003800U) /*!< HCLK divided by 16 */
/*!< MCOSEL configuration */
#define RCC_CFGR_MCOSEL_Pos (24U)
#define RCC_CFGR_MCOSEL_Msk (0xFUL << RCC_CFGR_MCOSEL_Pos) /*!< 0x0F000000 */
#define RCC_CFGR_MCOSEL RCC_CFGR_MCOSEL_Msk /*!< MCOSEL [3:0] bits (Clock output selection) */
#define RCC_CFGR_MCOSEL_0 (0x1UL << RCC_CFGR_MCOSEL_Pos) /*!< 0x01000000 */
#define RCC_CFGR_MCOSEL_1 (0x2UL << RCC_CFGR_MCOSEL_Pos) /*!< 0x02000000 */
#define RCC_CFGR_MCOSEL_2 (0x4UL << RCC_CFGR_MCOSEL_Pos) /*!< 0x04000000 */
#define RCC_CFGR_MCOSEL_3 (0x8UL << RCC_CFGR_MCOSEL_Pos) /*!< 0x08000000 */
#define RCC_CFGR_MCOPRE_Pos (28U)
#define RCC_CFGR_MCOPRE_Msk (0x7UL << RCC_CFGR_MCOPRE_Pos) /*!< 0x70000000 */
#define RCC_CFGR_MCOPRE RCC_CFGR_MCOPRE_Msk /*!< MCO prescaler */
#define RCC_CFGR_MCOPRE_0 (0x1UL << RCC_CFGR_MCOPRE_Pos) /*!< 0x10000000 */
#define RCC_CFGR_MCOPRE_1 (0x2UL << RCC_CFGR_MCOPRE_Pos) /*!< 0x20000000 */
#define RCC_CFGR_MCOPRE_2 (0x4UL << RCC_CFGR_MCOPRE_Pos) /*!< 0x40000000 */
#define RCC_CFGR_MCOPRE_DIV1 (0x00000000U) /*!< MCO is divided by 1 */
#define RCC_CFGR_MCOPRE_DIV2 (0x10000000U) /*!< MCO is divided by 2 */
#define RCC_CFGR_MCOPRE_DIV4 (0x20000000U) /*!< MCO is divided by 4 */
#define RCC_CFGR_MCOPRE_DIV8 (0x30000000U) /*!< MCO is divided by 8 */
#define RCC_CFGR_MCOPRE_DIV16 (0x40000000U) /*!< MCO is divided by 16 */
/* Legacy aliases */
#define RCC_CFGR_MCO_PRE RCC_CFGR_MCOPRE
#define RCC_CFGR_MCO_PRE_1 RCC_CFGR_MCOPRE_DIV1
#define RCC_CFGR_MCO_PRE_2 RCC_CFGR_MCOPRE_DIV2
#define RCC_CFGR_MCO_PRE_4 RCC_CFGR_MCOPRE_DIV4
#define RCC_CFGR_MCO_PRE_8 RCC_CFGR_MCOPRE_DIV8
#define RCC_CFGR_MCO_PRE_16 RCC_CFGR_MCOPRE_DIV16
/******************** Bit definition for RCC_PLLCFGR register ***************/
#define RCC_PLLCFGR_PLLSRC_Pos (0U)
#define RCC_PLLCFGR_PLLSRC_Msk (0x3UL << RCC_PLLCFGR_PLLSRC_Pos) /*!< 0x00000003 */
#define RCC_PLLCFGR_PLLSRC RCC_PLLCFGR_PLLSRC_Msk
#define RCC_PLLCFGR_PLLSRC_0 (0x1UL << RCC_PLLCFGR_PLLSRC_Pos) /*!< 0x00000001 */
#define RCC_PLLCFGR_PLLSRC_1 (0x2UL << RCC_PLLCFGR_PLLSRC_Pos) /*!< 0x00000002 */
#define RCC_PLLCFGR_PLLSRC_HSI_Pos (1U)
#define RCC_PLLCFGR_PLLSRC_HSI_Msk (0x1UL << RCC_PLLCFGR_PLLSRC_HSI_Pos)/*!< 0x00000002 */
#define RCC_PLLCFGR_PLLSRC_HSI RCC_PLLCFGR_PLLSRC_HSI_Msk /*!< HSI16 oscillator source clock selected */
#define RCC_PLLCFGR_PLLSRC_HSE_Pos (0U)
#define RCC_PLLCFGR_PLLSRC_HSE_Msk (0x3UL << RCC_PLLCFGR_PLLSRC_HSE_Pos)/*!< 0x00000003 */
#define RCC_PLLCFGR_PLLSRC_HSE RCC_PLLCFGR_PLLSRC_HSE_Msk /*!< HSE oscillator source clock selected */
#define RCC_PLLCFGR_PLLM_Pos (4U)
#define RCC_PLLCFGR_PLLM_Msk (0xFUL << RCC_PLLCFGR_PLLM_Pos) /*!< 0x000000F0 */
#define RCC_PLLCFGR_PLLM RCC_PLLCFGR_PLLM_Msk
#define RCC_PLLCFGR_PLLM_0 (0x1UL << RCC_PLLCFGR_PLLM_Pos) /*!< 0x00000010 */
#define RCC_PLLCFGR_PLLM_1 (0x2UL << RCC_PLLCFGR_PLLM_Pos) /*!< 0x00000020 */
#define RCC_PLLCFGR_PLLM_2 (0x4UL << RCC_PLLCFGR_PLLM_Pos) /*!< 0x00000040 */
#define RCC_PLLCFGR_PLLM_3 (0x8UL << RCC_PLLCFGR_PLLM_Pos) /*!< 0x00000080 */
#define RCC_PLLCFGR_PLLN_Pos (8U)
#define RCC_PLLCFGR_PLLN_Msk (0x7FUL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00007F00 */
#define RCC_PLLCFGR_PLLN RCC_PLLCFGR_PLLN_Msk
#define RCC_PLLCFGR_PLLN_0 (0x01UL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00000100 */
#define RCC_PLLCFGR_PLLN_1 (0x02UL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00000200 */
#define RCC_PLLCFGR_PLLN_2 (0x04UL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00000400 */
#define RCC_PLLCFGR_PLLN_3 (0x08UL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00000800 */
#define RCC_PLLCFGR_PLLN_4 (0x10UL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00001000 */
#define RCC_PLLCFGR_PLLN_5 (0x20UL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00002000 */
#define RCC_PLLCFGR_PLLN_6 (0x40UL << RCC_PLLCFGR_PLLN_Pos) /*!< 0x00004000 */
#define RCC_PLLCFGR_PLLPEN_Pos (16U)
#define RCC_PLLCFGR_PLLPEN_Msk (0x1UL << RCC_PLLCFGR_PLLPEN_Pos) /*!< 0x00010000 */
#define RCC_PLLCFGR_PLLPEN RCC_PLLCFGR_PLLPEN_Msk
#define RCC_PLLCFGR_PLLP_Pos (17U)
#define RCC_PLLCFGR_PLLP_Msk (0x1UL << RCC_PLLCFGR_PLLP_Pos) /*!< 0x00020000 */
#define RCC_PLLCFGR_PLLP RCC_PLLCFGR_PLLP_Msk
#define RCC_PLLCFGR_PLLQEN_Pos (20U)
#define RCC_PLLCFGR_PLLQEN_Msk (0x1UL << RCC_PLLCFGR_PLLQEN_Pos) /*!< 0x00100000 */
#define RCC_PLLCFGR_PLLQEN RCC_PLLCFGR_PLLQEN_Msk
#define RCC_PLLCFGR_PLLQ_Pos (21U)
#define RCC_PLLCFGR_PLLQ_Msk (0x3UL << RCC_PLLCFGR_PLLQ_Pos) /*!< 0x00600000 */
#define RCC_PLLCFGR_PLLQ RCC_PLLCFGR_PLLQ_Msk
#define RCC_PLLCFGR_PLLQ_0 (0x1UL << RCC_PLLCFGR_PLLQ_Pos) /*!< 0x00200000 */
#define RCC_PLLCFGR_PLLQ_1 (0x2UL << RCC_PLLCFGR_PLLQ_Pos) /*!< 0x00400000 */
#define RCC_PLLCFGR_PLLREN_Pos (24U)
#define RCC_PLLCFGR_PLLREN_Msk (0x1UL << RCC_PLLCFGR_PLLREN_Pos) /*!< 0x01000000 */
#define RCC_PLLCFGR_PLLREN RCC_PLLCFGR_PLLREN_Msk
#define RCC_PLLCFGR_PLLR_Pos (25U)
#define RCC_PLLCFGR_PLLR_Msk (0x3UL << RCC_PLLCFGR_PLLR_Pos) /*!< 0x06000000 */
#define RCC_PLLCFGR_PLLR RCC_PLLCFGR_PLLR_Msk
#define RCC_PLLCFGR_PLLR_0 (0x1UL << RCC_PLLCFGR_PLLR_Pos) /*!< 0x02000000 */
#define RCC_PLLCFGR_PLLR_1 (0x2UL << RCC_PLLCFGR_PLLR_Pos) /*!< 0x04000000 */
#define RCC_PLLCFGR_PLLPDIV_Pos (27U)
#define RCC_PLLCFGR_PLLPDIV_Msk (0x1FUL << RCC_PLLCFGR_PLLPDIV_Pos)/*!< 0xF8000000 */
#define RCC_PLLCFGR_PLLPDIV RCC_PLLCFGR_PLLPDIV_Msk
#define RCC_PLLCFGR_PLLPDIV_0 (0x01UL << RCC_PLLCFGR_PLLPDIV_Pos)/*!< 0x08000000 */
#define RCC_PLLCFGR_PLLPDIV_1 (0x02UL << RCC_PLLCFGR_PLLPDIV_Pos)/*!< 0x10000000 */
#define RCC_PLLCFGR_PLLPDIV_2 (0x04UL << RCC_PLLCFGR_PLLPDIV_Pos)/*!< 0x20000000 */
#define RCC_PLLCFGR_PLLPDIV_3 (0x08UL << RCC_PLLCFGR_PLLPDIV_Pos)/*!< 0x40000000 */
#define RCC_PLLCFGR_PLLPDIV_4 (0x10UL << RCC_PLLCFGR_PLLPDIV_Pos)/*!< 0x80000000 */
/******************** Bit definition for RCC_CIER register ******************/
#define RCC_CIER_LSIRDYIE_Pos (0U)
#define RCC_CIER_LSIRDYIE_Msk (0x1UL << RCC_CIER_LSIRDYIE_Pos) /*!< 0x00000001 */
#define RCC_CIER_LSIRDYIE RCC_CIER_LSIRDYIE_Msk
#define RCC_CIER_LSERDYIE_Pos (1U)
#define RCC_CIER_LSERDYIE_Msk (0x1UL << RCC_CIER_LSERDYIE_Pos) /*!< 0x00000002 */
#define RCC_CIER_LSERDYIE RCC_CIER_LSERDYIE_Msk
#define RCC_CIER_HSIRDYIE_Pos (3U)
#define RCC_CIER_HSIRDYIE_Msk (0x1UL << RCC_CIER_HSIRDYIE_Pos) /*!< 0x00000008 */
#define RCC_CIER_HSIRDYIE RCC_CIER_HSIRDYIE_Msk
#define RCC_CIER_HSERDYIE_Pos (4U)
#define RCC_CIER_HSERDYIE_Msk (0x1UL << RCC_CIER_HSERDYIE_Pos) /*!< 0x00000010 */
#define RCC_CIER_HSERDYIE RCC_CIER_HSERDYIE_Msk
#define RCC_CIER_PLLRDYIE_Pos (5U)
#define RCC_CIER_PLLRDYIE_Msk (0x1UL << RCC_CIER_PLLRDYIE_Pos) /*!< 0x00000020 */
#define RCC_CIER_PLLRDYIE RCC_CIER_PLLRDYIE_Msk
#define RCC_CIER_LSECSSIE_Pos (9U)
#define RCC_CIER_LSECSSIE_Msk (0x1UL << RCC_CIER_LSECSSIE_Pos) /*!< 0x00000200 */
#define RCC_CIER_LSECSSIE RCC_CIER_LSECSSIE_Msk
#define RCC_CIER_HSI48RDYIE_Pos (10U)
#define RCC_CIER_HSI48RDYIE_Msk (0x1UL << RCC_CIER_HSI48RDYIE_Pos)/*!< 0x00000400 */
#define RCC_CIER_HSI48RDYIE RCC_CIER_HSI48RDYIE_Msk
/******************** Bit definition for RCC_CIFR register ******************/
#define RCC_CIFR_LSIRDYF_Pos (0U)
#define RCC_CIFR_LSIRDYF_Msk (0x1UL << RCC_CIFR_LSIRDYF_Pos) /*!< 0x00000001 */
#define RCC_CIFR_LSIRDYF RCC_CIFR_LSIRDYF_Msk
#define RCC_CIFR_LSERDYF_Pos (1U)
#define RCC_CIFR_LSERDYF_Msk (0x1UL << RCC_CIFR_LSERDYF_Pos) /*!< 0x00000002 */
#define RCC_CIFR_LSERDYF RCC_CIFR_LSERDYF_Msk
#define RCC_CIFR_HSIRDYF_Pos (3U)
#define RCC_CIFR_HSIRDYF_Msk (0x1UL << RCC_CIFR_HSIRDYF_Pos) /*!< 0x00000008 */
#define RCC_CIFR_HSIRDYF RCC_CIFR_HSIRDYF_Msk
#define RCC_CIFR_HSERDYF_Pos (4U)
#define RCC_CIFR_HSERDYF_Msk (0x1UL << RCC_CIFR_HSERDYF_Pos) /*!< 0x00000010 */
#define RCC_CIFR_HSERDYF RCC_CIFR_HSERDYF_Msk
#define RCC_CIFR_PLLRDYF_Pos (5U)
#define RCC_CIFR_PLLRDYF_Msk (0x1UL << RCC_CIFR_PLLRDYF_Pos) /*!< 0x00000020 */
#define RCC_CIFR_PLLRDYF RCC_CIFR_PLLRDYF_Msk
#define RCC_CIFR_CSSF_Pos (8U)
#define RCC_CIFR_CSSF_Msk (0x1UL << RCC_CIFR_CSSF_Pos) /*!< 0x00000100 */
#define RCC_CIFR_CSSF RCC_CIFR_CSSF_Msk
#define RCC_CIFR_LSECSSF_Pos (9U)
#define RCC_CIFR_LSECSSF_Msk (0x1UL << RCC_CIFR_LSECSSF_Pos) /*!< 0x00000200 */
#define RCC_CIFR_LSECSSF RCC_CIFR_LSECSSF_Msk
#define RCC_CIFR_HSI48RDYF_Pos (10U)
#define RCC_CIFR_HSI48RDYF_Msk (0x1UL << RCC_CIFR_HSI48RDYF_Pos) /*!< 0x00000400 */
#define RCC_CIFR_HSI48RDYF RCC_CIFR_HSI48RDYF_Msk
/******************** Bit definition for RCC_CICR register ******************/
#define RCC_CICR_LSIRDYC_Pos (0U)
#define RCC_CICR_LSIRDYC_Msk (0x1UL << RCC_CICR_LSIRDYC_Pos) /*!< 0x00000001 */
#define RCC_CICR_LSIRDYC RCC_CICR_LSIRDYC_Msk
#define RCC_CICR_LSERDYC_Pos (1U)
#define RCC_CICR_LSERDYC_Msk (0x1UL << RCC_CICR_LSERDYC_Pos) /*!< 0x00000002 */
#define RCC_CICR_LSERDYC RCC_CICR_LSERDYC_Msk
#define RCC_CICR_HSIRDYC_Pos (3U)
#define RCC_CICR_HSIRDYC_Msk (0x1UL << RCC_CICR_HSIRDYC_Pos) /*!< 0x00000008 */
#define RCC_CICR_HSIRDYC RCC_CICR_HSIRDYC_Msk
#define RCC_CICR_HSERDYC_Pos (4U)
#define RCC_CICR_HSERDYC_Msk (0x1UL << RCC_CICR_HSERDYC_Pos) /*!< 0x00000010 */
#define RCC_CICR_HSERDYC RCC_CICR_HSERDYC_Msk
#define RCC_CICR_PLLRDYC_Pos (5U)
#define RCC_CICR_PLLRDYC_Msk (0x1UL << RCC_CICR_PLLRDYC_Pos) /*!< 0x00000020 */
#define RCC_CICR_PLLRDYC RCC_CICR_PLLRDYC_Msk
#define RCC_CICR_CSSC_Pos (8U)
#define RCC_CICR_CSSC_Msk (0x1UL << RCC_CICR_CSSC_Pos) /*!< 0x00000100 */
#define RCC_CICR_CSSC RCC_CICR_CSSC_Msk
#define RCC_CICR_LSECSSC_Pos (9U)
#define RCC_CICR_LSECSSC_Msk (0x1UL << RCC_CICR_LSECSSC_Pos) /*!< 0x00000200 */
#define RCC_CICR_LSECSSC RCC_CICR_LSECSSC_Msk
#define RCC_CICR_HSI48RDYC_Pos (10U)
#define RCC_CICR_HSI48RDYC_Msk (0x1UL << RCC_CICR_HSI48RDYC_Pos) /*!< 0x00000400 */
#define RCC_CICR_HSI48RDYC RCC_CICR_HSI48RDYC_Msk
/******************** Bit definition for RCC_AHB1RSTR register **************/
#define RCC_AHB1RSTR_DMA1RST_Pos (0U)
#define RCC_AHB1RSTR_DMA1RST_Msk (0x1UL << RCC_AHB1RSTR_DMA1RST_Pos)/*!< 0x00000001 */
#define RCC_AHB1RSTR_DMA1RST RCC_AHB1RSTR_DMA1RST_Msk
#define RCC_AHB1RSTR_DMA2RST_Pos (1U)
#define RCC_AHB1RSTR_DMA2RST_Msk (0x1UL << RCC_AHB1RSTR_DMA2RST_Pos)/*!< 0x00000002 */
#define RCC_AHB1RSTR_DMA2RST RCC_AHB1RSTR_DMA2RST_Msk
#define RCC_AHB1RSTR_DMAMUX1RST_Pos (2U)
#define RCC_AHB1RSTR_DMAMUX1RST_Msk (0x1UL << RCC_AHB1RSTR_DMAMUX1RST_Pos)/*!< 0x00000004 */
#define RCC_AHB1RSTR_DMAMUX1RST RCC_AHB1RSTR_DMAMUX1RST_Msk
#define RCC_AHB1RSTR_CORDICRST_Pos (3U)
#define RCC_AHB1RSTR_CORDICRST_Msk (0x1UL << RCC_AHB1RSTR_CORDICRST_Pos)/*!< 0x00000008 */
#define RCC_AHB1RSTR_CORDICRST RCC_AHB1RSTR_CORDICRST_Msk
#define RCC_AHB1RSTR_FMACRST_Pos (4U)
#define RCC_AHB1RSTR_FMACRST_Msk (0x1UL << RCC_AHB1RSTR_FMACRST_Pos) /*!< 0x00000010 */
#define RCC_AHB1RSTR_FMACRST RCC_AHB1RSTR_FMACRST_Msk
#define RCC_AHB1RSTR_FLASHRST_Pos (8U)
#define RCC_AHB1RSTR_FLASHRST_Msk (0x1UL << RCC_AHB1RSTR_FLASHRST_Pos)/*!< 0x00000100 */
#define RCC_AHB1RSTR_FLASHRST RCC_AHB1RSTR_FLASHRST_Msk
#define RCC_AHB1RSTR_CRCRST_Pos (12U)
#define RCC_AHB1RSTR_CRCRST_Msk (0x1UL << RCC_AHB1RSTR_CRCRST_Pos)/*!< 0x00001000 */
#define RCC_AHB1RSTR_CRCRST RCC_AHB1RSTR_CRCRST_Msk
/******************** Bit definition for RCC_AHB2RSTR register **************/
#define RCC_AHB2RSTR_GPIOARST_Pos (0U)
#define RCC_AHB2RSTR_GPIOARST_Msk (0x1UL << RCC_AHB2RSTR_GPIOARST_Pos)/*!< 0x00000001 */
#define RCC_AHB2RSTR_GPIOARST RCC_AHB2RSTR_GPIOARST_Msk
#define RCC_AHB2RSTR_GPIOBRST_Pos (1U)
#define RCC_AHB2RSTR_GPIOBRST_Msk (0x1UL << RCC_AHB2RSTR_GPIOBRST_Pos)/*!< 0x00000002 */
#define RCC_AHB2RSTR_GPIOBRST RCC_AHB2RSTR_GPIOBRST_Msk
#define RCC_AHB2RSTR_GPIOCRST_Pos (2U)
#define RCC_AHB2RSTR_GPIOCRST_Msk (0x1UL << RCC_AHB2RSTR_GPIOCRST_Pos)/*!< 0x00000004 */
#define RCC_AHB2RSTR_GPIOCRST RCC_AHB2RSTR_GPIOCRST_Msk
#define RCC_AHB2RSTR_GPIODRST_Pos (3U)
#define RCC_AHB2RSTR_GPIODRST_Msk (0x1UL << RCC_AHB2RSTR_GPIODRST_Pos)/*!< 0x00000008 */
#define RCC_AHB2RSTR_GPIODRST RCC_AHB2RSTR_GPIODRST_Msk
#define RCC_AHB2RSTR_GPIOERST_Pos (4U)
#define RCC_AHB2RSTR_GPIOERST_Msk (0x1UL << RCC_AHB2RSTR_GPIOERST_Pos)/*!< 0x00000010 */
#define RCC_AHB2RSTR_GPIOERST RCC_AHB2RSTR_GPIOERST_Msk
#define RCC_AHB2RSTR_GPIOFRST_Pos (5U)
#define RCC_AHB2RSTR_GPIOFRST_Msk (0x1UL << RCC_AHB2RSTR_GPIOFRST_Pos)/*!< 0x00000020 */
#define RCC_AHB2RSTR_GPIOFRST RCC_AHB2RSTR_GPIOFRST_Msk
#define RCC_AHB2RSTR_GPIOGRST_Pos (6U)
#define RCC_AHB2RSTR_GPIOGRST_Msk (0x1UL << RCC_AHB2RSTR_GPIOGRST_Pos)/*!< 0x00000040 */
#define RCC_AHB2RSTR_GPIOGRST RCC_AHB2RSTR_GPIOGRST_Msk
#define RCC_AHB2RSTR_ADC12RST_Pos (13U)
#define RCC_AHB2RSTR_ADC12RST_Msk (0x1UL << RCC_AHB2RSTR_ADC12RST_Pos)/*!< 0x00002000 */
#define RCC_AHB2RSTR_ADC12RST RCC_AHB2RSTR_ADC12RST_Msk
#define RCC_AHB2RSTR_DAC1RST_Pos (16U)
#define RCC_AHB2RSTR_DAC1RST_Msk (0x1UL << RCC_AHB2RSTR_DAC1RST_Pos)/*!< 0x00010000 */
#define RCC_AHB2RSTR_DAC1RST RCC_AHB2RSTR_DAC1RST_Msk
#define RCC_AHB2RSTR_DAC3RST_Pos (18U)
#define RCC_AHB2RSTR_DAC3RST_Msk (0x1UL << RCC_AHB2RSTR_DAC3RST_Pos)/*!< 0x00040000 */
#define RCC_AHB2RSTR_DAC3RST RCC_AHB2RSTR_DAC3RST_Msk
#define RCC_AHB2RSTR_RNGRST_Pos (26U)
#define RCC_AHB2RSTR_RNGRST_Msk (0x1UL << RCC_AHB2RSTR_RNGRST_Pos)/*!< 0x04000000 */
#define RCC_AHB2RSTR_RNGRST RCC_AHB2RSTR_RNGRST_Msk
/******************** Bit definition for RCC_AHB3RSTR register **************/
/******************** Bit definition for RCC_APB1RSTR1 register **************/
#define RCC_APB1RSTR1_TIM2RST_Pos (0U)
#define RCC_APB1RSTR1_TIM2RST_Msk (0x1UL << RCC_APB1RSTR1_TIM2RST_Pos)/*!< 0x00000001 */
#define RCC_APB1RSTR1_TIM2RST RCC_APB1RSTR1_TIM2RST_Msk
#define RCC_APB1RSTR1_TIM3RST_Pos (1U)
#define RCC_APB1RSTR1_TIM3RST_Msk (0x1UL << RCC_APB1RSTR1_TIM3RST_Pos)/*!< 0x00000002 */
#define RCC_APB1RSTR1_TIM3RST RCC_APB1RSTR1_TIM3RST_Msk
#define RCC_APB1RSTR1_TIM4RST_Pos (2U)
#define RCC_APB1RSTR1_TIM4RST_Msk (0x1UL << RCC_APB1RSTR1_TIM4RST_Pos)/*!< 0x00000004 */
#define RCC_APB1RSTR1_TIM4RST RCC_APB1RSTR1_TIM4RST_Msk
#define RCC_APB1RSTR1_TIM6RST_Pos (4U)
#define RCC_APB1RSTR1_TIM6RST_Msk (0x1UL << RCC_APB1RSTR1_TIM6RST_Pos)/*!< 0x00000010 */
#define RCC_APB1RSTR1_TIM6RST RCC_APB1RSTR1_TIM6RST_Msk
#define RCC_APB1RSTR1_TIM7RST_Pos (5U)
#define RCC_APB1RSTR1_TIM7RST_Msk (0x1UL << RCC_APB1RSTR1_TIM7RST_Pos)/*!< 0x00000020 */
#define RCC_APB1RSTR1_TIM7RST RCC_APB1RSTR1_TIM7RST_Msk
#define RCC_APB1RSTR1_CRSRST_Pos (8U)
#define RCC_APB1RSTR1_CRSRST_Msk (0x1UL << RCC_APB1RSTR1_CRSRST_Pos)/*!< 0x00000100 */
#define RCC_APB1RSTR1_CRSRST RCC_APB1RSTR1_CRSRST_Msk
#define RCC_APB1RSTR1_SPI2RST_Pos (14U)
#define RCC_APB1RSTR1_SPI2RST_Msk (0x1UL << RCC_APB1RSTR1_SPI2RST_Pos)/*!< 0x00004000 */
#define RCC_APB1RSTR1_SPI2RST RCC_APB1RSTR1_SPI2RST_Msk
#define RCC_APB1RSTR1_SPI3RST_Pos (15U)
#define RCC_APB1RSTR1_SPI3RST_Msk (0x1UL << RCC_APB1RSTR1_SPI3RST_Pos)/*!< 0x00008000 */
#define RCC_APB1RSTR1_SPI3RST RCC_APB1RSTR1_SPI3RST_Msk
#define RCC_APB1RSTR1_USART2RST_Pos (17U)
#define RCC_APB1RSTR1_USART2RST_Msk (0x1UL << RCC_APB1RSTR1_USART2RST_Pos)/*!< 0x00020000 */
#define RCC_APB1RSTR1_USART2RST RCC_APB1RSTR1_USART2RST_Msk
#define RCC_APB1RSTR1_USART3RST_Pos (18U)
#define RCC_APB1RSTR1_USART3RST_Msk (0x1UL << RCC_APB1RSTR1_USART3RST_Pos)/*!< 0x00040000 */
#define RCC_APB1RSTR1_USART3RST RCC_APB1RSTR1_USART3RST_Msk
#define RCC_APB1RSTR1_UART4RST_Pos (19U)
#define RCC_APB1RSTR1_UART4RST_Msk (0x1UL << RCC_APB1RSTR1_UART4RST_Pos)/*!< 0x00080000 */
#define RCC_APB1RSTR1_UART4RST RCC_APB1RSTR1_UART4RST_Msk
#define RCC_APB1RSTR1_I2C1RST_Pos (21U)
#define RCC_APB1RSTR1_I2C1RST_Msk (0x1UL << RCC_APB1RSTR1_I2C1RST_Pos)/*!< 0x00200000 */
#define RCC_APB1RSTR1_I2C1RST RCC_APB1RSTR1_I2C1RST_Msk
#define RCC_APB1RSTR1_I2C2RST_Pos (22U)
#define RCC_APB1RSTR1_I2C2RST_Msk (0x1UL << RCC_APB1RSTR1_I2C2RST_Pos)/*!< 0x00400000 */
#define RCC_APB1RSTR1_I2C2RST RCC_APB1RSTR1_I2C2RST_Msk
#define RCC_APB1RSTR1_USBRST_Pos (23U)
#define RCC_APB1RSTR1_USBRST_Msk (0x1UL << RCC_APB1RSTR1_USBRST_Pos)/*!< 0x00800000 */
#define RCC_APB1RSTR1_USBRST RCC_APB1RSTR1_USBRST_Msk
#define RCC_APB1RSTR1_FDCANRST_Pos (25U)
#define RCC_APB1RSTR1_FDCANRST_Msk (0x1UL << RCC_APB1RSTR1_FDCANRST_Pos)/*!< 0x02000000 */
#define RCC_APB1RSTR1_FDCANRST RCC_APB1RSTR1_FDCANRST_Msk
#define RCC_APB1RSTR1_PWRRST_Pos (28U)
#define RCC_APB1RSTR1_PWRRST_Msk (0x1UL << RCC_APB1RSTR1_PWRRST_Pos)/*!< 0x10000000 */
#define RCC_APB1RSTR1_PWRRST RCC_APB1RSTR1_PWRRST_Msk
#define RCC_APB1RSTR1_I2C3RST_Pos (30U)
#define RCC_APB1RSTR1_I2C3RST_Msk (0x1UL << RCC_APB1RSTR1_I2C3RST_Pos)/*!< 0x40000000 */
#define RCC_APB1RSTR1_I2C3RST RCC_APB1RSTR1_I2C3RST_Msk
#define RCC_APB1RSTR1_LPTIM1RST_Pos (31U)
#define RCC_APB1RSTR1_LPTIM1RST_Msk (0x1UL << RCC_APB1RSTR1_LPTIM1RST_Pos)/*!< 0x80000000 */
#define RCC_APB1RSTR1_LPTIM1RST RCC_APB1RSTR1_LPTIM1RST_Msk
/******************** Bit definition for RCC_APB1RSTR2 register **************/
#define RCC_APB1RSTR2_LPUART1RST_Pos (0U)
#define RCC_APB1RSTR2_LPUART1RST_Msk (0x1UL << RCC_APB1RSTR2_LPUART1RST_Pos)/*!< 0x00000001 */
#define RCC_APB1RSTR2_LPUART1RST RCC_APB1RSTR2_LPUART1RST_Msk
#define RCC_APB1RSTR2_UCPD1RST_Pos (8U)
#define RCC_APB1RSTR2_UCPD1RST_Msk (0x1UL << RCC_APB1RSTR2_UCPD1RST_Pos)/*!< 0x00000100 */
#define RCC_APB1RSTR2_UCPD1RST RCC_APB1RSTR2_UCPD1RST_Msk
/******************** Bit definition for RCC_APB2RSTR register **************/
#define RCC_APB2RSTR_SYSCFGRST_Pos (0U)
#define RCC_APB2RSTR_SYSCFGRST_Msk (0x1UL << RCC_APB2RSTR_SYSCFGRST_Pos)/*!< 0x00000001 */
#define RCC_APB2RSTR_SYSCFGRST RCC_APB2RSTR_SYSCFGRST_Msk
#define RCC_APB2RSTR_TIM1RST_Pos (11U)
#define RCC_APB2RSTR_TIM1RST_Msk (0x1UL << RCC_APB2RSTR_TIM1RST_Pos)/*!< 0x00000800 */
#define RCC_APB2RSTR_TIM1RST RCC_APB2RSTR_TIM1RST_Msk
#define RCC_APB2RSTR_SPI1RST_Pos (12U)
#define RCC_APB2RSTR_SPI1RST_Msk (0x1UL << RCC_APB2RSTR_SPI1RST_Pos)/*!< 0x00001000 */
#define RCC_APB2RSTR_SPI1RST RCC_APB2RSTR_SPI1RST_Msk
#define RCC_APB2RSTR_TIM8RST_Pos (13U)
#define RCC_APB2RSTR_TIM8RST_Msk (0x1UL << RCC_APB2RSTR_TIM8RST_Pos)/*!< 0x00002000 */
#define RCC_APB2RSTR_TIM8RST RCC_APB2RSTR_TIM8RST_Msk
#define RCC_APB2RSTR_USART1RST_Pos (14U)
#define RCC_APB2RSTR_USART1RST_Msk (0x1UL << RCC_APB2RSTR_USART1RST_Pos)/*!< 0x00004000 */
#define RCC_APB2RSTR_USART1RST RCC_APB2RSTR_USART1RST_Msk
#define RCC_APB2RSTR_TIM15RST_Pos (16U)
#define RCC_APB2RSTR_TIM15RST_Msk (0x1UL << RCC_APB2RSTR_TIM15RST_Pos)/*!< 0x00010000 */
#define RCC_APB2RSTR_TIM15RST RCC_APB2RSTR_TIM15RST_Msk
#define RCC_APB2RSTR_TIM16RST_Pos (17U)
#define RCC_APB2RSTR_TIM16RST_Msk (0x1UL << RCC_APB2RSTR_TIM16RST_Pos)/*!< 0x00020000 */
#define RCC_APB2RSTR_TIM16RST RCC_APB2RSTR_TIM16RST_Msk
#define RCC_APB2RSTR_TIM17RST_Pos (18U)
#define RCC_APB2RSTR_TIM17RST_Msk (0x1UL << RCC_APB2RSTR_TIM17RST_Pos)/*!< 0x00040000 */
#define RCC_APB2RSTR_TIM17RST RCC_APB2RSTR_TIM17RST_Msk
#define RCC_APB2RSTR_SAI1RST_Pos (21U)
#define RCC_APB2RSTR_SAI1RST_Msk (0x1UL << RCC_APB2RSTR_SAI1RST_Pos)/*!< 0x00200000 */
#define RCC_APB2RSTR_SAI1RST RCC_APB2RSTR_SAI1RST_Msk
/******************** Bit definition for RCC_AHB1ENR register ***************/
#define RCC_AHB1ENR_DMA1EN_Pos (0U)
#define RCC_AHB1ENR_DMA1EN_Msk (0x1UL << RCC_AHB1ENR_DMA1EN_Pos) /*!< 0x00000001 */
#define RCC_AHB1ENR_DMA1EN RCC_AHB1ENR_DMA1EN_Msk
#define RCC_AHB1ENR_DMA2EN_Pos (1U)
#define RCC_AHB1ENR_DMA2EN_Msk (0x1UL << RCC_AHB1ENR_DMA2EN_Pos) /*!< 0x00000002 */
#define RCC_AHB1ENR_DMA2EN RCC_AHB1ENR_DMA2EN_Msk
#define RCC_AHB1ENR_DMAMUX1EN_Pos (2U)
#define RCC_AHB1ENR_DMAMUX1EN_Msk (0x1UL << RCC_AHB1ENR_DMAMUX1EN_Pos)/*!< 0x00000004 */
#define RCC_AHB1ENR_DMAMUX1EN RCC_AHB1ENR_DMAMUX1EN_Msk
#define RCC_AHB1ENR_CORDICEN_Pos (3U)
#define RCC_AHB1ENR_CORDICEN_Msk (0x1UL << RCC_AHB1ENR_CORDICEN_Pos)/*!< 0x00000008 */
#define RCC_AHB1ENR_CORDICEN RCC_AHB1ENR_CORDICEN_Msk
#define RCC_AHB1ENR_FMACEN_Pos (4U)
#define RCC_AHB1ENR_FMACEN_Msk (0x1UL << RCC_AHB1ENR_FMACEN_Pos) /*!< 0x00000010 */
#define RCC_AHB1ENR_FMACEN RCC_AHB1ENR_FMACEN_Msk
#define RCC_AHB1ENR_FLASHEN_Pos (8U)
#define RCC_AHB1ENR_FLASHEN_Msk (0x1UL << RCC_AHB1ENR_FLASHEN_Pos)/*!< 0x00000100 */
#define RCC_AHB1ENR_FLASHEN RCC_AHB1ENR_FLASHEN_Msk
#define RCC_AHB1ENR_CRCEN_Pos (12U)
#define RCC_AHB1ENR_CRCEN_Msk (0x1UL << RCC_AHB1ENR_CRCEN_Pos) /*!< 0x00001000 */
#define RCC_AHB1ENR_CRCEN RCC_AHB1ENR_CRCEN_Msk
/******************** Bit definition for RCC_AHB2ENR register ***************/
#define RCC_AHB2ENR_GPIOAEN_Pos (0U)
#define RCC_AHB2ENR_GPIOAEN_Msk (0x1UL << RCC_AHB2ENR_GPIOAEN_Pos)/*!< 0x00000001 */
#define RCC_AHB2ENR_GPIOAEN RCC_AHB2ENR_GPIOAEN_Msk
#define RCC_AHB2ENR_GPIOBEN_Pos (1U)
#define RCC_AHB2ENR_GPIOBEN_Msk (0x1UL << RCC_AHB2ENR_GPIOBEN_Pos)/*!< 0x00000002 */
#define RCC_AHB2ENR_GPIOBEN RCC_AHB2ENR_GPIOBEN_Msk
#define RCC_AHB2ENR_GPIOCEN_Pos (2U)
#define RCC_AHB2ENR_GPIOCEN_Msk (0x1UL << RCC_AHB2ENR_GPIOCEN_Pos)/*!< 0x00000004 */
#define RCC_AHB2ENR_GPIOCEN RCC_AHB2ENR_GPIOCEN_Msk
#define RCC_AHB2ENR_GPIODEN_Pos (3U)
#define RCC_AHB2ENR_GPIODEN_Msk (0x1UL << RCC_AHB2ENR_GPIODEN_Pos)/*!< 0x00000008 */
#define RCC_AHB2ENR_GPIODEN RCC_AHB2ENR_GPIODEN_Msk
#define RCC_AHB2ENR_GPIOEEN_Pos (4U)
#define RCC_AHB2ENR_GPIOEEN_Msk (0x1UL << RCC_AHB2ENR_GPIOEEN_Pos)/*!< 0x00000010 */
#define RCC_AHB2ENR_GPIOEEN RCC_AHB2ENR_GPIOEEN_Msk
#define RCC_AHB2ENR_GPIOFEN_Pos (5U)
#define RCC_AHB2ENR_GPIOFEN_Msk (0x1UL << RCC_AHB2ENR_GPIOFEN_Pos)/*!< 0x00000020 */
#define RCC_AHB2ENR_GPIOFEN RCC_AHB2ENR_GPIOFEN_Msk
#define RCC_AHB2ENR_GPIOGEN_Pos (6U)
#define RCC_AHB2ENR_GPIOGEN_Msk (0x1UL << RCC_AHB2ENR_GPIOGEN_Pos)/*!< 0x00000040 */
#define RCC_AHB2ENR_GPIOGEN RCC_AHB2ENR_GPIOGEN_Msk
#define RCC_AHB2ENR_ADC12EN_Pos (13U)
#define RCC_AHB2ENR_ADC12EN_Msk (0x1UL << RCC_AHB2ENR_ADC12EN_Pos) /*!< 0x00002000 */
#define RCC_AHB2ENR_ADC12EN RCC_AHB2ENR_ADC12EN_Msk
#define RCC_AHB2ENR_DAC1EN_Pos (16U)
#define RCC_AHB2ENR_DAC1EN_Msk (0x1UL << RCC_AHB2ENR_DAC1EN_Pos) /*!< 0x00010000 */
#define RCC_AHB2ENR_DAC1EN RCC_AHB2ENR_DAC1EN_Msk
#define RCC_AHB2ENR_DAC3EN_Pos (18U)
#define RCC_AHB2ENR_DAC3EN_Msk (0x1UL << RCC_AHB2ENR_DAC3EN_Pos) /*!< 0x00040000 */
#define RCC_AHB2ENR_DAC3EN RCC_AHB2ENR_DAC3EN_Msk
#define RCC_AHB2ENR_RNGEN_Pos (26U)
#define RCC_AHB2ENR_RNGEN_Msk (0x1UL << RCC_AHB2ENR_RNGEN_Pos) /*!< 0x04000000 */
#define RCC_AHB2ENR_RNGEN RCC_AHB2ENR_RNGEN_Msk
/******************** Bit definition for RCC_AHB3ENR register ***************/
/******************** Bit definition for RCC_APB1ENR1 register ***************/
#define RCC_APB1ENR1_TIM2EN_Pos (0U)
#define RCC_APB1ENR1_TIM2EN_Msk (0x1UL << RCC_APB1ENR1_TIM2EN_Pos)/*!< 0x00000001 */
#define RCC_APB1ENR1_TIM2EN RCC_APB1ENR1_TIM2EN_Msk
#define RCC_APB1ENR1_TIM3EN_Pos (1U)
#define RCC_APB1ENR1_TIM3EN_Msk (0x1UL << RCC_APB1ENR1_TIM3EN_Pos)/*!< 0x00000002 */
#define RCC_APB1ENR1_TIM3EN RCC_APB1ENR1_TIM3EN_Msk
#define RCC_APB1ENR1_TIM4EN_Pos (2U)
#define RCC_APB1ENR1_TIM4EN_Msk (0x1UL << RCC_APB1ENR1_TIM4EN_Pos)/*!< 0x00000004 */
#define RCC_APB1ENR1_TIM4EN RCC_APB1ENR1_TIM4EN_Msk
#define RCC_APB1ENR1_TIM6EN_Pos (4U)
#define RCC_APB1ENR1_TIM6EN_Msk (0x1UL << RCC_APB1ENR1_TIM6EN_Pos)/*!< 0x00000010 */
#define RCC_APB1ENR1_TIM6EN RCC_APB1ENR1_TIM6EN_Msk
#define RCC_APB1ENR1_TIM7EN_Pos (5U)
#define RCC_APB1ENR1_TIM7EN_Msk (0x1UL << RCC_APB1ENR1_TIM7EN_Pos)/*!< 0x00000020 */
#define RCC_APB1ENR1_TIM7EN RCC_APB1ENR1_TIM7EN_Msk
#define RCC_APB1ENR1_CRSEN_Pos (8U)
#define RCC_APB1ENR1_CRSEN_Msk (0x1UL << RCC_APB1ENR1_CRSEN_Pos) /*!< 0x00000100 */
#define RCC_APB1ENR1_CRSEN RCC_APB1ENR1_CRSEN_Msk
#define RCC_APB1ENR1_RTCAPBEN_Pos (10U)
#define RCC_APB1ENR1_RTCAPBEN_Msk (0x1UL << RCC_APB1ENR1_RTCAPBEN_Pos)/*!< 0x00000400 */
#define RCC_APB1ENR1_RTCAPBEN RCC_APB1ENR1_RTCAPBEN_Msk
#define RCC_APB1ENR1_WWDGEN_Pos (11U)
#define RCC_APB1ENR1_WWDGEN_Msk (0x1UL << RCC_APB1ENR1_WWDGEN_Pos)/*!< 0x00000800 */
#define RCC_APB1ENR1_WWDGEN RCC_APB1ENR1_WWDGEN_Msk
#define RCC_APB1ENR1_SPI2EN_Pos (14U)
#define RCC_APB1ENR1_SPI2EN_Msk (0x1UL << RCC_APB1ENR1_SPI2EN_Pos)/*!< 0x00004000 */
#define RCC_APB1ENR1_SPI2EN RCC_APB1ENR1_SPI2EN_Msk
#define RCC_APB1ENR1_SPI3EN_Pos (15U)
#define RCC_APB1ENR1_SPI3EN_Msk (0x1UL << RCC_APB1ENR1_SPI3EN_Pos)/*!< 0x00008000 */
#define RCC_APB1ENR1_SPI3EN RCC_APB1ENR1_SPI3EN_Msk
#define RCC_APB1ENR1_USART2EN_Pos (17U)
#define RCC_APB1ENR1_USART2EN_Msk (0x1UL << RCC_APB1ENR1_USART2EN_Pos)/*!< 0x00020000 */
#define RCC_APB1ENR1_USART2EN RCC_APB1ENR1_USART2EN_Msk
#define RCC_APB1ENR1_USART3EN_Pos (18U)
#define RCC_APB1ENR1_USART3EN_Msk (0x1UL << RCC_APB1ENR1_USART3EN_Pos)/*!< 0x00040000 */
#define RCC_APB1ENR1_USART3EN RCC_APB1ENR1_USART3EN_Msk
#define RCC_APB1ENR1_UART4EN_Pos (19U)
#define RCC_APB1ENR1_UART4EN_Msk (0x1UL << RCC_APB1ENR1_UART4EN_Pos)/*!< 0x00080000 */
#define RCC_APB1ENR1_UART4EN RCC_APB1ENR1_UART4EN_Msk
#define RCC_APB1ENR1_I2C1EN_Pos (21U)
#define RCC_APB1ENR1_I2C1EN_Msk (0x1UL << RCC_APB1ENR1_I2C1EN_Pos)/*!< 0x00200000 */
#define RCC_APB1ENR1_I2C1EN RCC_APB1ENR1_I2C1EN_Msk
#define RCC_APB1ENR1_I2C2EN_Pos (22U)
#define RCC_APB1ENR1_I2C2EN_Msk (0x1UL << RCC_APB1ENR1_I2C2EN_Pos)/*!< 0x00400000 */
#define RCC_APB1ENR1_I2C2EN RCC_APB1ENR1_I2C2EN_Msk
#define RCC_APB1ENR1_USBEN_Pos (23U)
#define RCC_APB1ENR1_USBEN_Msk (0x1UL << RCC_APB1ENR1_USBEN_Pos)/*!< 0x00800000 */
#define RCC_APB1ENR1_USBEN RCC_APB1ENR1_USBEN_Msk
#define RCC_APB1ENR1_FDCANEN_Pos (25U)
#define RCC_APB1ENR1_FDCANEN_Msk (0x1UL << RCC_APB1ENR1_FDCANEN_Pos)/*!< 0x02000000 */
#define RCC_APB1ENR1_FDCANEN RCC_APB1ENR1_FDCANEN_Msk
#define RCC_APB1ENR1_PWREN_Pos (28U)
#define RCC_APB1ENR1_PWREN_Msk (0x1UL << RCC_APB1ENR1_PWREN_Pos) /*!< 0x10000000 */
#define RCC_APB1ENR1_PWREN RCC_APB1ENR1_PWREN_Msk
#define RCC_APB1ENR1_I2C3EN_Pos (30U)
#define RCC_APB1ENR1_I2C3EN_Msk (0x1UL << RCC_APB1ENR1_I2C3EN_Pos)/*!< 0x40000000 */
#define RCC_APB1ENR1_I2C3EN RCC_APB1ENR1_I2C3EN_Msk
#define RCC_APB1ENR1_LPTIM1EN_Pos (31U)
#define RCC_APB1ENR1_LPTIM1EN_Msk (0x1UL << RCC_APB1ENR1_LPTIM1EN_Pos)/*!< 0x80000000 */
#define RCC_APB1ENR1_LPTIM1EN RCC_APB1ENR1_LPTIM1EN_Msk
/******************** Bit definition for RCC_APB1RSTR2 register **************/
#define RCC_APB1ENR2_LPUART1EN_Pos (0U)
#define RCC_APB1ENR2_LPUART1EN_Msk (0x1UL << RCC_APB1ENR2_LPUART1EN_Pos)/*!< 0x00000001 */
#define RCC_APB1ENR2_LPUART1EN RCC_APB1ENR2_LPUART1EN_Msk
#define RCC_APB1ENR2_UCPD1EN_Pos (8U)
#define RCC_APB1ENR2_UCPD1EN_Msk (0x1UL << RCC_APB1ENR2_UCPD1EN_Pos)/*!< 0x00000100 */
#define RCC_APB1ENR2_UCPD1EN RCC_APB1ENR2_UCPD1EN_Msk
/******************** Bit definition for RCC_APB2ENR register ***************/
#define RCC_APB2ENR_SYSCFGEN_Pos (0U)
#define RCC_APB2ENR_SYSCFGEN_Msk (0x1UL << RCC_APB2ENR_SYSCFGEN_Pos)/*!< 0x00000001 */
#define RCC_APB2ENR_SYSCFGEN RCC_APB2ENR_SYSCFGEN_Msk
#define RCC_APB2ENR_TIM1EN_Pos (11U)
#define RCC_APB2ENR_TIM1EN_Msk (0x1UL << RCC_APB2ENR_TIM1EN_Pos) /*!< 0x00000800 */
#define RCC_APB2ENR_TIM1EN RCC_APB2ENR_TIM1EN_Msk
#define RCC_APB2ENR_SPI1EN_Pos (12U)
#define RCC_APB2ENR_SPI1EN_Msk (0x1UL << RCC_APB2ENR_SPI1EN_Pos) /*!< 0x00001000 */
#define RCC_APB2ENR_SPI1EN RCC_APB2ENR_SPI1EN_Msk
#define RCC_APB2ENR_TIM8EN_Pos (13U)
#define RCC_APB2ENR_TIM8EN_Msk (0x1UL << RCC_APB2ENR_TIM8EN_Pos) /*!< 0x00002000 */
#define RCC_APB2ENR_TIM8EN RCC_APB2ENR_TIM8EN_Msk
#define RCC_APB2ENR_USART1EN_Pos (14U)
#define RCC_APB2ENR_USART1EN_Msk (0x1UL << RCC_APB2ENR_USART1EN_Pos)/*!< 0x00004000 */
#define RCC_APB2ENR_USART1EN RCC_APB2ENR_USART1EN_Msk
#define RCC_APB2ENR_TIM15EN_Pos (16U)
#define RCC_APB2ENR_TIM15EN_Msk (0x1UL << RCC_APB2ENR_TIM15EN_Pos)/*!< 0x00010000 */
#define RCC_APB2ENR_TIM15EN RCC_APB2ENR_TIM15EN_Msk
#define RCC_APB2ENR_TIM16EN_Pos (17U)
#define RCC_APB2ENR_TIM16EN_Msk (0x1UL << RCC_APB2ENR_TIM16EN_Pos)/*!< 0x00020000 */
#define RCC_APB2ENR_TIM16EN RCC_APB2ENR_TIM16EN_Msk
#define RCC_APB2ENR_TIM17EN_Pos (18U)
#define RCC_APB2ENR_TIM17EN_Msk (0x1UL << RCC_APB2ENR_TIM17EN_Pos)/*!< 0x00040000 */
#define RCC_APB2ENR_TIM17EN RCC_APB2ENR_TIM17EN_Msk
#define RCC_APB2ENR_SAI1EN_Pos (21U)
#define RCC_APB2ENR_SAI1EN_Msk (0x1UL << RCC_APB2ENR_SAI1EN_Pos)/*!< 0x00200000 */
#define RCC_APB2ENR_SAI1EN RCC_APB2ENR_SAI1EN_Msk
/******************** Bit definition for RCC_AHB1SMENR register ***************/
#define RCC_AHB1SMENR_DMA1SMEN_Pos (0U)
#define RCC_AHB1SMENR_DMA1SMEN_Msk (0x1UL << RCC_AHB1SMENR_DMA1SMEN_Pos)/*!< 0x00000001 */
#define RCC_AHB1SMENR_DMA1SMEN RCC_AHB1SMENR_DMA1SMEN_Msk
#define RCC_AHB1SMENR_DMA2SMEN_Pos (1U)
#define RCC_AHB1SMENR_DMA2SMEN_Msk (0x1UL << RCC_AHB1SMENR_DMA2SMEN_Pos)/*!< 0x00000002 */
#define RCC_AHB1SMENR_DMA2SMEN RCC_AHB1SMENR_DMA2SMEN_Msk
#define RCC_AHB1SMENR_DMAMUX1SMEN_Pos (2U)
#define RCC_AHB1SMENR_DMAMUX1SMEN_Msk (0x1UL << RCC_AHB1SMENR_DMAMUX1SMEN_Pos)/*!< 0x00000004 */
#define RCC_AHB1SMENR_DMAMUX1SMEN RCC_AHB1SMENR_DMAMUX1SMEN_Msk
#define RCC_AHB1SMENR_CORDICSMEN_Pos (3U)
#define RCC_AHB1SMENR_CORDICSMEN_Msk (0x1UL << RCC_AHB1SMENR_CORDICSMEN_Pos)/*!< 0x00000008 */
#define RCC_AHB1SMENR_CORDICSMEN RCC_AHB1SMENR_CORDICSMEN_Msk
#define RCC_AHB1SMENR_FMACSMEN_Pos (4U)
#define RCC_AHB1SMENR_FMACSMEN_Msk (0x1UL << RCC_AHB1SMENR_FMACSMEN_Pos) /*!< 0x00000010 */
#define RCC_AHB1SMENR_FMACSMEN RCC_AHB1SMENR_FMACSMEN_Msk
#define RCC_AHB1SMENR_FLASHSMEN_Pos (8U)
#define RCC_AHB1SMENR_FLASHSMEN_Msk (0x1UL << RCC_AHB1SMENR_FLASHSMEN_Pos)/*!< 0x00000100 */
#define RCC_AHB1SMENR_FLASHSMEN RCC_AHB1SMENR_FLASHSMEN_Msk
#define RCC_AHB1SMENR_SRAM1SMEN_Pos (9U)
#define RCC_AHB1SMENR_SRAM1SMEN_Msk (0x1UL << RCC_AHB1SMENR_SRAM1SMEN_Pos)/*!< 0x00000200 */
#define RCC_AHB1SMENR_SRAM1SMEN RCC_AHB1SMENR_SRAM1SMEN_Msk
#define RCC_AHB1SMENR_CRCSMEN_Pos (12U)
#define RCC_AHB1SMENR_CRCSMEN_Msk (0x1UL << RCC_AHB1SMENR_CRCSMEN_Pos)/*!< 0x00001000 */
#define RCC_AHB1SMENR_CRCSMEN RCC_AHB1SMENR_CRCSMEN_Msk
/******************** Bit definition for RCC_AHB2SMENR register *************/
#define RCC_AHB2SMENR_GPIOASMEN_Pos (0U)
#define RCC_AHB2SMENR_GPIOASMEN_Msk (0x1UL << RCC_AHB2SMENR_GPIOASMEN_Pos)/*!< 0x00000001 */
#define RCC_AHB2SMENR_GPIOASMEN RCC_AHB2SMENR_GPIOASMEN_Msk
#define RCC_AHB2SMENR_GPIOBSMEN_Pos (1U)
#define RCC_AHB2SMENR_GPIOBSMEN_Msk (0x1UL << RCC_AHB2SMENR_GPIOBSMEN_Pos)/*!< 0x00000002 */
#define RCC_AHB2SMENR_GPIOBSMEN RCC_AHB2SMENR_GPIOBSMEN_Msk
#define RCC_AHB2SMENR_GPIOCSMEN_Pos (2U)
#define RCC_AHB2SMENR_GPIOCSMEN_Msk (0x1UL << RCC_AHB2SMENR_GPIOCSMEN_Pos)/*!< 0x00000004 */
#define RCC_AHB2SMENR_GPIOCSMEN RCC_AHB2SMENR_GPIOCSMEN_Msk
#define RCC_AHB2SMENR_GPIODSMEN_Pos (3U)
#define RCC_AHB2SMENR_GPIODSMEN_Msk (0x1UL << RCC_AHB2SMENR_GPIODSMEN_Pos)/*!< 0x00000008 */
#define RCC_AHB2SMENR_GPIODSMEN RCC_AHB2SMENR_GPIODSMEN_Msk
#define RCC_AHB2SMENR_GPIOESMEN_Pos (4U)
#define RCC_AHB2SMENR_GPIOESMEN_Msk (0x1UL << RCC_AHB2SMENR_GPIOESMEN_Pos)/*!< 0x00000010 */
#define RCC_AHB2SMENR_GPIOESMEN RCC_AHB2SMENR_GPIOESMEN_Msk
#define RCC_AHB2SMENR_GPIOFSMEN_Pos (5U)
#define RCC_AHB2SMENR_GPIOFSMEN_Msk (0x1UL << RCC_AHB2SMENR_GPIOFSMEN_Pos)/*!< 0x00000020 */
#define RCC_AHB2SMENR_GPIOFSMEN RCC_AHB2SMENR_GPIOFSMEN_Msk
#define RCC_AHB2SMENR_GPIOGSMEN_Pos (6U)
#define RCC_AHB2SMENR_GPIOGSMEN_Msk (0x1UL << RCC_AHB2SMENR_GPIOGSMEN_Pos)/*!< 0x00000040 */
#define RCC_AHB2SMENR_GPIOGSMEN RCC_AHB2SMENR_GPIOGSMEN_Msk
#define RCC_AHB2SMENR_CCMSRAMSMEN_Pos (9U)
#define RCC_AHB2SMENR_CCMSRAMSMEN_Msk (0x1UL << RCC_AHB2SMENR_CCMSRAMSMEN_Pos) /*!< 0x00000200 */
#define RCC_AHB2SMENR_CCMSRAMSMEN RCC_AHB2SMENR_CCMSRAMSMEN_Msk
#define RCC_AHB2SMENR_SRAM2SMEN_Pos (10U)
#define RCC_AHB2SMENR_SRAM2SMEN_Msk (0x1UL << RCC_AHB2SMENR_SRAM2SMEN_Pos)/*!< 0x00000400 */
#define RCC_AHB2SMENR_SRAM2SMEN RCC_AHB2SMENR_SRAM2SMEN_Msk
#define RCC_AHB2SMENR_ADC12SMEN_Pos (13U)
#define RCC_AHB2SMENR_ADC12SMEN_Msk (0x1UL << RCC_AHB2SMENR_ADC12SMEN_Pos)/*!< 0x00002000 */
#define RCC_AHB2SMENR_ADC12SMEN RCC_AHB2SMENR_ADC12SMEN_Msk
#define RCC_AHB2SMENR_DAC1SMEN_Pos (16U)
#define RCC_AHB2SMENR_DAC1SMEN_Msk (0x1UL << RCC_AHB2SMENR_DAC1SMEN_Pos)/*!< 0x00010000 */
#define RCC_AHB2SMENR_DAC1SMEN RCC_AHB2SMENR_DAC1SMEN_Msk
#define RCC_AHB2SMENR_DAC3SMEN_Pos (18U)
#define RCC_AHB2SMENR_DAC3SMEN_Msk (0x1UL << RCC_AHB2SMENR_DAC3SMEN_Pos)/*!< 0x00040000 */
#define RCC_AHB2SMENR_DAC3SMEN RCC_AHB2SMENR_DAC3SMEN_Msk
#define RCC_AHB2SMENR_RNGSMEN_Pos (26U)
#define RCC_AHB2SMENR_RNGSMEN_Msk (0x1UL << RCC_AHB2SMENR_RNGSMEN_Pos)/*!< 0x04000000 */
#define RCC_AHB2SMENR_RNGSMEN RCC_AHB2SMENR_RNGSMEN_Msk
/******************** Bit definition for RCC_AHB3SMENR register *************/
/******************** Bit definition for RCC_APB1SMENR1 register *************/
#define RCC_APB1SMENR1_TIM2SMEN_Pos (0U)
#define RCC_APB1SMENR1_TIM2SMEN_Msk (0x1UL << RCC_APB1SMENR1_TIM2SMEN_Pos)/*!< 0x00000001 */
#define RCC_APB1SMENR1_TIM2SMEN RCC_APB1SMENR1_TIM2SMEN_Msk
#define RCC_APB1SMENR1_TIM3SMEN_Pos (1U)
#define RCC_APB1SMENR1_TIM3SMEN_Msk (0x1UL << RCC_APB1SMENR1_TIM3SMEN_Pos)/*!< 0x00000002 */
#define RCC_APB1SMENR1_TIM3SMEN RCC_APB1SMENR1_TIM3SMEN_Msk
#define RCC_APB1SMENR1_TIM4SMEN_Pos (2U)
#define RCC_APB1SMENR1_TIM4SMEN_Msk (0x1UL << RCC_APB1SMENR1_TIM4SMEN_Pos)/*!< 0x00000004 */
#define RCC_APB1SMENR1_TIM4SMEN RCC_APB1SMENR1_TIM4SMEN_Msk
#define RCC_APB1SMENR1_TIM6SMEN_Pos (4U)
#define RCC_APB1SMENR1_TIM6SMEN_Msk (0x1UL << RCC_APB1SMENR1_TIM6SMEN_Pos)/*!< 0x00000010 */
#define RCC_APB1SMENR1_TIM6SMEN RCC_APB1SMENR1_TIM6SMEN_Msk
#define RCC_APB1SMENR1_TIM7SMEN_Pos (5U)
#define RCC_APB1SMENR1_TIM7SMEN_Msk (0x1UL << RCC_APB1SMENR1_TIM7SMEN_Pos)/*!< 0x00000020 */
#define RCC_APB1SMENR1_TIM7SMEN RCC_APB1SMENR1_TIM7SMEN_Msk
#define RCC_APB1SMENR1_CRSSMEN_Pos (8U)
#define RCC_APB1SMENR1_CRSSMEN_Msk (0x1UL << RCC_APB1SMENR1_CRSSMEN_Pos)/*!< 0x00000100 */
#define RCC_APB1SMENR1_CRSSMEN RCC_APB1SMENR1_CRSSMEN_Msk
#define RCC_APB1SMENR1_RTCAPBSMEN_Pos (10U)
#define RCC_APB1SMENR1_RTCAPBSMEN_Msk (0x1UL << RCC_APB1SMENR1_RTCAPBSMEN_Pos)/*!< 0x00000400 */
#define RCC_APB1SMENR1_RTCAPBSMEN RCC_APB1SMENR1_RTCAPBSMEN_Msk
#define RCC_APB1SMENR1_WWDGSMEN_Pos (11U)
#define RCC_APB1SMENR1_WWDGSMEN_Msk (0x1UL << RCC_APB1SMENR1_WWDGSMEN_Pos)/*!< 0x00000800 */
#define RCC_APB1SMENR1_WWDGSMEN RCC_APB1SMENR1_WWDGSMEN_Msk
#define RCC_APB1SMENR1_SPI2SMEN_Pos (14U)
#define RCC_APB1SMENR1_SPI2SMEN_Msk (0x1UL << RCC_APB1SMENR1_SPI2SMEN_Pos)/*!< 0x00004000 */
#define RCC_APB1SMENR1_SPI2SMEN RCC_APB1SMENR1_SPI2SMEN_Msk
#define RCC_APB1SMENR1_SPI3SMEN_Pos (15U)
#define RCC_APB1SMENR1_SPI3SMEN_Msk (0x1UL << RCC_APB1SMENR1_SPI3SMEN_Pos)/*!< 0x00008000 */
#define RCC_APB1SMENR1_SPI3SMEN RCC_APB1SMENR1_SPI3SMEN_Msk
#define RCC_APB1SMENR1_USART2SMEN_Pos (17U)
#define RCC_APB1SMENR1_USART2SMEN_Msk (0x1UL << RCC_APB1SMENR1_USART2SMEN_Pos)/*!< 0x00020000 */
#define RCC_APB1SMENR1_USART2SMEN RCC_APB1SMENR1_USART2SMEN_Msk
#define RCC_APB1SMENR1_USART3SMEN_Pos (18U)
#define RCC_APB1SMENR1_USART3SMEN_Msk (0x1UL << RCC_APB1SMENR1_USART3SMEN_Pos)/*!< 0x00040000 */
#define RCC_APB1SMENR1_USART3SMEN RCC_APB1SMENR1_USART3SMEN_Msk
#define RCC_APB1SMENR1_UART4SMEN_Pos (19U)
#define RCC_APB1SMENR1_UART4SMEN_Msk (0x1UL << RCC_APB1SMENR1_UART4SMEN_Pos)/*!< 0x00080000 */
#define RCC_APB1SMENR1_UART4SMEN RCC_APB1SMENR1_UART4SMEN_Msk
#define RCC_APB1SMENR1_I2C1SMEN_Pos (21U)
#define RCC_APB1SMENR1_I2C1SMEN_Msk (0x1UL << RCC_APB1SMENR1_I2C1SMEN_Pos)/*!< 0x00200000 */
#define RCC_APB1SMENR1_I2C1SMEN RCC_APB1SMENR1_I2C1SMEN_Msk
#define RCC_APB1SMENR1_I2C2SMEN_Pos (22U)
#define RCC_APB1SMENR1_I2C2SMEN_Msk (0x1UL << RCC_APB1SMENR1_I2C2SMEN_Pos)/*!< 0x00400000 */
#define RCC_APB1SMENR1_I2C2SMEN RCC_APB1SMENR1_I2C2SMEN_Msk
#define RCC_APB1SMENR1_USBSMEN_Pos (23U)
#define RCC_APB1SMENR1_USBSMEN_Msk (0x1UL << RCC_APB1SMENR1_USBSMEN_Pos)/*!< 0x00800000 */
#define RCC_APB1SMENR1_USBSMEN RCC_APB1SMENR1_USBSMEN_Msk
#define RCC_APB1SMENR1_FDCANSMEN_Pos (25U)
#define RCC_APB1SMENR1_FDCANSMEN_Msk (0x1UL << RCC_APB1SMENR1_FDCANSMEN_Pos)/*!< 0x02000000 */
#define RCC_APB1SMENR1_FDCANSMEN RCC_APB1SMENR1_FDCANSMEN_Msk
#define RCC_APB1SMENR1_PWRSMEN_Pos (28U)
#define RCC_APB1SMENR1_PWRSMEN_Msk (0x1UL << RCC_APB1SMENR1_PWRSMEN_Pos)/*!< 0x10000000 */
#define RCC_APB1SMENR1_PWRSMEN RCC_APB1SMENR1_PWRSMEN_Msk
#define RCC_APB1SMENR1_I2C3SMEN_Pos (30U)
#define RCC_APB1SMENR1_I2C3SMEN_Msk (0x1UL << RCC_APB1SMENR1_I2C3SMEN_Pos)/*!< 0x40000000 */
#define RCC_APB1SMENR1_I2C3SMEN RCC_APB1SMENR1_I2C3SMEN_Msk
#define RCC_APB1SMENR1_LPTIM1SMEN_Pos (31U)
#define RCC_APB1SMENR1_LPTIM1SMEN_Msk (0x1UL << RCC_APB1SMENR1_LPTIM1SMEN_Pos)/*!< 0x80000000 */
#define RCC_APB1SMENR1_LPTIM1SMEN RCC_APB1SMENR1_LPTIM1SMEN_Msk
/******************** Bit definition for RCC_APB1SMENR2 register *************/
#define RCC_APB1SMENR2_LPUART1SMEN_Pos (0U)
#define RCC_APB1SMENR2_LPUART1SMEN_Msk (0x1UL << RCC_APB1SMENR2_LPUART1SMEN_Pos)/*!< 0x00000001 */
#define RCC_APB1SMENR2_LPUART1SMEN RCC_APB1SMENR2_LPUART1SMEN_Msk
#define RCC_APB1SMENR2_UCPD1SMEN_Pos (8U)
#define RCC_APB1SMENR2_UCPD1SMEN_Msk (0x1UL << RCC_APB1SMENR2_UCPD1SMEN_Pos)/*!< 0x00000100 */
#define RCC_APB1SMENR2_UCPD1SMEN RCC_APB1SMENR2_UCPD1SMEN_Msk
/******************** Bit definition for RCC_APB2SMENR register *************/
#define RCC_APB2SMENR_SYSCFGSMEN_Pos (0U)
#define RCC_APB2SMENR_SYSCFGSMEN_Msk (0x1UL << RCC_APB2SMENR_SYSCFGSMEN_Pos)/*!< 0x00000001 */
#define RCC_APB2SMENR_SYSCFGSMEN RCC_APB2SMENR_SYSCFGSMEN_Msk
#define RCC_APB2SMENR_TIM1SMEN_Pos (11U)
#define RCC_APB2SMENR_TIM1SMEN_Msk (0x1UL << RCC_APB2SMENR_TIM1SMEN_Pos)/*!< 0x00000800 */
#define RCC_APB2SMENR_TIM1SMEN RCC_APB2SMENR_TIM1SMEN_Msk
#define RCC_APB2SMENR_SPI1SMEN_Pos (12U)
#define RCC_APB2SMENR_SPI1SMEN_Msk (0x1UL << RCC_APB2SMENR_SPI1SMEN_Pos)/*!< 0x00001000 */
#define RCC_APB2SMENR_SPI1SMEN RCC_APB2SMENR_SPI1SMEN_Msk
#define RCC_APB2SMENR_TIM8SMEN_Pos (13U)
#define RCC_APB2SMENR_TIM8SMEN_Msk (0x1UL << RCC_APB2SMENR_TIM8SMEN_Pos)/*!< 0x00002000 */
#define RCC_APB2SMENR_TIM8SMEN RCC_APB2SMENR_TIM8SMEN_Msk
#define RCC_APB2SMENR_USART1SMEN_Pos (14U)
#define RCC_APB2SMENR_USART1SMEN_Msk (0x1UL << RCC_APB2SMENR_USART1SMEN_Pos)/*!< 0x00004000 */
#define RCC_APB2SMENR_USART1SMEN RCC_APB2SMENR_USART1SMEN_Msk
#define RCC_APB2SMENR_TIM15SMEN_Pos (16U)
#define RCC_APB2SMENR_TIM15SMEN_Msk (0x1UL << RCC_APB2SMENR_TIM15SMEN_Pos)/*!< 0x00010000 */
#define RCC_APB2SMENR_TIM15SMEN RCC_APB2SMENR_TIM15SMEN_Msk
#define RCC_APB2SMENR_TIM16SMEN_Pos (17U)
#define RCC_APB2SMENR_TIM16SMEN_Msk (0x1UL << RCC_APB2SMENR_TIM16SMEN_Pos)/*!< 0x00020000 */
#define RCC_APB2SMENR_TIM16SMEN RCC_APB2SMENR_TIM16SMEN_Msk
#define RCC_APB2SMENR_TIM17SMEN_Pos (18U)
#define RCC_APB2SMENR_TIM17SMEN_Msk (0x1UL << RCC_APB2SMENR_TIM17SMEN_Pos)/*!< 0x00040000 */
#define RCC_APB2SMENR_TIM17SMEN RCC_APB2SMENR_TIM17SMEN_Msk
#define RCC_APB2SMENR_SAI1SMEN_Pos (21U)
#define RCC_APB2SMENR_SAI1SMEN_Msk (0x1UL << RCC_APB2SMENR_SAI1SMEN_Pos)/*!< 0x00200000 */
#define RCC_APB2SMENR_SAI1SMEN RCC_APB2SMENR_SAI1SMEN_Msk
/******************** Bit definition for RCC_CCIPR register ******************/
#define RCC_CCIPR_USART1SEL_Pos (0U)
#define RCC_CCIPR_USART1SEL_Msk (0x3UL << RCC_CCIPR_USART1SEL_Pos)/*!< 0x00000003 */
#define RCC_CCIPR_USART1SEL RCC_CCIPR_USART1SEL_Msk
#define RCC_CCIPR_USART1SEL_0 (0x1UL << RCC_CCIPR_USART1SEL_Pos)/*!< 0x00000001 */
#define RCC_CCIPR_USART1SEL_1 (0x2UL << RCC_CCIPR_USART1SEL_Pos)/*!< 0x00000002 */
#define RCC_CCIPR_USART2SEL_Pos (2U)
#define RCC_CCIPR_USART2SEL_Msk (0x3UL << RCC_CCIPR_USART2SEL_Pos)/*!< 0x0000000C */
#define RCC_CCIPR_USART2SEL RCC_CCIPR_USART2SEL_Msk
#define RCC_CCIPR_USART2SEL_0 (0x1UL << RCC_CCIPR_USART2SEL_Pos)/*!< 0x00000004 */
#define RCC_CCIPR_USART2SEL_1 (0x2UL << RCC_CCIPR_USART2SEL_Pos)/*!< 0x00000008 */
#define RCC_CCIPR_USART3SEL_Pos (4U)
#define RCC_CCIPR_USART3SEL_Msk (0x3UL << RCC_CCIPR_USART3SEL_Pos)/*!< 0x00000030 */
#define RCC_CCIPR_USART3SEL RCC_CCIPR_USART3SEL_Msk
#define RCC_CCIPR_USART3SEL_0 (0x1UL << RCC_CCIPR_USART3SEL_Pos)/*!< 0x00000010 */
#define RCC_CCIPR_USART3SEL_1 (0x2UL << RCC_CCIPR_USART3SEL_Pos)/*!< 0x00000020 */
#define RCC_CCIPR_UART4SEL_Pos (6U)
#define RCC_CCIPR_UART4SEL_Msk (0x3UL << RCC_CCIPR_UART4SEL_Pos) /*!< 0x000000C0 */
#define RCC_CCIPR_UART4SEL RCC_CCIPR_UART4SEL_Msk
#define RCC_CCIPR_UART4SEL_0 (0x1UL << RCC_CCIPR_UART4SEL_Pos) /*!< 0x00000040 */
#define RCC_CCIPR_UART4SEL_1 (0x2UL << RCC_CCIPR_UART4SEL_Pos) /*!< 0x00000080 */
#define RCC_CCIPR_LPUART1SEL_Pos (10U)
#define RCC_CCIPR_LPUART1SEL_Msk (0x3UL << RCC_CCIPR_LPUART1SEL_Pos)/*!< 0x00000C00 */
#define RCC_CCIPR_LPUART1SEL RCC_CCIPR_LPUART1SEL_Msk
#define RCC_CCIPR_LPUART1SEL_0 (0x1UL << RCC_CCIPR_LPUART1SEL_Pos)/*!< 0x00000400 */
#define RCC_CCIPR_LPUART1SEL_1 (0x2UL << RCC_CCIPR_LPUART1SEL_Pos)/*!< 0x00000800 */
#define RCC_CCIPR_I2C1SEL_Pos (12U)
#define RCC_CCIPR_I2C1SEL_Msk (0x3UL << RCC_CCIPR_I2C1SEL_Pos) /*!< 0x00003000 */
#define RCC_CCIPR_I2C1SEL RCC_CCIPR_I2C1SEL_Msk
#define RCC_CCIPR_I2C1SEL_0 (0x1UL << RCC_CCIPR_I2C1SEL_Pos) /*!< 0x00001000 */
#define RCC_CCIPR_I2C1SEL_1 (0x2UL << RCC_CCIPR_I2C1SEL_Pos) /*!< 0x00002000 */
#define RCC_CCIPR_I2C2SEL_Pos (14U)
#define RCC_CCIPR_I2C2SEL_Msk (0x3UL << RCC_CCIPR_I2C2SEL_Pos) /*!< 0x0000C000 */
#define RCC_CCIPR_I2C2SEL RCC_CCIPR_I2C2SEL_Msk
#define RCC_CCIPR_I2C2SEL_0 (0x1UL << RCC_CCIPR_I2C2SEL_Pos) /*!< 0x00004000 */
#define RCC_CCIPR_I2C2SEL_1 (0x2UL << RCC_CCIPR_I2C2SEL_Pos) /*!< 0x00008000 */
#define RCC_CCIPR_I2C3SEL_Pos (16U)
#define RCC_CCIPR_I2C3SEL_Msk (0x3UL << RCC_CCIPR_I2C3SEL_Pos) /*!< 0x00030000 */
#define RCC_CCIPR_I2C3SEL RCC_CCIPR_I2C3SEL_Msk
#define RCC_CCIPR_I2C3SEL_0 (0x1UL << RCC_CCIPR_I2C3SEL_Pos) /*!< 0x00010000 */
#define RCC_CCIPR_I2C3SEL_1 (0x2UL << RCC_CCIPR_I2C3SEL_Pos) /*!< 0x00020000 */
#define RCC_CCIPR_LPTIM1SEL_Pos (18U)
#define RCC_CCIPR_LPTIM1SEL_Msk (0x3UL << RCC_CCIPR_LPTIM1SEL_Pos)/*!< 0x000C0000 */
#define RCC_CCIPR_LPTIM1SEL RCC_CCIPR_LPTIM1SEL_Msk
#define RCC_CCIPR_LPTIM1SEL_0 (0x1UL << RCC_CCIPR_LPTIM1SEL_Pos)/*!< 0x00040000 */
#define RCC_CCIPR_LPTIM1SEL_1 (0x2UL << RCC_CCIPR_LPTIM1SEL_Pos)/*!< 0x00080000 */
#define RCC_CCIPR_SAI1SEL_Pos (20U)
#define RCC_CCIPR_SAI1SEL_Msk (0x3UL << RCC_CCIPR_SAI1SEL_Pos)/*!< 0x00300000 */
#define RCC_CCIPR_SAI1SEL RCC_CCIPR_SAI1SEL_Msk
#define RCC_CCIPR_SAI1SEL_0 (0x1UL << RCC_CCIPR_SAI1SEL_Pos)/*!< 0x00100000 */
#define RCC_CCIPR_SAI1SEL_1 (0x2UL << RCC_CCIPR_SAI1SEL_Pos)/*!< 0x00200000 */
#define RCC_CCIPR_I2S23SEL_Pos (22U)
#define RCC_CCIPR_I2S23SEL_Msk (0x3UL << RCC_CCIPR_I2S23SEL_Pos)/*!< 0x00C00000 */
#define RCC_CCIPR_I2S23SEL RCC_CCIPR_I2S23SEL_Msk
#define RCC_CCIPR_I2S23SEL_0 (0x1UL << RCC_CCIPR_I2S23SEL_Pos)/*!< 0x00400000 */
#define RCC_CCIPR_I2S23SEL_1 (0x2UL << RCC_CCIPR_I2S23SEL_Pos)/*!< 0x00800000 */
#define RCC_CCIPR_FDCANSEL_Pos (24U)
#define RCC_CCIPR_FDCANSEL_Msk (0x3UL << RCC_CCIPR_FDCANSEL_Pos) /*!< 0x03000000 */
#define RCC_CCIPR_FDCANSEL RCC_CCIPR_FDCANSEL_Msk
#define RCC_CCIPR_FDCANSEL_0 (0x1UL << RCC_CCIPR_FDCANSEL_Pos) /*!< 0x01000000 */
#define RCC_CCIPR_FDCANSEL_1 (0x2UL << RCC_CCIPR_FDCANSEL_Pos) /*!< 0x02000000 */
#define RCC_CCIPR_CLK48SEL_Pos (26U)
#define RCC_CCIPR_CLK48SEL_Msk (0x3UL << RCC_CCIPR_CLK48SEL_Pos) /*!< 0x0C000000 */
#define RCC_CCIPR_CLK48SEL RCC_CCIPR_CLK48SEL_Msk
#define RCC_CCIPR_CLK48SEL_0 (0x1UL << RCC_CCIPR_CLK48SEL_Pos) /*!< 0x04000000 */
#define RCC_CCIPR_CLK48SEL_1 (0x2UL << RCC_CCIPR_CLK48SEL_Pos) /*!< 0x08000000 */
#define RCC_CCIPR_ADC12SEL_Pos (28U)
#define RCC_CCIPR_ADC12SEL_Msk (0x3UL << RCC_CCIPR_ADC12SEL_Pos) /*!< 0x30000000 */
#define RCC_CCIPR_ADC12SEL RCC_CCIPR_ADC12SEL_Msk
#define RCC_CCIPR_ADC12SEL_0 (0x1UL << RCC_CCIPR_ADC12SEL_Pos) /*!< 0x10000000 */
#define RCC_CCIPR_ADC12SEL_1 (0x2UL << RCC_CCIPR_ADC12SEL_Pos) /*!< 0x20000000 */
/******************** Bit definition for RCC_BDCR register ******************/
#define RCC_BDCR_LSEON_Pos (0U)
#define RCC_BDCR_LSEON_Msk (0x1UL << RCC_BDCR_LSEON_Pos) /*!< 0x00000001 */
#define RCC_BDCR_LSEON RCC_BDCR_LSEON_Msk
#define RCC_BDCR_LSERDY_Pos (1U)
#define RCC_BDCR_LSERDY_Msk (0x1UL << RCC_BDCR_LSERDY_Pos) /*!< 0x00000002 */
#define RCC_BDCR_LSERDY RCC_BDCR_LSERDY_Msk
#define RCC_BDCR_LSEBYP_Pos (2U)
#define RCC_BDCR_LSEBYP_Msk (0x1UL << RCC_BDCR_LSEBYP_Pos) /*!< 0x00000004 */
#define RCC_BDCR_LSEBYP RCC_BDCR_LSEBYP_Msk
#define RCC_BDCR_LSEDRV_Pos (3U)
#define RCC_BDCR_LSEDRV_Msk (0x3UL << RCC_BDCR_LSEDRV_Pos) /*!< 0x00000018 */
#define RCC_BDCR_LSEDRV RCC_BDCR_LSEDRV_Msk
#define RCC_BDCR_LSEDRV_0 (0x1UL << RCC_BDCR_LSEDRV_Pos) /*!< 0x00000008 */
#define RCC_BDCR_LSEDRV_1 (0x2UL << RCC_BDCR_LSEDRV_Pos) /*!< 0x00000010 */
#define RCC_BDCR_LSECSSON_Pos (5U)
#define RCC_BDCR_LSECSSON_Msk (0x1UL << RCC_BDCR_LSECSSON_Pos) /*!< 0x00000020 */
#define RCC_BDCR_LSECSSON RCC_BDCR_LSECSSON_Msk
#define RCC_BDCR_LSECSSD_Pos (6U)
#define RCC_BDCR_LSECSSD_Msk (0x1UL << RCC_BDCR_LSECSSD_Pos) /*!< 0x00000040 */
#define RCC_BDCR_LSECSSD RCC_BDCR_LSECSSD_Msk
#define RCC_BDCR_RTCSEL_Pos (8U)
#define RCC_BDCR_RTCSEL_Msk (0x3UL << RCC_BDCR_RTCSEL_Pos) /*!< 0x00000300 */
#define RCC_BDCR_RTCSEL RCC_BDCR_RTCSEL_Msk
#define RCC_BDCR_RTCSEL_0 (0x1UL << RCC_BDCR_RTCSEL_Pos) /*!< 0x00000100 */
#define RCC_BDCR_RTCSEL_1 (0x2UL << RCC_BDCR_RTCSEL_Pos) /*!< 0x00000200 */
#define RCC_BDCR_RTCEN_Pos (15U)
#define RCC_BDCR_RTCEN_Msk (0x1UL << RCC_BDCR_RTCEN_Pos) /*!< 0x00008000 */
#define RCC_BDCR_RTCEN RCC_BDCR_RTCEN_Msk
#define RCC_BDCR_BDRST_Pos (16U)
#define RCC_BDCR_BDRST_Msk (0x1UL << RCC_BDCR_BDRST_Pos) /*!< 0x00010000 */
#define RCC_BDCR_BDRST RCC_BDCR_BDRST_Msk
#define RCC_BDCR_LSCOEN_Pos (24U)
#define RCC_BDCR_LSCOEN_Msk (0x1UL << RCC_BDCR_LSCOEN_Pos) /*!< 0x01000000 */
#define RCC_BDCR_LSCOEN RCC_BDCR_LSCOEN_Msk
#define RCC_BDCR_LSCOSEL_Pos (25U)
#define RCC_BDCR_LSCOSEL_Msk (0x1UL << RCC_BDCR_LSCOSEL_Pos) /*!< 0x02000000 */
#define RCC_BDCR_LSCOSEL RCC_BDCR_LSCOSEL_Msk
/******************** Bit definition for RCC_CSR register *******************/
#define RCC_CSR_LSION_Pos (0U)
#define RCC_CSR_LSION_Msk (0x1UL << RCC_CSR_LSION_Pos) /*!< 0x00000001 */
#define RCC_CSR_LSION RCC_CSR_LSION_Msk
#define RCC_CSR_LSIRDY_Pos (1U)
#define RCC_CSR_LSIRDY_Msk (0x1UL << RCC_CSR_LSIRDY_Pos) /*!< 0x00000002 */
#define RCC_CSR_LSIRDY RCC_CSR_LSIRDY_Msk
#define RCC_CSR_RMVF_Pos (23U)
#define RCC_CSR_RMVF_Msk (0x1UL << RCC_CSR_RMVF_Pos) /*!< 0x00800000 */
#define RCC_CSR_RMVF RCC_CSR_RMVF_Msk
#define RCC_CSR_OBLRSTF_Pos (25U)
#define RCC_CSR_OBLRSTF_Msk (0x1UL << RCC_CSR_OBLRSTF_Pos) /*!< 0x02000000 */
#define RCC_CSR_OBLRSTF RCC_CSR_OBLRSTF_Msk
#define RCC_CSR_PINRSTF_Pos (26U)
#define RCC_CSR_PINRSTF_Msk (0x1UL << RCC_CSR_PINRSTF_Pos) /*!< 0x04000000 */
#define RCC_CSR_PINRSTF RCC_CSR_PINRSTF_Msk
#define RCC_CSR_BORRSTF_Pos (27U)
#define RCC_CSR_BORRSTF_Msk (0x1UL << RCC_CSR_BORRSTF_Pos) /*!< 0x08000000 */
#define RCC_CSR_BORRSTF RCC_CSR_BORRSTF_Msk
#define RCC_CSR_SFTRSTF_Pos (28U)
#define RCC_CSR_SFTRSTF_Msk (0x1UL << RCC_CSR_SFTRSTF_Pos) /*!< 0x10000000 */
#define RCC_CSR_SFTRSTF RCC_CSR_SFTRSTF_Msk
#define RCC_CSR_IWDGRSTF_Pos (29U)
#define RCC_CSR_IWDGRSTF_Msk (0x1UL << RCC_CSR_IWDGRSTF_Pos) /*!< 0x20000000 */
#define RCC_CSR_IWDGRSTF RCC_CSR_IWDGRSTF_Msk
#define RCC_CSR_WWDGRSTF_Pos (30U)
#define RCC_CSR_WWDGRSTF_Msk (0x1UL << RCC_CSR_WWDGRSTF_Pos) /*!< 0x40000000 */
#define RCC_CSR_WWDGRSTF RCC_CSR_WWDGRSTF_Msk
#define RCC_CSR_LPWRRSTF_Pos (31U)
#define RCC_CSR_LPWRRSTF_Msk (0x1UL << RCC_CSR_LPWRRSTF_Pos) /*!< 0x80000000 */
#define RCC_CSR_LPWRRSTF RCC_CSR_LPWRRSTF_Msk
/******************** Bit definition for RCC_CRRCR register *****************/
#define RCC_CRRCR_HSI48ON_Pos (0U)
#define RCC_CRRCR_HSI48ON_Msk (0x1UL << RCC_CRRCR_HSI48ON_Pos) /*!< 0x00000001 */
#define RCC_CRRCR_HSI48ON RCC_CRRCR_HSI48ON_Msk
#define RCC_CRRCR_HSI48RDY_Pos (1U)
#define RCC_CRRCR_HSI48RDY_Msk (0x1UL << RCC_CRRCR_HSI48RDY_Pos) /*!< 0x00000002 */
#define RCC_CRRCR_HSI48RDY RCC_CRRCR_HSI48RDY_Msk
/*!< HSI48CAL configuration */
#define RCC_CRRCR_HSI48CAL_Pos (7U)
#define RCC_CRRCR_HSI48CAL_Msk (0x1FFUL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x0000FF80 */
#define RCC_CRRCR_HSI48CAL RCC_CRRCR_HSI48CAL_Msk /*!< HSI48CAL[8:0] bits */
#define RCC_CRRCR_HSI48CAL_0 (0x001UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00000080 */
#define RCC_CRRCR_HSI48CAL_1 (0x002UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00000100 */
#define RCC_CRRCR_HSI48CAL_2 (0x004UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00000200 */
#define RCC_CRRCR_HSI48CAL_3 (0x008UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00000400 */
#define RCC_CRRCR_HSI48CAL_4 (0x010UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00000800 */
#define RCC_CRRCR_HSI48CAL_5 (0x020UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00001000 */
#define RCC_CRRCR_HSI48CAL_6 (0x040UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00002000 */
#define RCC_CRRCR_HSI48CAL_7 (0x080UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00004000 */
#define RCC_CRRCR_HSI48CAL_8 (0x100UL << RCC_CRRCR_HSI48CAL_Pos)/*!< 0x00008000 */
/******************** Bit definition for RCC_CCIPR2 register ******************/
/******************************************************************************/
/* */
/* RNG */
/* */
/******************************************************************************/
/******************** Bits definition for RNG_CR register *******************/
#define RNG_CR_RNGEN_Pos (2U)
#define RNG_CR_RNGEN_Msk (0x1UL << RNG_CR_RNGEN_Pos) /*!< 0x00000004 */
#define RNG_CR_RNGEN RNG_CR_RNGEN_Msk
#define RNG_CR_IE_Pos (3U)
#define RNG_CR_IE_Msk (0x1UL << RNG_CR_IE_Pos) /*!< 0x00000008 */
#define RNG_CR_IE RNG_CR_IE_Msk
#define RNG_CR_CED_Pos (5U)
#define RNG_CR_CED_Msk (0x1UL << RNG_CR_IE_Pos) /*!< 0x00000020 */
#define RNG_CR_CED RNG_CR_IE_Msk
/******************** Bits definition for RNG_SR register *******************/
#define RNG_SR_DRDY_Pos (0U)
#define RNG_SR_DRDY_Msk (0x1UL << RNG_SR_DRDY_Pos) /*!< 0x00000001 */
#define RNG_SR_DRDY RNG_SR_DRDY_Msk
#define RNG_SR_CECS_Pos (1U)
#define RNG_SR_CECS_Msk (0x1UL << RNG_SR_CECS_Pos) /*!< 0x00000002 */
#define RNG_SR_CECS RNG_SR_CECS_Msk
#define RNG_SR_SECS_Pos (2U)
#define RNG_SR_SECS_Msk (0x1UL << RNG_SR_SECS_Pos) /*!< 0x00000004 */
#define RNG_SR_SECS RNG_SR_SECS_Msk
#define RNG_SR_CEIS_Pos (5U)
#define RNG_SR_CEIS_Msk (0x1UL << RNG_SR_CEIS_Pos) /*!< 0x00000020 */
#define RNG_SR_CEIS RNG_SR_CEIS_Msk
#define RNG_SR_SEIS_Pos (6U)
#define RNG_SR_SEIS_Msk (0x1UL << RNG_SR_SEIS_Pos) /*!< 0x00000040 */
#define RNG_SR_SEIS RNG_SR_SEIS_Msk
/******************************************************************************/
/* */
/* Real-Time Clock (RTC) */
/* */
/******************************************************************************/
/******************** Bits definition for RTC_TR register *******************/
#define RTC_TR_PM_Pos (22U)
#define RTC_TR_PM_Msk (0x1UL << RTC_TR_PM_Pos) /*!< 0x00400000 */
#define RTC_TR_PM RTC_TR_PM_Msk
#define RTC_TR_HT_Pos (20U)
#define RTC_TR_HT_Msk (0x3UL << RTC_TR_HT_Pos) /*!< 0x00300000 */
#define RTC_TR_HT RTC_TR_HT_Msk
#define RTC_TR_HT_0 (0x1UL << RTC_TR_HT_Pos) /*!< 0x00100000 */
#define RTC_TR_HT_1 (0x2UL << RTC_TR_HT_Pos) /*!< 0x00200000 */
#define RTC_TR_HU_Pos (16U)
#define RTC_TR_HU_Msk (0xFUL << RTC_TR_HU_Pos) /*!< 0x000F0000 */
#define RTC_TR_HU RTC_TR_HU_Msk
#define RTC_TR_HU_0 (0x1UL << RTC_TR_HU_Pos) /*!< 0x00010000 */
#define RTC_TR_HU_1 (0x2UL << RTC_TR_HU_Pos) /*!< 0x00020000 */
#define RTC_TR_HU_2 (0x4UL << RTC_TR_HU_Pos) /*!< 0x00040000 */
#define RTC_TR_HU_3 (0x8UL << RTC_TR_HU_Pos) /*!< 0x00080000 */
#define RTC_TR_MNT_Pos (12U)
#define RTC_TR_MNT_Msk (0x7UL << RTC_TR_MNT_Pos) /*!< 0x00007000 */
#define RTC_TR_MNT RTC_TR_MNT_Msk
#define RTC_TR_MNT_0 (0x1UL << RTC_TR_MNT_Pos) /*!< 0x00001000 */
#define RTC_TR_MNT_1 (0x2UL << RTC_TR_MNT_Pos) /*!< 0x00002000 */
#define RTC_TR_MNT_2 (0x4UL << RTC_TR_MNT_Pos) /*!< 0x00004000 */
#define RTC_TR_MNU_Pos (8U)
#define RTC_TR_MNU_Msk (0xFUL << RTC_TR_MNU_Pos) /*!< 0x00000F00 */
#define RTC_TR_MNU RTC_TR_MNU_Msk
#define RTC_TR_MNU_0 (0x1UL << RTC_TR_MNU_Pos) /*!< 0x00000100 */
#define RTC_TR_MNU_1 (0x2UL << RTC_TR_MNU_Pos) /*!< 0x00000200 */
#define RTC_TR_MNU_2 (0x4UL << RTC_TR_MNU_Pos) /*!< 0x00000400 */
#define RTC_TR_MNU_3 (0x8UL << RTC_TR_MNU_Pos) /*!< 0x00000800 */
#define RTC_TR_ST_Pos (4U)
#define RTC_TR_ST_Msk (0x7UL << RTC_TR_ST_Pos) /*!< 0x00000070 */
#define RTC_TR_ST RTC_TR_ST_Msk
#define RTC_TR_ST_0 (0x1UL << RTC_TR_ST_Pos) /*!< 0x00000010 */
#define RTC_TR_ST_1 (0x2UL << RTC_TR_ST_Pos) /*!< 0x00000020 */
#define RTC_TR_ST_2 (0x4UL << RTC_TR_ST_Pos) /*!< 0x00000040 */
#define RTC_TR_SU_Pos (0U)
#define RTC_TR_SU_Msk (0xFUL << RTC_TR_SU_Pos) /*!< 0x0000000F */
#define RTC_TR_SU RTC_TR_SU_Msk
#define RTC_TR_SU_0 (0x1UL << RTC_TR_SU_Pos) /*!< 0x00000001 */
#define RTC_TR_SU_1 (0x2UL << RTC_TR_SU_Pos) /*!< 0x00000002 */
#define RTC_TR_SU_2 (0x4UL << RTC_TR_SU_Pos) /*!< 0x00000004 */
#define RTC_TR_SU_3 (0x8UL << RTC_TR_SU_Pos) /*!< 0x00000008 */
/******************** Bits definition for RTC_DR register *******************/
#define RTC_DR_YT_Pos (20U)
#define RTC_DR_YT_Msk (0xFUL << RTC_DR_YT_Pos) /*!< 0x00F00000 */
#define RTC_DR_YT RTC_DR_YT_Msk
#define RTC_DR_YT_0 (0x1UL << RTC_DR_YT_Pos) /*!< 0x00100000 */
#define RTC_DR_YT_1 (0x2UL << RTC_DR_YT_Pos) /*!< 0x00200000 */
#define RTC_DR_YT_2 (0x4UL << RTC_DR_YT_Pos) /*!< 0x00400000 */
#define RTC_DR_YT_3 (0x8UL << RTC_DR_YT_Pos) /*!< 0x00800000 */
#define RTC_DR_YU_Pos (16U)
#define RTC_DR_YU_Msk (0xFUL << RTC_DR_YU_Pos) /*!< 0x000F0000 */
#define RTC_DR_YU RTC_DR_YU_Msk
#define RTC_DR_YU_0 (0x1UL << RTC_DR_YU_Pos) /*!< 0x00010000 */
#define RTC_DR_YU_1 (0x2UL << RTC_DR_YU_Pos) /*!< 0x00020000 */
#define RTC_DR_YU_2 (0x4UL << RTC_DR_YU_Pos) /*!< 0x00040000 */
#define RTC_DR_YU_3 (0x8UL << RTC_DR_YU_Pos) /*!< 0x00080000 */
#define RTC_DR_WDU_Pos (13U)
#define RTC_DR_WDU_Msk (0x7UL << RTC_DR_WDU_Pos) /*!< 0x0000E000 */
#define RTC_DR_WDU RTC_DR_WDU_Msk
#define RTC_DR_WDU_0 (0x1UL << RTC_DR_WDU_Pos) /*!< 0x00002000 */
#define RTC_DR_WDU_1 (0x2UL << RTC_DR_WDU_Pos) /*!< 0x00004000 */
#define RTC_DR_WDU_2 (0x4UL << RTC_DR_WDU_Pos) /*!< 0x00008000 */
#define RTC_DR_MT_Pos (12U)
#define RTC_DR_MT_Msk (0x1UL << RTC_DR_MT_Pos) /*!< 0x00001000 */
#define RTC_DR_MT RTC_DR_MT_Msk
#define RTC_DR_MU_Pos (8U)
#define RTC_DR_MU_Msk (0xFUL << RTC_DR_MU_Pos) /*!< 0x00000F00 */
#define RTC_DR_MU RTC_DR_MU_Msk
#define RTC_DR_MU_0 (0x1UL << RTC_DR_MU_Pos) /*!< 0x00000100 */
#define RTC_DR_MU_1 (0x2UL << RTC_DR_MU_Pos) /*!< 0x00000200 */
#define RTC_DR_MU_2 (0x4UL << RTC_DR_MU_Pos) /*!< 0x00000400 */
#define RTC_DR_MU_3 (0x8UL << RTC_DR_MU_Pos) /*!< 0x00000800 */
#define RTC_DR_DT_Pos (4U)
#define RTC_DR_DT_Msk (0x3UL << RTC_DR_DT_Pos) /*!< 0x00000030 */
#define RTC_DR_DT RTC_DR_DT_Msk
#define RTC_DR_DT_0 (0x1UL << RTC_DR_DT_Pos) /*!< 0x00000010 */
#define RTC_DR_DT_1 (0x2UL << RTC_DR_DT_Pos) /*!< 0x00000020 */
#define RTC_DR_DU_Pos (0U)
#define RTC_DR_DU_Msk (0xFUL << RTC_DR_DU_Pos) /*!< 0x0000000F */
#define RTC_DR_DU RTC_DR_DU_Msk
#define RTC_DR_DU_0 (0x1UL << RTC_DR_DU_Pos) /*!< 0x00000001 */
#define RTC_DR_DU_1 (0x2UL << RTC_DR_DU_Pos) /*!< 0x00000002 */
#define RTC_DR_DU_2 (0x4UL << RTC_DR_DU_Pos) /*!< 0x00000004 */
#define RTC_DR_DU_3 (0x8UL << RTC_DR_DU_Pos) /*!< 0x00000008 */
/******************** Bits definition for RTC_SSR register ******************/
#define RTC_SSR_SS_Pos (0U)
#define RTC_SSR_SS_Msk (0xFFFFUL << RTC_SSR_SS_Pos) /*!< 0x0000FFFF */
#define RTC_SSR_SS RTC_SSR_SS_Msk
/******************** Bits definition for RTC_ICSR register ******************/
#define RTC_ICSR_RECALPF_Pos (16U)
#define RTC_ICSR_RECALPF_Msk (0x1UL << RTC_ICSR_RECALPF_Pos) /*!< 0x00010000 */
#define RTC_ICSR_RECALPF RTC_ICSR_RECALPF_Msk
#define RTC_ICSR_INIT_Pos (7U)
#define RTC_ICSR_INIT_Msk (0x1UL << RTC_ICSR_INIT_Pos) /*!< 0x00000080 */
#define RTC_ICSR_INIT RTC_ICSR_INIT_Msk
#define RTC_ICSR_INITF_Pos (6U)
#define RTC_ICSR_INITF_Msk (0x1UL << RTC_ICSR_INITF_Pos) /*!< 0x00000040 */
#define RTC_ICSR_INITF RTC_ICSR_INITF_Msk
#define RTC_ICSR_RSF_Pos (5U)
#define RTC_ICSR_RSF_Msk (0x1UL << RTC_ICSR_RSF_Pos) /*!< 0x00000020 */
#define RTC_ICSR_RSF RTC_ICSR_RSF_Msk
#define RTC_ICSR_INITS_Pos (4U)
#define RTC_ICSR_INITS_Msk (0x1UL << RTC_ICSR_INITS_Pos) /*!< 0x00000010 */
#define RTC_ICSR_INITS RTC_ICSR_INITS_Msk
#define RTC_ICSR_SHPF_Pos (3U)
#define RTC_ICSR_SHPF_Msk (0x1UL << RTC_ICSR_SHPF_Pos) /*!< 0x00000008 */
#define RTC_ICSR_SHPF RTC_ICSR_SHPF_Msk
#define RTC_ICSR_WUTWF_Pos (2U)
#define RTC_ICSR_WUTWF_Msk (0x1UL << RTC_ICSR_WUTWF_Pos) /*!< 0x00000004 */
#define RTC_ICSR_WUTWF RTC_ICSR_WUTWF_Msk
#define RTC_ICSR_ALRBWF_Pos (1U)
#define RTC_ICSR_ALRBWF_Msk (0x1UL << RTC_ICSR_ALRBWF_Pos) /*!< 0x00000002 */
#define RTC_ICSR_ALRBWF RTC_ICSR_ALRBWF_Msk
#define RTC_ICSR_ALRAWF_Pos (0U)
#define RTC_ICSR_ALRAWF_Msk (0x1UL << RTC_ICSR_ALRAWF_Pos) /*!< 0x00000001 */
#define RTC_ICSR_ALRAWF RTC_ICSR_ALRAWF_Msk
/******************** Bits definition for RTC_PRER register *****************/
#define RTC_PRER_PREDIV_A_Pos (16U)
#define RTC_PRER_PREDIV_A_Msk (0x7FUL << RTC_PRER_PREDIV_A_Pos) /*!< 0x007F0000 */
#define RTC_PRER_PREDIV_A RTC_PRER_PREDIV_A_Msk
#define RTC_PRER_PREDIV_S_Pos (0U)
#define RTC_PRER_PREDIV_S_Msk (0x7FFFUL << RTC_PRER_PREDIV_S_Pos) /*!< 0x00007FFF */
#define RTC_PRER_PREDIV_S RTC_PRER_PREDIV_S_Msk
/******************** Bits definition for RTC_WUTR register *****************/
#define RTC_WUTR_WUT_Pos (0U)
#define RTC_WUTR_WUT_Msk (0xFFFFUL << RTC_WUTR_WUT_Pos) /*!< 0x0000FFFF */
#define RTC_WUTR_WUT RTC_WUTR_WUT_Msk
/******************** Bits definition for RTC_CR register *******************/
#define RTC_CR_OUT2EN_Pos (31U)
#define RTC_CR_OUT2EN_Msk (0x1UL << RTC_CR_OUT2EN_Pos) /*!< 0x80000000 */
#define RTC_CR_OUT2EN RTC_CR_OUT2EN_Msk /*!<RTC_OUT2 output enable */
#define RTC_CR_TAMPALRM_TYPE_Pos (30U)
#define RTC_CR_TAMPALRM_TYPE_Msk (0x1UL << RTC_CR_TAMPALRM_TYPE_Pos) /*!< 0x40000000 */
#define RTC_CR_TAMPALRM_TYPE RTC_CR_TAMPALRM_TYPE_Msk /*!<TAMPALARM output type */
#define RTC_CR_TAMPALRM_PU_Pos (29U)
#define RTC_CR_TAMPALRM_PU_Msk (0x1UL << RTC_CR_TAMPALRM_PU_Pos) /*!< 0x20000000 */
#define RTC_CR_TAMPALRM_PU RTC_CR_TAMPALRM_PU_Msk /*!<TAMPALARM output pull-up config */
#define RTC_CR_TAMPOE_Pos (26U)
#define RTC_CR_TAMPOE_Msk (0x1UL << RTC_CR_TAMPOE_Pos) /*!< 0x04000000 */
#define RTC_CR_TAMPOE RTC_CR_TAMPOE_Msk /*!<Tamper detection output enable on TAMPALARM */
#define RTC_CR_TAMPTS_Pos (25U)
#define RTC_CR_TAMPTS_Msk (0x1UL << RTC_CR_TAMPTS_Pos) /*!< 0x02000000 */
#define RTC_CR_TAMPTS RTC_CR_TAMPTS_Msk /*!<Activate timestamp on tamper detection event */
#define RTC_CR_ITSE_Pos (24U)
#define RTC_CR_ITSE_Msk (0x1UL << RTC_CR_ITSE_Pos) /*!< 0x01000000 */
#define RTC_CR_ITSE RTC_CR_ITSE_Msk /*!<Timestamp on internal event enable */
#define RTC_CR_COE_Pos (23U)
#define RTC_CR_COE_Msk (0x1UL << RTC_CR_COE_Pos) /*!< 0x00800000 */
#define RTC_CR_COE RTC_CR_COE_Msk
#define RTC_CR_OSEL_Pos (21U)
#define RTC_CR_OSEL_Msk (0x3UL << RTC_CR_OSEL_Pos) /*!< 0x00600000 */
#define RTC_CR_OSEL RTC_CR_OSEL_Msk
#define RTC_CR_OSEL_0 (0x1UL << RTC_CR_OSEL_Pos) /*!< 0x00200000 */
#define RTC_CR_OSEL_1 (0x2UL << RTC_CR_OSEL_Pos) /*!< 0x00400000 */
#define RTC_CR_POL_Pos (20U)
#define RTC_CR_POL_Msk (0x1UL << RTC_CR_POL_Pos) /*!< 0x00100000 */
#define RTC_CR_POL RTC_CR_POL_Msk
#define RTC_CR_COSEL_Pos (19U)
#define RTC_CR_COSEL_Msk (0x1UL << RTC_CR_COSEL_Pos) /*!< 0x00080000 */
#define RTC_CR_COSEL RTC_CR_COSEL_Msk
#define RTC_CR_BKP_Pos (18U)
#define RTC_CR_BKP_Msk (0x1UL << RTC_CR_BKP_Pos) /*!< 0x00040000 */
#define RTC_CR_BKP RTC_CR_BKP_Msk
#define RTC_CR_SUB1H_Pos (17U)
#define RTC_CR_SUB1H_Msk (0x1UL << RTC_CR_SUB1H_Pos) /*!< 0x00020000 */
#define RTC_CR_SUB1H RTC_CR_SUB1H_Msk
#define RTC_CR_ADD1H_Pos (16U)
#define RTC_CR_ADD1H_Msk (0x1UL << RTC_CR_ADD1H_Pos) /*!< 0x00010000 */
#define RTC_CR_ADD1H RTC_CR_ADD1H_Msk
#define RTC_CR_TSIE_Pos (15U)
#define RTC_CR_TSIE_Msk (0x1UL << RTC_CR_TSIE_Pos) /*!< 0x00008000 */
#define RTC_CR_TSIE RTC_CR_TSIE_Msk
#define RTC_CR_WUTIE_Pos (14U)
#define RTC_CR_WUTIE_Msk (0x1UL << RTC_CR_WUTIE_Pos) /*!< 0x00004000 */
#define RTC_CR_WUTIE RTC_CR_WUTIE_Msk
#define RTC_CR_ALRBIE_Pos (13U)
#define RTC_CR_ALRBIE_Msk (0x1UL << RTC_CR_ALRBIE_Pos) /*!< 0x00002000 */
#define RTC_CR_ALRBIE RTC_CR_ALRBIE_Msk
#define RTC_CR_ALRAIE_Pos (12U)
#define RTC_CR_ALRAIE_Msk (0x1UL << RTC_CR_ALRAIE_Pos) /*!< 0x00001000 */
#define RTC_CR_ALRAIE RTC_CR_ALRAIE_Msk
#define RTC_CR_TSE_Pos (11U)
#define RTC_CR_TSE_Msk (0x1UL << RTC_CR_TSE_Pos) /*!< 0x00000800 */
#define RTC_CR_TSE RTC_CR_TSE_Msk
#define RTC_CR_WUTE_Pos (10U)
#define RTC_CR_WUTE_Msk (0x1UL << RTC_CR_WUTE_Pos) /*!< 0x00000400 */
#define RTC_CR_WUTE RTC_CR_WUTE_Msk
#define RTC_CR_ALRBE_Pos (9U)
#define RTC_CR_ALRBE_Msk (0x1UL << RTC_CR_ALRBE_Pos) /*!< 0x00000200 */
#define RTC_CR_ALRBE RTC_CR_ALRBE_Msk
#define RTC_CR_ALRAE_Pos (8U)
#define RTC_CR_ALRAE_Msk (0x1UL << RTC_CR_ALRAE_Pos) /*!< 0x00000100 */
#define RTC_CR_ALRAE RTC_CR_ALRAE_Msk
#define RTC_CR_FMT_Pos (6U)
#define RTC_CR_FMT_Msk (0x1UL << RTC_CR_FMT_Pos) /*!< 0x00000040 */
#define RTC_CR_FMT RTC_CR_FMT_Msk
#define RTC_CR_BYPSHAD_Pos (5U)
#define RTC_CR_BYPSHAD_Msk (0x1UL << RTC_CR_BYPSHAD_Pos) /*!< 0x00000020 */
#define RTC_CR_BYPSHAD RTC_CR_BYPSHAD_Msk
#define RTC_CR_REFCKON_Pos (4U)
#define RTC_CR_REFCKON_Msk (0x1UL << RTC_CR_REFCKON_Pos) /*!< 0x00000010 */
#define RTC_CR_REFCKON RTC_CR_REFCKON_Msk
#define RTC_CR_TSEDGE_Pos (3U)
#define RTC_CR_TSEDGE_Msk (0x1UL << RTC_CR_TSEDGE_Pos) /*!< 0x00000008 */
#define RTC_CR_TSEDGE RTC_CR_TSEDGE_Msk
#define RTC_CR_WUCKSEL_Pos (0U)
#define RTC_CR_WUCKSEL_Msk (0x7UL << RTC_CR_WUCKSEL_Pos) /*!< 0x00000007 */
#define RTC_CR_WUCKSEL RTC_CR_WUCKSEL_Msk
#define RTC_CR_WUCKSEL_0 (0x1UL << RTC_CR_WUCKSEL_Pos) /*!< 0x00000001 */
#define RTC_CR_WUCKSEL_1 (0x2UL << RTC_CR_WUCKSEL_Pos) /*!< 0x00000002 */
#define RTC_CR_WUCKSEL_2 (0x4UL << RTC_CR_WUCKSEL_Pos) /*!< 0x00000004 */
/******************** Bits definition for RTC_WPR register ******************/
#define RTC_WPR_KEY_Pos (0U)
#define RTC_WPR_KEY_Msk (0xFFUL << RTC_WPR_KEY_Pos) /*!< 0x000000FF */
#define RTC_WPR_KEY RTC_WPR_KEY_Msk
/******************** Bits definition for RTC_CALR register *****************/
#define RTC_CALR_CALP_Pos (15U)
#define RTC_CALR_CALP_Msk (0x1UL << RTC_CALR_CALP_Pos) /*!< 0x00008000 */
#define RTC_CALR_CALP RTC_CALR_CALP_Msk
#define RTC_CALR_CALW8_Pos (14U)
#define RTC_CALR_CALW8_Msk (0x1UL << RTC_CALR_CALW8_Pos) /*!< 0x00004000 */
#define RTC_CALR_CALW8 RTC_CALR_CALW8_Msk
#define RTC_CALR_CALW16_Pos (13U)
#define RTC_CALR_CALW16_Msk (0x1UL << RTC_CALR_CALW16_Pos) /*!< 0x00002000 */
#define RTC_CALR_CALW16 RTC_CALR_CALW16_Msk
#define RTC_CALR_CALM_Pos (0U)
#define RTC_CALR_CALM_Msk (0x1FFUL << RTC_CALR_CALM_Pos) /*!< 0x000001FF */
#define RTC_CALR_CALM RTC_CALR_CALM_Msk
#define RTC_CALR_CALM_0 (0x001UL << RTC_CALR_CALM_Pos) /*!< 0x00000001 */
#define RTC_CALR_CALM_1 (0x002UL << RTC_CALR_CALM_Pos) /*!< 0x00000002 */
#define RTC_CALR_CALM_2 (0x004UL << RTC_CALR_CALM_Pos) /*!< 0x00000004 */
#define RTC_CALR_CALM_3 (0x008UL << RTC_CALR_CALM_Pos) /*!< 0x00000008 */
#define RTC_CALR_CALM_4 (0x010UL << RTC_CALR_CALM_Pos) /*!< 0x00000010 */
#define RTC_CALR_CALM_5 (0x020UL << RTC_CALR_CALM_Pos) /*!< 0x00000020 */
#define RTC_CALR_CALM_6 (0x040UL << RTC_CALR_CALM_Pos) /*!< 0x00000040 */
#define RTC_CALR_CALM_7 (0x080UL << RTC_CALR_CALM_Pos) /*!< 0x00000080 */
#define RTC_CALR_CALM_8 (0x100UL << RTC_CALR_CALM_Pos) /*!< 0x00000100 */
/******************** Bits definition for RTC_SHIFTR register ***************/
#define RTC_SHIFTR_SUBFS_Pos (0U)
#define RTC_SHIFTR_SUBFS_Msk (0x7FFFUL << RTC_SHIFTR_SUBFS_Pos) /*!< 0x00007FFF */
#define RTC_SHIFTR_SUBFS RTC_SHIFTR_SUBFS_Msk
#define RTC_SHIFTR_ADD1S_Pos (31U)
#define RTC_SHIFTR_ADD1S_Msk (0x1UL << RTC_SHIFTR_ADD1S_Pos) /*!< 0x80000000 */
#define RTC_SHIFTR_ADD1S RTC_SHIFTR_ADD1S_Msk
/******************** Bits definition for RTC_TSTR register *****************/
#define RTC_TSTR_PM_Pos (22U)
#define RTC_TSTR_PM_Msk (0x1UL << RTC_TSTR_PM_Pos) /*!< 0x00400000 */
#define RTC_TSTR_PM RTC_TSTR_PM_Msk
#define RTC_TSTR_HT_Pos (20U)
#define RTC_TSTR_HT_Msk (0x3UL << RTC_TSTR_HT_Pos) /*!< 0x00300000 */
#define RTC_TSTR_HT RTC_TSTR_HT_Msk
#define RTC_TSTR_HT_0 (0x1UL << RTC_TSTR_HT_Pos) /*!< 0x00100000 */
#define RTC_TSTR_HT_1 (0x2UL << RTC_TSTR_HT_Pos) /*!< 0x00200000 */
#define RTC_TSTR_HU_Pos (16U)
#define RTC_TSTR_HU_Msk (0xFUL << RTC_TSTR_HU_Pos) /*!< 0x000F0000 */
#define RTC_TSTR_HU RTC_TSTR_HU_Msk
#define RTC_TSTR_HU_0 (0x1UL << RTC_TSTR_HU_Pos) /*!< 0x00010000 */
#define RTC_TSTR_HU_1 (0x2UL << RTC_TSTR_HU_Pos) /*!< 0x00020000 */
#define RTC_TSTR_HU_2 (0x4UL << RTC_TSTR_HU_Pos) /*!< 0x00040000 */
#define RTC_TSTR_HU_3 (0x8UL << RTC_TSTR_HU_Pos) /*!< 0x00080000 */
#define RTC_TSTR_MNT_Pos (12U)
#define RTC_TSTR_MNT_Msk (0x7UL << RTC_TSTR_MNT_Pos) /*!< 0x00007000 */
#define RTC_TSTR_MNT RTC_TSTR_MNT_Msk
#define RTC_TSTR_MNT_0 (0x1UL << RTC_TSTR_MNT_Pos) /*!< 0x00001000 */
#define RTC_TSTR_MNT_1 (0x2UL << RTC_TSTR_MNT_Pos) /*!< 0x00002000 */
#define RTC_TSTR_MNT_2 (0x4UL << RTC_TSTR_MNT_Pos) /*!< 0x00004000 */
#define RTC_TSTR_MNU_Pos (8U)
#define RTC_TSTR_MNU_Msk (0xFUL << RTC_TSTR_MNU_Pos) /*!< 0x00000F00 */
#define RTC_TSTR_MNU RTC_TSTR_MNU_Msk
#define RTC_TSTR_MNU_0 (0x1UL << RTC_TSTR_MNU_Pos) /*!< 0x00000100 */
#define RTC_TSTR_MNU_1 (0x2UL << RTC_TSTR_MNU_Pos) /*!< 0x00000200 */
#define RTC_TSTR_MNU_2 (0x4UL << RTC_TSTR_MNU_Pos) /*!< 0x00000400 */
#define RTC_TSTR_MNU_3 (0x8UL << RTC_TSTR_MNU_Pos) /*!< 0x00000800 */
#define RTC_TSTR_ST_Pos (4U)
#define RTC_TSTR_ST_Msk (0x7UL << RTC_TSTR_ST_Pos) /*!< 0x00000070 */
#define RTC_TSTR_ST RTC_TSTR_ST_Msk
#define RTC_TSTR_ST_0 (0x1UL << RTC_TSTR_ST_Pos) /*!< 0x00000010 */
#define RTC_TSTR_ST_1 (0x2UL << RTC_TSTR_ST_Pos) /*!< 0x00000020 */
#define RTC_TSTR_ST_2 (0x4UL << RTC_TSTR_ST_Pos) /*!< 0x00000040 */
#define RTC_TSTR_SU_Pos (0U)
#define RTC_TSTR_SU_Msk (0xFUL << RTC_TSTR_SU_Pos) /*!< 0x0000000F */
#define RTC_TSTR_SU RTC_TSTR_SU_Msk
#define RTC_TSTR_SU_0 (0x1UL << RTC_TSTR_SU_Pos) /*!< 0x00000001 */
#define RTC_TSTR_SU_1 (0x2UL << RTC_TSTR_SU_Pos) /*!< 0x00000002 */
#define RTC_TSTR_SU_2 (0x4UL << RTC_TSTR_SU_Pos) /*!< 0x00000004 */
#define RTC_TSTR_SU_3 (0x8UL << RTC_TSTR_SU_Pos) /*!< 0x00000008 */
/******************** Bits definition for RTC_TSDR register *****************/
#define RTC_TSDR_WDU_Pos (13U)
#define RTC_TSDR_WDU_Msk (0x7UL << RTC_TSDR_WDU_Pos) /*!< 0x0000E000 */
#define RTC_TSDR_WDU RTC_TSDR_WDU_Msk
#define RTC_TSDR_WDU_0 (0x1UL << RTC_TSDR_WDU_Pos) /*!< 0x00002000 */
#define RTC_TSDR_WDU_1 (0x2UL << RTC_TSDR_WDU_Pos) /*!< 0x00004000 */
#define RTC_TSDR_WDU_2 (0x4UL << RTC_TSDR_WDU_Pos) /*!< 0x00008000 */
#define RTC_TSDR_MT_Pos (12U)
#define RTC_TSDR_MT_Msk (0x1UL << RTC_TSDR_MT_Pos) /*!< 0x00001000 */
#define RTC_TSDR_MT RTC_TSDR_MT_Msk
#define RTC_TSDR_MU_Pos (8U)
#define RTC_TSDR_MU_Msk (0xFUL << RTC_TSDR_MU_Pos) /*!< 0x00000F00 */
#define RTC_TSDR_MU RTC_TSDR_MU_Msk
#define RTC_TSDR_MU_0 (0x1UL << RTC_TSDR_MU_Pos) /*!< 0x00000100 */
#define RTC_TSDR_MU_1 (0x2UL << RTC_TSDR_MU_Pos) /*!< 0x00000200 */
#define RTC_TSDR_MU_2 (0x4UL << RTC_TSDR_MU_Pos) /*!< 0x00000400 */
#define RTC_TSDR_MU_3 (0x8UL << RTC_TSDR_MU_Pos) /*!< 0x00000800 */
#define RTC_TSDR_DT_Pos (4U)
#define RTC_TSDR_DT_Msk (0x3UL << RTC_TSDR_DT_Pos) /*!< 0x00000030 */
#define RTC_TSDR_DT RTC_TSDR_DT_Msk
#define RTC_TSDR_DT_0 (0x1UL << RTC_TSDR_DT_Pos) /*!< 0x00000010 */
#define RTC_TSDR_DT_1 (0x2UL << RTC_TSDR_DT_Pos) /*!< 0x00000020 */
#define RTC_TSDR_DU_Pos (0U)
#define RTC_TSDR_DU_Msk (0xFUL << RTC_TSDR_DU_Pos) /*!< 0x0000000F */
#define RTC_TSDR_DU RTC_TSDR_DU_Msk
#define RTC_TSDR_DU_0 (0x1UL << RTC_TSDR_DU_Pos) /*!< 0x00000001 */
#define RTC_TSDR_DU_1 (0x2UL << RTC_TSDR_DU_Pos) /*!< 0x00000002 */
#define RTC_TSDR_DU_2 (0x4UL << RTC_TSDR_DU_Pos) /*!< 0x00000004 */
#define RTC_TSDR_DU_3 (0x8UL << RTC_TSDR_DU_Pos) /*!< 0x00000008 */
/******************** Bits definition for RTC_TSSSR register ****************/
#define RTC_TSSSR_SS_Pos (0U)
#define RTC_TSSSR_SS_Msk (0xFFFFUL << RTC_TSSSR_SS_Pos) /*!< 0x0000FFFF */
#define RTC_TSSSR_SS RTC_TSSSR_SS_Msk
/******************** Bits definition for RTC_ALRMAR register ***************/
#define RTC_ALRMAR_MSK4_Pos (31U)
#define RTC_ALRMAR_MSK4_Msk (0x1UL << RTC_ALRMAR_MSK4_Pos) /*!< 0x80000000 */
#define RTC_ALRMAR_MSK4 RTC_ALRMAR_MSK4_Msk
#define RTC_ALRMAR_WDSEL_Pos (30U)
#define RTC_ALRMAR_WDSEL_Msk (0x1UL << RTC_ALRMAR_WDSEL_Pos) /*!< 0x40000000 */
#define RTC_ALRMAR_WDSEL RTC_ALRMAR_WDSEL_Msk
#define RTC_ALRMAR_DT_Pos (28U)
#define RTC_ALRMAR_DT_Msk (0x3UL << RTC_ALRMAR_DT_Pos) /*!< 0x30000000 */
#define RTC_ALRMAR_DT RTC_ALRMAR_DT_Msk
#define RTC_ALRMAR_DT_0 (0x1UL << RTC_ALRMAR_DT_Pos) /*!< 0x10000000 */
#define RTC_ALRMAR_DT_1 (0x2UL << RTC_ALRMAR_DT_Pos) /*!< 0x20000000 */
#define RTC_ALRMAR_DU_Pos (24U)
#define RTC_ALRMAR_DU_Msk (0xFUL << RTC_ALRMAR_DU_Pos) /*!< 0x0F000000 */
#define RTC_ALRMAR_DU RTC_ALRMAR_DU_Msk
#define RTC_ALRMAR_DU_0 (0x1UL << RTC_ALRMAR_DU_Pos) /*!< 0x01000000 */
#define RTC_ALRMAR_DU_1 (0x2UL << RTC_ALRMAR_DU_Pos) /*!< 0x02000000 */
#define RTC_ALRMAR_DU_2 (0x4UL << RTC_ALRMAR_DU_Pos) /*!< 0x04000000 */
#define RTC_ALRMAR_DU_3 (0x8UL << RTC_ALRMAR_DU_Pos) /*!< 0x08000000 */
#define RTC_ALRMAR_MSK3_Pos (23U)
#define RTC_ALRMAR_MSK3_Msk (0x1UL << RTC_ALRMAR_MSK3_Pos) /*!< 0x00800000 */
#define RTC_ALRMAR_MSK3 RTC_ALRMAR_MSK3_Msk
#define RTC_ALRMAR_PM_Pos (22U)
#define RTC_ALRMAR_PM_Msk (0x1UL << RTC_ALRMAR_PM_Pos) /*!< 0x00400000 */
#define RTC_ALRMAR_PM RTC_ALRMAR_PM_Msk
#define RTC_ALRMAR_HT_Pos (20U)
#define RTC_ALRMAR_HT_Msk (0x3UL << RTC_ALRMAR_HT_Pos) /*!< 0x00300000 */
#define RTC_ALRMAR_HT RTC_ALRMAR_HT_Msk
#define RTC_ALRMAR_HT_0 (0x1UL << RTC_ALRMAR_HT_Pos) /*!< 0x00100000 */
#define RTC_ALRMAR_HT_1 (0x2UL << RTC_ALRMAR_HT_Pos) /*!< 0x00200000 */
#define RTC_ALRMAR_HU_Pos (16U)
#define RTC_ALRMAR_HU_Msk (0xFUL << RTC_ALRMAR_HU_Pos) /*!< 0x000F0000 */
#define RTC_ALRMAR_HU RTC_ALRMAR_HU_Msk
#define RTC_ALRMAR_HU_0 (0x1UL << RTC_ALRMAR_HU_Pos) /*!< 0x00010000 */
#define RTC_ALRMAR_HU_1 (0x2UL << RTC_ALRMAR_HU_Pos) /*!< 0x00020000 */
#define RTC_ALRMAR_HU_2 (0x4UL << RTC_ALRMAR_HU_Pos) /*!< 0x00040000 */
#define RTC_ALRMAR_HU_3 (0x8UL << RTC_ALRMAR_HU_Pos) /*!< 0x00080000 */
#define RTC_ALRMAR_MSK2_Pos (15U)
#define RTC_ALRMAR_MSK2_Msk (0x1UL << RTC_ALRMAR_MSK2_Pos) /*!< 0x00008000 */
#define RTC_ALRMAR_MSK2 RTC_ALRMAR_MSK2_Msk
#define RTC_ALRMAR_MNT_Pos (12U)
#define RTC_ALRMAR_MNT_Msk (0x7UL << RTC_ALRMAR_MNT_Pos) /*!< 0x00007000 */
#define RTC_ALRMAR_MNT RTC_ALRMAR_MNT_Msk
#define RTC_ALRMAR_MNT_0 (0x1UL << RTC_ALRMAR_MNT_Pos) /*!< 0x00001000 */
#define RTC_ALRMAR_MNT_1 (0x2UL << RTC_ALRMAR_MNT_Pos) /*!< 0x00002000 */
#define RTC_ALRMAR_MNT_2 (0x4UL << RTC_ALRMAR_MNT_Pos) /*!< 0x00004000 */
#define RTC_ALRMAR_MNU_Pos (8U)
#define RTC_ALRMAR_MNU_Msk (0xFUL << RTC_ALRMAR_MNU_Pos) /*!< 0x00000F00 */
#define RTC_ALRMAR_MNU RTC_ALRMAR_MNU_Msk
#define RTC_ALRMAR_MNU_0 (0x1UL << RTC_ALRMAR_MNU_Pos) /*!< 0x00000100 */
#define RTC_ALRMAR_MNU_1 (0x2UL << RTC_ALRMAR_MNU_Pos) /*!< 0x00000200 */
#define RTC_ALRMAR_MNU_2 (0x4UL << RTC_ALRMAR_MNU_Pos) /*!< 0x00000400 */
#define RTC_ALRMAR_MNU_3 (0x8UL << RTC_ALRMAR_MNU_Pos) /*!< 0x00000800 */
#define RTC_ALRMAR_MSK1_Pos (7U)
#define RTC_ALRMAR_MSK1_Msk (0x1UL << RTC_ALRMAR_MSK1_Pos) /*!< 0x00000080 */
#define RTC_ALRMAR_MSK1 RTC_ALRMAR_MSK1_Msk
#define RTC_ALRMAR_ST_Pos (4U)
#define RTC_ALRMAR_ST_Msk (0x7UL << RTC_ALRMAR_ST_Pos) /*!< 0x00000070 */
#define RTC_ALRMAR_ST RTC_ALRMAR_ST_Msk
#define RTC_ALRMAR_ST_0 (0x1UL << RTC_ALRMAR_ST_Pos) /*!< 0x00000010 */
#define RTC_ALRMAR_ST_1 (0x2UL << RTC_ALRMAR_ST_Pos) /*!< 0x00000020 */
#define RTC_ALRMAR_ST_2 (0x4UL << RTC_ALRMAR_ST_Pos) /*!< 0x00000040 */
#define RTC_ALRMAR_SU_Pos (0U)
#define RTC_ALRMAR_SU_Msk (0xFUL << RTC_ALRMAR_SU_Pos) /*!< 0x0000000F */
#define RTC_ALRMAR_SU RTC_ALRMAR_SU_Msk
#define RTC_ALRMAR_SU_0 (0x1UL << RTC_ALRMAR_SU_Pos) /*!< 0x00000001 */
#define RTC_ALRMAR_SU_1 (0x2UL << RTC_ALRMAR_SU_Pos) /*!< 0x00000002 */
#define RTC_ALRMAR_SU_2 (0x4UL << RTC_ALRMAR_SU_Pos) /*!< 0x00000004 */
#define RTC_ALRMAR_SU_3 (0x8UL << RTC_ALRMAR_SU_Pos) /*!< 0x00000008 */
/******************** Bits definition for RTC_ALRMASSR register *************/
#define RTC_ALRMASSR_MASKSS_Pos (24U)
#define RTC_ALRMASSR_MASKSS_Msk (0xFUL << RTC_ALRMASSR_MASKSS_Pos) /*!< 0x0F000000 */
#define RTC_ALRMASSR_MASKSS RTC_ALRMASSR_MASKSS_Msk
#define RTC_ALRMASSR_MASKSS_0 (0x1UL << RTC_ALRMASSR_MASKSS_Pos) /*!< 0x01000000 */
#define RTC_ALRMASSR_MASKSS_1 (0x2UL << RTC_ALRMASSR_MASKSS_Pos) /*!< 0x02000000 */
#define RTC_ALRMASSR_MASKSS_2 (0x4UL << RTC_ALRMASSR_MASKSS_Pos) /*!< 0x04000000 */
#define RTC_ALRMASSR_MASKSS_3 (0x8UL << RTC_ALRMASSR_MASKSS_Pos) /*!< 0x08000000 */
#define RTC_ALRMASSR_SS_Pos (0U)
#define RTC_ALRMASSR_SS_Msk (0x7FFFUL << RTC_ALRMASSR_SS_Pos) /*!< 0x00007FFF */
#define RTC_ALRMASSR_SS RTC_ALRMASSR_SS_Msk
/******************** Bits definition for RTC_ALRMBR register ***************/
#define RTC_ALRMBR_MSK4_Pos (31U)
#define RTC_ALRMBR_MSK4_Msk (0x1UL << RTC_ALRMBR_MSK4_Pos) /*!< 0x80000000 */
#define RTC_ALRMBR_MSK4 RTC_ALRMBR_MSK4_Msk
#define RTC_ALRMBR_WDSEL_Pos (30U)
#define RTC_ALRMBR_WDSEL_Msk (0x1UL << RTC_ALRMBR_WDSEL_Pos) /*!< 0x40000000 */
#define RTC_ALRMBR_WDSEL RTC_ALRMBR_WDSEL_Msk
#define RTC_ALRMBR_DT_Pos (28U)
#define RTC_ALRMBR_DT_Msk (0x3UL << RTC_ALRMBR_DT_Pos) /*!< 0x30000000 */
#define RTC_ALRMBR_DT RTC_ALRMBR_DT_Msk
#define RTC_ALRMBR_DT_0 (0x1UL << RTC_ALRMBR_DT_Pos) /*!< 0x10000000 */
#define RTC_ALRMBR_DT_1 (0x2UL << RTC_ALRMBR_DT_Pos) /*!< 0x20000000 */
#define RTC_ALRMBR_DU_Pos (24U)
#define RTC_ALRMBR_DU_Msk (0xFUL << RTC_ALRMBR_DU_Pos) /*!< 0x0F000000 */
#define RTC_ALRMBR_DU RTC_ALRMBR_DU_Msk
#define RTC_ALRMBR_DU_0 (0x1UL << RTC_ALRMBR_DU_Pos) /*!< 0x01000000 */
#define RTC_ALRMBR_DU_1 (0x2UL << RTC_ALRMBR_DU_Pos) /*!< 0x02000000 */
#define RTC_ALRMBR_DU_2 (0x4UL << RTC_ALRMBR_DU_Pos) /*!< 0x04000000 */
#define RTC_ALRMBR_DU_3 (0x8UL << RTC_ALRMBR_DU_Pos) /*!< 0x08000000 */
#define RTC_ALRMBR_MSK3_Pos (23U)
#define RTC_ALRMBR_MSK3_Msk (0x1UL << RTC_ALRMBR_MSK3_Pos) /*!< 0x00800000 */
#define RTC_ALRMBR_MSK3 RTC_ALRMBR_MSK3_Msk
#define RTC_ALRMBR_PM_Pos (22U)
#define RTC_ALRMBR_PM_Msk (0x1UL << RTC_ALRMBR_PM_Pos) /*!< 0x00400000 */
#define RTC_ALRMBR_PM RTC_ALRMBR_PM_Msk
#define RTC_ALRMBR_HT_Pos (20U)
#define RTC_ALRMBR_HT_Msk (0x3UL << RTC_ALRMBR_HT_Pos) /*!< 0x00300000 */
#define RTC_ALRMBR_HT RTC_ALRMBR_HT_Msk
#define RTC_ALRMBR_HT_0 (0x1UL << RTC_ALRMBR_HT_Pos) /*!< 0x00100000 */
#define RTC_ALRMBR_HT_1 (0x2UL << RTC_ALRMBR_HT_Pos) /*!< 0x00200000 */
#define RTC_ALRMBR_HU_Pos (16U)
#define RTC_ALRMBR_HU_Msk (0xFUL << RTC_ALRMBR_HU_Pos) /*!< 0x000F0000 */
#define RTC_ALRMBR_HU RTC_ALRMBR_HU_Msk
#define RTC_ALRMBR_HU_0 (0x1UL << RTC_ALRMBR_HU_Pos) /*!< 0x00010000 */
#define RTC_ALRMBR_HU_1 (0x2UL << RTC_ALRMBR_HU_Pos) /*!< 0x00020000 */
#define RTC_ALRMBR_HU_2 (0x4UL << RTC_ALRMBR_HU_Pos) /*!< 0x00040000 */
#define RTC_ALRMBR_HU_3 (0x8UL << RTC_ALRMBR_HU_Pos) /*!< 0x00080000 */
#define RTC_ALRMBR_MSK2_Pos (15U)
#define RTC_ALRMBR_MSK2_Msk (0x1UL << RTC_ALRMBR_MSK2_Pos) /*!< 0x00008000 */
#define RTC_ALRMBR_MSK2 RTC_ALRMBR_MSK2_Msk
#define RTC_ALRMBR_MNT_Pos (12U)
#define RTC_ALRMBR_MNT_Msk (0x7UL << RTC_ALRMBR_MNT_Pos) /*!< 0x00007000 */
#define RTC_ALRMBR_MNT RTC_ALRMBR_MNT_Msk
#define RTC_ALRMBR_MNT_0 (0x1UL << RTC_ALRMBR_MNT_Pos) /*!< 0x00001000 */
#define RTC_ALRMBR_MNT_1 (0x2UL << RTC_ALRMBR_MNT_Pos) /*!< 0x00002000 */
#define RTC_ALRMBR_MNT_2 (0x4UL << RTC_ALRMBR_MNT_Pos) /*!< 0x00004000 */
#define RTC_ALRMBR_MNU_Pos (8U)
#define RTC_ALRMBR_MNU_Msk (0xFUL << RTC_ALRMBR_MNU_Pos) /*!< 0x00000F00 */
#define RTC_ALRMBR_MNU RTC_ALRMBR_MNU_Msk
#define RTC_ALRMBR_MNU_0 (0x1UL << RTC_ALRMBR_MNU_Pos) /*!< 0x00000100 */
#define RTC_ALRMBR_MNU_1 (0x2UL << RTC_ALRMBR_MNU_Pos) /*!< 0x00000200 */
#define RTC_ALRMBR_MNU_2 (0x4UL << RTC_ALRMBR_MNU_Pos) /*!< 0x00000400 */
#define RTC_ALRMBR_MNU_3 (0x8UL << RTC_ALRMBR_MNU_Pos) /*!< 0x00000800 */
#define RTC_ALRMBR_MSK1_Pos (7U)
#define RTC_ALRMBR_MSK1_Msk (0x1UL << RTC_ALRMBR_MSK1_Pos) /*!< 0x00000080 */
#define RTC_ALRMBR_MSK1 RTC_ALRMBR_MSK1_Msk
#define RTC_ALRMBR_ST_Pos (4U)
#define RTC_ALRMBR_ST_Msk (0x7UL << RTC_ALRMBR_ST_Pos) /*!< 0x00000070 */
#define RTC_ALRMBR_ST RTC_ALRMBR_ST_Msk
#define RTC_ALRMBR_ST_0 (0x1UL << RTC_ALRMBR_ST_Pos) /*!< 0x00000010 */
#define RTC_ALRMBR_ST_1 (0x2UL << RTC_ALRMBR_ST_Pos) /*!< 0x00000020 */
#define RTC_ALRMBR_ST_2 (0x4UL << RTC_ALRMBR_ST_Pos) /*!< 0x00000040 */
#define RTC_ALRMBR_SU_Pos (0U)
#define RTC_ALRMBR_SU_Msk (0xFUL << RTC_ALRMBR_SU_Pos) /*!< 0x0000000F */
#define RTC_ALRMBR_SU RTC_ALRMBR_SU_Msk
#define RTC_ALRMBR_SU_0 (0x1UL << RTC_ALRMBR_SU_Pos) /*!< 0x00000001 */
#define RTC_ALRMBR_SU_1 (0x2UL << RTC_ALRMBR_SU_Pos) /*!< 0x00000002 */
#define RTC_ALRMBR_SU_2 (0x4UL << RTC_ALRMBR_SU_Pos) /*!< 0x00000004 */
#define RTC_ALRMBR_SU_3 (0x8UL << RTC_ALRMBR_SU_Pos) /*!< 0x00000008 */
/******************** Bits definition for RTC_ALRMASSR register *************/
#define RTC_ALRMBSSR_MASKSS_Pos (24U)
#define RTC_ALRMBSSR_MASKSS_Msk (0xFUL << RTC_ALRMBSSR_MASKSS_Pos) /*!< 0x0F000000 */
#define RTC_ALRMBSSR_MASKSS RTC_ALRMBSSR_MASKSS_Msk
#define RTC_ALRMBSSR_MASKSS_0 (0x1UL << RTC_ALRMBSSR_MASKSS_Pos) /*!< 0x01000000 */
#define RTC_ALRMBSSR_MASKSS_1 (0x2UL << RTC_ALRMBSSR_MASKSS_Pos) /*!< 0x02000000 */
#define RTC_ALRMBSSR_MASKSS_2 (0x4UL << RTC_ALRMBSSR_MASKSS_Pos) /*!< 0x04000000 */
#define RTC_ALRMBSSR_MASKSS_3 (0x8UL << RTC_ALRMBSSR_MASKSS_Pos) /*!< 0x08000000 */
#define RTC_ALRMBSSR_SS_Pos (0U)
#define RTC_ALRMBSSR_SS_Msk (0x7FFFUL << RTC_ALRMBSSR_SS_Pos) /*!< 0x00007FFF */
#define RTC_ALRMBSSR_SS RTC_ALRMBSSR_SS_Msk
/******************** Bits definition for RTC_SR register *******************/
#define RTC_SR_ITSF_Pos (5U)
#define RTC_SR_ITSF_Msk (0x1UL << RTC_SR_ITSF_Pos) /*!< 0x00000020 */
#define RTC_SR_ITSF RTC_SR_ITSF_Msk
#define RTC_SR_TSOVF_Pos (4U)
#define RTC_SR_TSOVF_Msk (0x1UL << RTC_SR_TSOVF_Pos) /*!< 0x00000010 */
#define RTC_SR_TSOVF RTC_SR_TSOVF_Msk
#define RTC_SR_TSF_Pos (3U)
#define RTC_SR_TSF_Msk (0x1UL << RTC_SR_TSF_Pos) /*!< 0x00000008 */
#define RTC_SR_TSF RTC_SR_TSF_Msk
#define RTC_SR_WUTF_Pos (2U)
#define RTC_SR_WUTF_Msk (0x1UL << RTC_SR_WUTF_Pos) /*!< 0x00000004 */
#define RTC_SR_WUTF RTC_SR_WUTF_Msk
#define RTC_SR_ALRBF_Pos (1U)
#define RTC_SR_ALRBF_Msk (0x1UL << RTC_SR_ALRBF_Pos) /*!< 0x00000002 */
#define RTC_SR_ALRBF RTC_SR_ALRBF_Msk
#define RTC_SR_ALRAF_Pos (0U)
#define RTC_SR_ALRAF_Msk (0x1UL << RTC_SR_ALRAF_Pos) /*!< 0x00000001 */
#define RTC_SR_ALRAF RTC_SR_ALRAF_Msk
/******************** Bits definition for RTC_MISR register *****************/
#define RTC_MISR_ITSMF_Pos (5U)
#define RTC_MISR_ITSMF_Msk (0x1UL << RTC_MISR_ITSMF_Pos) /*!< 0x00000020 */
#define RTC_MISR_ITSMF RTC_MISR_ITSMF_Msk
#define RTC_MISR_TSOVMF_Pos (4U)
#define RTC_MISR_TSOVMF_Msk (0x1UL << RTC_MISR_TSOVMF_Pos) /*!< 0x00000010 */
#define RTC_MISR_TSOVMF RTC_MISR_TSOVMF_Msk
#define RTC_MISR_TSMF_Pos (3U)
#define RTC_MISR_TSMF_Msk (0x1UL << RTC_MISR_TSMF_Pos) /*!< 0x00000008 */
#define RTC_MISR_TSMF RTC_MISR_TSMF_Msk
#define RTC_MISR_WUTMF_Pos (2U)
#define RTC_MISR_WUTMF_Msk (0x1UL << RTC_MISR_WUTMF_Pos) /*!< 0x00000004 */
#define RTC_MISR_WUTMF RTC_MISR_WUTMF_Msk
#define RTC_MISR_ALRBMF_Pos (1U)
#define RTC_MISR_ALRBMF_Msk (0x1UL << RTC_MISR_ALRBMF_Pos) /*!< 0x00000002 */
#define RTC_MISR_ALRBMF RTC_MISR_ALRBMF_Msk
#define RTC_MISR_ALRAMF_Pos (0U)
#define RTC_MISR_ALRAMF_Msk (0x1UL << RTC_MISR_ALRAMF_Pos) /*!< 0x00000001 */
#define RTC_MISR_ALRAMF RTC_MISR_ALRAMF_Msk
/******************** Bits definition for RTC_SCR register ******************/
#define RTC_SCR_CITSF_Pos (5U)
#define RTC_SCR_CITSF_Msk (0x1UL << RTC_SCR_CITSF_Pos) /*!< 0x00000020 */
#define RTC_SCR_CITSF RTC_SCR_CITSF_Msk
#define RTC_SCR_CTSOVF_Pos (4U)
#define RTC_SCR_CTSOVF_Msk (0x1UL << RTC_SCR_CTSOVF_Pos) /*!< 0x00000010 */
#define RTC_SCR_CTSOVF RTC_SCR_CTSOVF_Msk
#define RTC_SCR_CTSF_Pos (3U)
#define RTC_SCR_CTSF_Msk (0x1UL << RTC_SCR_CTSF_Pos) /*!< 0x00000008 */
#define RTC_SCR_CTSF RTC_SCR_CTSF_Msk
#define RTC_SCR_CWUTF_Pos (2U)
#define RTC_SCR_CWUTF_Msk (0x1UL << RTC_SCR_CWUTF_Pos) /*!< 0x00000004 */
#define RTC_SCR_CWUTF RTC_SCR_CWUTF_Msk
#define RTC_SCR_CALRBF_Pos (1U)
#define RTC_SCR_CALRBF_Msk (0x1UL << RTC_SCR_CALRBF_Pos) /*!< 0x00000002 */
#define RTC_SCR_CALRBF RTC_SCR_CALRBF_Msk
#define RTC_SCR_CALRAF_Pos (0U)
#define RTC_SCR_CALRAF_Msk (0x1UL << RTC_SCR_CALRAF_Pos) /*!< 0x00000001 */
#define RTC_SCR_CALRAF RTC_SCR_CALRAF_Msk
/******************************************************************************/
/* */
/* Tamper and backup register (TAMP) */
/* */
/******************************************************************************/
/******************** Bits definition for TAMP_CR1 register *****************/
#define TAMP_CR1_TAMP1E_Pos (0U)
#define TAMP_CR1_TAMP1E_Msk (0x1UL << TAMP_CR1_TAMP1E_Pos) /*!< 0x00000001 */
#define TAMP_CR1_TAMP1E TAMP_CR1_TAMP1E_Msk
#define TAMP_CR1_TAMP2E_Pos (1U)
#define TAMP_CR1_TAMP2E_Msk (0x1UL << TAMP_CR1_TAMP2E_Pos) /*!< 0x00000002 */
#define TAMP_CR1_TAMP2E TAMP_CR1_TAMP2E_Msk
#define TAMP_CR1_TAMP3E_Pos (2U)
#define TAMP_CR1_TAMP3E_Msk (0x1UL << TAMP_CR1_TAMP3E_Pos) /*!< 0x00000004 */
#define TAMP_CR1_TAMP3E TAMP_CR1_TAMP3E_Msk
#define TAMP_CR1_ITAMP3E_Pos (18U)
#define TAMP_CR1_ITAMP3E_Msk (0x1UL << TAMP_CR1_ITAMP3E_Pos) /*!< 0x00040000 */
#define TAMP_CR1_ITAMP3E TAMP_CR1_ITAMP3E_Msk
#define TAMP_CR1_ITAMP4E_Pos (19U)
#define TAMP_CR1_ITAMP4E_Msk (0x1UL << TAMP_CR1_ITAMP4E_Pos) /*!< 0x00080000 */
#define TAMP_CR1_ITAMP4E TAMP_CR1_ITAMP4E_Msk
#define TAMP_CR1_ITAMP5E_Pos (20U)
#define TAMP_CR1_ITAMP5E_Msk (0x1UL << TAMP_CR1_ITAMP5E_Pos) /*!< 0x00100000 */
#define TAMP_CR1_ITAMP5E TAMP_CR1_ITAMP5E_Msk
#define TAMP_CR1_ITAMP6E_Pos (21U)
#define TAMP_CR1_ITAMP6E_Msk (0x1UL << TAMP_CR1_ITAMP6E_Pos) /*!< 0x00200000 */
#define TAMP_CR1_ITAMP6E TAMP_CR1_ITAMP6E_Msk
/******************** Bits definition for TAMP_CR2 register *****************/
#define TAMP_CR2_TAMP1NOERASE_Pos (0U)
#define TAMP_CR2_TAMP1NOERASE_Msk (0x1UL << TAMP_CR2_TAMP1NOERASE_Pos) /*!< 0x00000001 */
#define TAMP_CR2_TAMP1NOERASE TAMP_CR2_TAMP1NOERASE_Msk
#define TAMP_CR2_TAMP2NOERASE_Pos (1U)
#define TAMP_CR2_TAMP2NOERASE_Msk (0x1UL << TAMP_CR2_TAMP2NOERASE_Pos) /*!< 0x00000002 */
#define TAMP_CR2_TAMP2NOERASE TAMP_CR2_TAMP2NOERASE_Msk
#define TAMP_CR2_TAMP3NOERASE_Pos (2U)
#define TAMP_CR2_TAMP3NOERASE_Msk (0x1UL << TAMP_CR2_TAMP3NOERASE_Pos) /*!< 0x00000004 */
#define TAMP_CR2_TAMP3NOERASE TAMP_CR2_TAMP3NOERASE_Msk
#define TAMP_CR2_TAMP1MF_Pos (16U)
#define TAMP_CR2_TAMP1MF_Msk (0x1UL << TAMP_CR2_TAMP1MF_Pos) /*!< 0x00010000 */
#define TAMP_CR2_TAMP1MF TAMP_CR2_TAMP1MF_Msk
#define TAMP_CR2_TAMP2MF_Pos (17U)
#define TAMP_CR2_TAMP2MF_Msk (0x1UL << TAMP_CR2_TAMP2MF_Pos) /*!< 0x00020000 */
#define TAMP_CR2_TAMP2MF TAMP_CR2_TAMP2MF_Msk
#define TAMP_CR2_TAMP3MF_Pos (18U)
#define TAMP_CR2_TAMP3MF_Msk (0x1UL << TAMP_CR2_TAMP3MF_Pos) /*!< 0x00040000 */
#define TAMP_CR2_TAMP3MF TAMP_CR2_TAMP3MF_Msk
#define TAMP_CR2_TAMP1TRG_Pos (24U)
#define TAMP_CR2_TAMP1TRG_Msk (0x1UL << TAMP_CR2_TAMP1TRG_Pos) /*!< 0x01000000 */
#define TAMP_CR2_TAMP1TRG TAMP_CR2_TAMP1TRG_Msk
#define TAMP_CR2_TAMP2TRG_Pos (25U)
#define TAMP_CR2_TAMP2TRG_Msk (0x1UL << TAMP_CR2_TAMP2TRG_Pos) /*!< 0x02000000 */
#define TAMP_CR2_TAMP2TRG TAMP_CR2_TAMP2TRG_Msk
#define TAMP_CR2_TAMP3TRG_Pos (26U)
#define TAMP_CR2_TAMP3TRG_Msk (0x1UL << TAMP_CR2_TAMP3TRG_Pos) /*!< 0x04000000 */
#define TAMP_CR2_TAMP3TRG TAMP_CR2_TAMP3TRG_Msk
/******************** Bits definition for TAMP_FLTCR register ***************/
#define TAMP_FLTCR_TAMPFREQ_0 (0x00000001UL)
#define TAMP_FLTCR_TAMPFREQ_1 (0x00000002UL)
#define TAMP_FLTCR_TAMPFREQ_2 (0x00000004UL)
#define TAMP_FLTCR_TAMPFREQ_Pos (0U)
#define TAMP_FLTCR_TAMPFREQ_Msk (0x7UL << TAMP_FLTCR_TAMPFREQ_Pos) /*!< 0x00000007 */
#define TAMP_FLTCR_TAMPFREQ TAMP_FLTCR_TAMPFREQ_Msk
#define TAMP_FLTCR_TAMPFLT_0 (0x00000008UL)
#define TAMP_FLTCR_TAMPFLT_1 (0x00000010UL)
#define TAMP_FLTCR_TAMPFLT_Pos (3U)
#define TAMP_FLTCR_TAMPFLT_Msk (0x3UL << TAMP_FLTCR_TAMPFLT_Pos) /*!< 0x00000018 */
#define TAMP_FLTCR_TAMPFLT TAMP_FLTCR_TAMPFLT_Msk
#define TAMP_FLTCR_TAMPPRCH_0 (0x00000020UL)
#define TAMP_FLTCR_TAMPPRCH_1 (0x00000040UL)
#define TAMP_FLTCR_TAMPPRCH_Pos (5U)
#define TAMP_FLTCR_TAMPPRCH_Msk (0x3UL << TAMP_FLTCR_TAMPPRCH_Pos) /*!< 0x00000060 */
#define TAMP_FLTCR_TAMPPRCH TAMP_FLTCR_TAMPPRCH_Msk
#define TAMP_FLTCR_TAMPPUDIS_Pos (7U)
#define TAMP_FLTCR_TAMPPUDIS_Msk (0x1UL << TAMP_FLTCR_TAMPPUDIS_Pos) /*!< 0x00000080 */
#define TAMP_FLTCR_TAMPPUDIS TAMP_FLTCR_TAMPPUDIS_Msk
/******************** Bits definition for TAMP_IER register *****************/
#define TAMP_IER_TAMP1IE_Pos (0U)
#define TAMP_IER_TAMP1IE_Msk (0x1UL << TAMP_IER_TAMP1IE_Pos) /*!< 0x00000001 */
#define TAMP_IER_TAMP1IE TAMP_IER_TAMP1IE_Msk
#define TAMP_IER_TAMP2IE_Pos (1U)
#define TAMP_IER_TAMP2IE_Msk (0x1UL << TAMP_IER_TAMP2IE_Pos) /*!< 0x00000002 */
#define TAMP_IER_TAMP2IE TAMP_IER_TAMP2IE_Msk
#define TAMP_IER_TAMP3IE_Pos (2U)
#define TAMP_IER_TAMP3IE_Msk (0x1UL << TAMP_IER_TAMP3IE_Pos) /*!< 0x00000004 */
#define TAMP_IER_TAMP3IE TAMP_IER_TAMP3IE_Msk
#define TAMP_IER_ITAMP3IE_Pos (18U)
#define TAMP_IER_ITAMP3IE_Msk (0x1UL << TAMP_IER_ITAMP3IE_Pos) /*!< 0x00040000 */
#define TAMP_IER_ITAMP3IE TAMP_IER_ITAMP3IE_Msk
#define TAMP_IER_ITAMP4IE_Pos (19U)
#define TAMP_IER_ITAMP4IE_Msk (0x1UL << TAMP_IER_ITAMP4IE_Pos) /*!< 0x00080000 */
#define TAMP_IER_ITAMP4IE TAMP_IER_ITAMP4IE_Msk
#define TAMP_IER_ITAMP5IE_Pos (20U)
#define TAMP_IER_ITAMP5IE_Msk (0x1UL << TAMP_IER_ITAMP5IE_Pos) /*!< 0x00100000 */
#define TAMP_IER_ITAMP5IE TAMP_IER_ITAMP5IE_Msk
#define TAMP_IER_ITAMP6IE_Pos (21U)
#define TAMP_IER_ITAMP6IE_Msk (0x1UL << TAMP_IER_ITAMP6IE_Pos) /*!< 0x00200000 */
#define TAMP_IER_ITAMP6IE TAMP_IER_ITAMP6IE_Msk
/******************** Bits definition for TAMP_SR register ******************/
#define TAMP_SR_TAMP1F_Pos (0U)
#define TAMP_SR_TAMP1F_Msk (0x1UL << TAMP_SR_TAMP1F_Pos) /*!< 0x00000001 */
#define TAMP_SR_TAMP1F TAMP_SR_TAMP1F_Msk
#define TAMP_SR_TAMP2F_Pos (1U)
#define TAMP_SR_TAMP2F_Msk (0x1UL << TAMP_SR_TAMP2F_Pos) /*!< 0x00000002 */
#define TAMP_SR_TAMP2F TAMP_SR_TAMP2F_Msk
#define TAMP_SR_TAMP3F_Pos (2U)
#define TAMP_SR_TAMP3F_Msk (0x1UL << TAMP_SR_TAMP3F_Pos) /*!< 0x00000004 */
#define TAMP_SR_TAMP3F TAMP_SR_TAMP3F_Msk
#define TAMP_SR_ITAMP3F_Pos (18U)
#define TAMP_SR_ITAMP3F_Msk (0x1UL << TAMP_SR_ITAMP3F_Pos) /*!< 0x00040000 */
#define TAMP_SR_ITAMP3F TAMP_SR_ITAMP3F_Msk
#define TAMP_SR_ITAMP4F_Pos (19U)
#define TAMP_SR_ITAMP4F_Msk (0x1UL << TAMP_SR_ITAMP4F_Pos) /*!< 0x00080000 */
#define TAMP_SR_ITAMP4F TAMP_SR_ITAMP4F_Msk
#define TAMP_SR_ITAMP5F_Pos (20U)
#define TAMP_SR_ITAMP5F_Msk (0x1UL << TAMP_SR_ITAMP5F_Pos) /*!< 0x00100000 */
#define TAMP_SR_ITAMP5F TAMP_SR_ITAMP5F_Msk
#define TAMP_SR_ITAMP6F_Pos (21U)
#define TAMP_SR_ITAMP6F_Msk (0x1UL << TAMP_SR_ITAMP6F_Pos) /*!< 0x00200000 */
#define TAMP_SR_ITAMP6F TAMP_SR_ITAMP6F_Msk
/******************** Bits definition for TAMP_MISR register ****************/
#define TAMP_MISR_TAMP1MF_Pos (0U)
#define TAMP_MISR_TAMP1MF_Msk (0x1UL << TAMP_MISR_TAMP1MF_Pos) /*!< 0x00000001 */
#define TAMP_MISR_TAMP1MF TAMP_MISR_TAMP1MF_Msk
#define TAMP_MISR_TAMP2MF_Pos (1U)
#define TAMP_MISR_TAMP2MF_Msk (0x1UL << TAMP_MISR_TAMP2MF_Pos) /*!< 0x00000002 */
#define TAMP_MISR_TAMP2MF TAMP_MISR_TAMP2MF_Msk
#define TAMP_MISR_TAMP3MF_Pos (2U)
#define TAMP_MISR_TAMP3MF_Msk (0x1UL << TAMP_MISR_TAMP3MF_Pos) /*!< 0x00000004 */
#define TAMP_MISR_TAMP3MF TAMP_MISR_TAMP3MF_Msk
#define TAMP_MISR_ITAMP3MF_Pos (18U)
#define TAMP_MISR_ITAMP3MF_Msk (0x1UL << TAMP_MISR_ITAMP3MF_Pos) /*!< 0x00040000 */
#define TAMP_MISR_ITAMP3MF TAMP_MISR_ITAMP3MF_Msk
#define TAMP_MISR_ITAMP4MF_Pos (19U)
#define TAMP_MISR_ITAMP4MF_Msk (0x1UL << TAMP_MISR_ITAMP4MF_Pos) /*!< 0x00080000 */
#define TAMP_MISR_ITAMP4MF TAMP_MISR_ITAMP4MF_Msk
#define TAMP_MISR_ITAMP5MF_Pos (20U)
#define TAMP_MISR_ITAMP5MF_Msk (0x1UL << TAMP_MISR_ITAMP5MF_Pos) /*!< 0x00100000 */
#define TAMP_MISR_ITAMP5MF TAMP_MISR_ITAMP5MF_Msk
#define TAMP_MISR_ITAMP6MF_Pos (21U)
#define TAMP_MISR_ITAMP6MF_Msk (0x1UL << TAMP_MISR_ITAMP6MF_Pos) /*!< 0x00200000 */
#define TAMP_MISR_ITAMP6MF TAMP_MISR_ITAMP6MF_Msk
/******************** Bits definition for TAMP_SCR register *****************/
#define TAMP_SCR_CTAMP1F_Pos (0U)
#define TAMP_SCR_CTAMP1F_Msk (0x1UL << TAMP_SCR_CTAMP1F_Pos) /*!< 0x00000001 */
#define TAMP_SCR_CTAMP1F TAMP_SCR_CTAMP1F_Msk
#define TAMP_SCR_CTAMP2F_Pos (1U)
#define TAMP_SCR_CTAMP2F_Msk (0x1UL << TAMP_SCR_CTAMP2F_Pos) /*!< 0x00000002 */
#define TAMP_SCR_CTAMP2F TAMP_SCR_CTAMP2F_Msk
#define TAMP_SCR_CTAMP3F_Pos (2U)
#define TAMP_SCR_CTAMP3F_Msk (0x1UL << TAMP_SCR_CTAMP3F_Pos) /*!< 0x00000004 */
#define TAMP_SCR_CTAMP3F TAMP_SCR_CTAMP3F_Msk
#define TAMP_SCR_CITAMP3F_Pos (18U)
#define TAMP_SCR_CITAMP3F_Msk (0x1UL << TAMP_SCR_CITAMP3F_Pos) /*!< 0x00040000 */
#define TAMP_SCR_CITAMP3F TAMP_SCR_CITAMP3F_Msk
#define TAMP_SCR_CITAMP4F_Pos (19U)
#define TAMP_SCR_CITAMP4F_Msk (0x1UL << TAMP_SCR_CITAMP4F_Pos) /*!< 0x00080000 */
#define TAMP_SCR_CITAMP4F TAMP_SCR_CITAMP4F_Msk
#define TAMP_SCR_CITAMP5F_Pos (20U)
#define TAMP_SCR_CITAMP5F_Msk (0x1UL << TAMP_SCR_CITAMP5F_Pos) /*!< 0x00100000 */
#define TAMP_SCR_CITAMP5F TAMP_SCR_CITAMP5F_Msk
#define TAMP_SCR_CITAMP6F_Pos (21U)
#define TAMP_SCR_CITAMP6F_Msk (0x1UL << TAMP_SCR_CITAMP6F_Pos) /*!< 0x00200000 */
#define TAMP_SCR_CITAMP6F TAMP_SCR_CITAMP6F_Msk
/******************** Bits definition for TAMP_BKP0R register ***************/
#define TAMP_BKP0R_Pos (0U)
#define TAMP_BKP0R_Msk (0xFFFFFFFFUL << TAMP_BKP0R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP0R TAMP_BKP0R_Msk
/******************** Bits definition for TAMP_BKP1R register ***************/
#define TAMP_BKP1R_Pos (0U)
#define TAMP_BKP1R_Msk (0xFFFFFFFFUL << TAMP_BKP1R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP1R TAMP_BKP1R_Msk
/******************** Bits definition for TAMP_BKP2R register ***************/
#define TAMP_BKP2R_Pos (0U)
#define TAMP_BKP2R_Msk (0xFFFFFFFFUL << TAMP_BKP2R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP2R TAMP_BKP2R_Msk
/******************** Bits definition for TAMP_BKP3R register ***************/
#define TAMP_BKP3R_Pos (0U)
#define TAMP_BKP3R_Msk (0xFFFFFFFFUL << TAMP_BKP3R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP3R TAMP_BKP3R_Msk
/******************** Bits definition for TAMP_BKP4R register ***************/
#define TAMP_BKP4R_Pos (0U)
#define TAMP_BKP4R_Msk (0xFFFFFFFFUL << TAMP_BKP4R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP4R TAMP_BKP4R_Msk
/******************** Bits definition for TAMP_BKP5R register ***************/
#define TAMP_BKP5R_Pos (0U)
#define TAMP_BKP5R_Msk (0xFFFFFFFFUL << TAMP_BKP5R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP5R TAMP_BKP5R_Msk
/******************** Bits definition for TAMP_BKP6R register ***************/
#define TAMP_BKP6R_Pos (0U)
#define TAMP_BKP6R_Msk (0xFFFFFFFFUL << TAMP_BKP6R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP6R TAMP_BKP6R_Msk
/******************** Bits definition for TAMP_BKP7R register ***************/
#define TAMP_BKP7R_Pos (0U)
#define TAMP_BKP7R_Msk (0xFFFFFFFFUL << TAMP_BKP7R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP7R TAMP_BKP7R_Msk
/******************** Bits definition for TAMP_BKP8R register ***************/
#define TAMP_BKP8R_Pos (0U)
#define TAMP_BKP8R_Msk (0xFFFFFFFFUL << TAMP_BKP8R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP8R TAMP_BKP8R_Msk
/******************** Bits definition for TAMP_BKP9R register ***************/
#define TAMP_BKP9R_Pos (0U)
#define TAMP_BKP9R_Msk (0xFFFFFFFFUL << TAMP_BKP9R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP9R TAMP_BKP9R_Msk
/******************** Bits definition for TAMP_BKP10R register ***************/
#define TAMP_BKP10R_Pos (0U)
#define TAMP_BKP10R_Msk (0xFFFFFFFFUL << TAMP_BKP10R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP10R TAMP_BKP10R_Msk
/******************** Bits definition for TAMP_BKP11R register ***************/
#define TAMP_BKP11R_Pos (0U)
#define TAMP_BKP11R_Msk (0xFFFFFFFFUL << TAMP_BKP11R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP11R TAMP_BKP11R_Msk
/******************** Bits definition for TAMP_BKP12R register ***************/
#define TAMP_BKP12R_Pos (0U)
#define TAMP_BKP12R_Msk (0xFFFFFFFFUL << TAMP_BKP12R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP12R TAMP_BKP12R_Msk
/******************** Bits definition for TAMP_BKP13R register ***************/
#define TAMP_BKP13R_Pos (0U)
#define TAMP_BKP13R_Msk (0xFFFFFFFFUL << TAMP_BKP13R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP13R TAMP_BKP13R_Msk
/******************** Bits definition for TAMP_BKP14R register ***************/
#define TAMP_BKP14R_Pos (0U)
#define TAMP_BKP14R_Msk (0xFFFFFFFFUL << TAMP_BKP14R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP14R TAMP_BKP14R_Msk
/******************** Bits definition for TAMP_BKP15R register ***************/
#define TAMP_BKP15R_Pos (0U)
#define TAMP_BKP15R_Msk (0xFFFFFFFFUL << TAMP_BKP15R_Pos) /*!< 0xFFFFFFFF */
#define TAMP_BKP15R TAMP_BKP15R_Msk
/******************************************************************************/
/* */
/* Serial Audio Interface */
/* */
/******************************************************************************/
/******************* Bit definition for SAI_xCR1 register *******************/
#define SAI_xCR1_MODE_Pos (0U)
#define SAI_xCR1_MODE_Msk (0x3UL << SAI_xCR1_MODE_Pos) /*!< 0x00000003 */
#define SAI_xCR1_MODE SAI_xCR1_MODE_Msk /*!<MODE[1:0] bits (Audio Block Mode) */
#define SAI_xCR1_MODE_0 (0x1UL << SAI_xCR1_MODE_Pos) /*!< 0x00000001 */
#define SAI_xCR1_MODE_1 (0x2UL << SAI_xCR1_MODE_Pos) /*!< 0x00000002 */
#define SAI_xCR1_PRTCFG_Pos (2U)
#define SAI_xCR1_PRTCFG_Msk (0x3UL << SAI_xCR1_PRTCFG_Pos) /*!< 0x0000000C */
#define SAI_xCR1_PRTCFG SAI_xCR1_PRTCFG_Msk /*!<PRTCFG[1:0] bits (Protocol Configuration) */
#define SAI_xCR1_PRTCFG_0 (0x1UL << SAI_xCR1_PRTCFG_Pos) /*!< 0x00000004 */
#define SAI_xCR1_PRTCFG_1 (0x2UL << SAI_xCR1_PRTCFG_Pos) /*!< 0x00000008 */
#define SAI_xCR1_DS_Pos (5U)
#define SAI_xCR1_DS_Msk (0x7UL << SAI_xCR1_DS_Pos) /*!< 0x000000E0 */
#define SAI_xCR1_DS SAI_xCR1_DS_Msk /*!<DS[1:0] bits (Data Size) */
#define SAI_xCR1_DS_0 (0x1UL << SAI_xCR1_DS_Pos) /*!< 0x00000020 */
#define SAI_xCR1_DS_1 (0x2UL << SAI_xCR1_DS_Pos) /*!< 0x00000040 */
#define SAI_xCR1_DS_2 (0x4UL << SAI_xCR1_DS_Pos) /*!< 0x00000080 */
#define SAI_xCR1_LSBFIRST_Pos (8U)
#define SAI_xCR1_LSBFIRST_Msk (0x1UL << SAI_xCR1_LSBFIRST_Pos) /*!< 0x00000100 */
#define SAI_xCR1_LSBFIRST SAI_xCR1_LSBFIRST_Msk /*!<LSB First Configuration */
#define SAI_xCR1_CKSTR_Pos (9U)
#define SAI_xCR1_CKSTR_Msk (0x1UL << SAI_xCR1_CKSTR_Pos) /*!< 0x00000200 */
#define SAI_xCR1_CKSTR SAI_xCR1_CKSTR_Msk /*!<ClocK STRobing edge */
#define SAI_xCR1_SYNCEN_Pos (10U)
#define SAI_xCR1_SYNCEN_Msk (0x3UL << SAI_xCR1_SYNCEN_Pos) /*!< 0x00000C00 */
#define SAI_xCR1_SYNCEN SAI_xCR1_SYNCEN_Msk /*!<SYNCEN[1:0](SYNChronization ENable) */
#define SAI_xCR1_SYNCEN_0 (0x1UL << SAI_xCR1_SYNCEN_Pos) /*!< 0x00000400 */
#define SAI_xCR1_SYNCEN_1 (0x2UL << SAI_xCR1_SYNCEN_Pos) /*!< 0x00000800 */
#define SAI_xCR1_MONO_Pos (12U)
#define SAI_xCR1_MONO_Msk (0x1UL << SAI_xCR1_MONO_Pos) /*!< 0x00001000 */
#define SAI_xCR1_MONO SAI_xCR1_MONO_Msk /*!<Mono mode */
#define SAI_xCR1_OUTDRIV_Pos (13U)
#define SAI_xCR1_OUTDRIV_Msk (0x1UL << SAI_xCR1_OUTDRIV_Pos) /*!< 0x00002000 */
#define SAI_xCR1_OUTDRIV SAI_xCR1_OUTDRIV_Msk /*!<Output Drive */
#define SAI_xCR1_SAIEN_Pos (16U)
#define SAI_xCR1_SAIEN_Msk (0x1UL << SAI_xCR1_SAIEN_Pos) /*!< 0x00010000 */
#define SAI_xCR1_SAIEN SAI_xCR1_SAIEN_Msk /*!<Audio Block enable */
#define SAI_xCR1_DMAEN_Pos (17U)
#define SAI_xCR1_DMAEN_Msk (0x1UL << SAI_xCR1_DMAEN_Pos) /*!< 0x00020000 */
#define SAI_xCR1_DMAEN SAI_xCR1_DMAEN_Msk /*!<DMA enable */
#define SAI_xCR1_NODIV_Pos (19U)
#define SAI_xCR1_NODIV_Msk (0x1UL << SAI_xCR1_NODIV_Pos) /*!< 0x00080000 */
#define SAI_xCR1_NODIV SAI_xCR1_NODIV_Msk /*!<No Divider Configuration */
#define SAI_xCR1_MCKDIV_Pos (20U)
#define SAI_xCR1_MCKDIV_Msk (0x3FUL << SAI_xCR1_MCKDIV_Pos) /*!< 0x03F00000 */
#define SAI_xCR1_MCKDIV SAI_xCR1_MCKDIV_Msk /*!<MCKDIV[5:0] (Master ClocK Divider) */
#define SAI_xCR1_MCKDIV_0 (0x00100000U) /*!<Bit 0 */
#define SAI_xCR1_MCKDIV_1 (0x00200000U) /*!<Bit 1 */
#define SAI_xCR1_MCKDIV_2 (0x00400000U) /*!<Bit 2 */
#define SAI_xCR1_MCKDIV_3 (0x00800000U) /*!<Bit 3 */
#define SAI_xCR1_MCKDIV_4 (0x01000000U) /*!<Bit 4 */
#define SAI_xCR1_MCKDIV_5 (0x02000000U) /*!<Bit 5 */
#define SAI_xCR1_OSR_Pos (26U)
#define SAI_xCR1_OSR_Msk (0x1UL << SAI_xCR1_OSR_Pos) /*!< 0x04000000 */
#define SAI_xCR1_OSR SAI_xCR1_OSR_Msk /*!<Oversampling ratio for master clock */
#define SAI_xCR1_MCKEN_Pos (27U)
#define SAI_xCR1_MCKEN_Msk (0x1UL << SAI_xCR1_MCKEN_Pos) /*!< 0x08000000 */
#define SAI_xCR1_MCKEN SAI_xCR1_MCKEN_Msk /*!<Master clock generation enable */
/******************* Bit definition for SAI_xCR2 register *******************/
#define SAI_xCR2_FTH_Pos (0U)
#define SAI_xCR2_FTH_Msk (0x7UL << SAI_xCR2_FTH_Pos) /*!< 0x00000007 */
#define SAI_xCR2_FTH SAI_xCR2_FTH_Msk /*!<FTH[2:0](Fifo THreshold) */
#define SAI_xCR2_FTH_0 (0x1UL << SAI_xCR2_FTH_Pos) /*!< 0x00000001 */
#define SAI_xCR2_FTH_1 (0x2UL << SAI_xCR2_FTH_Pos) /*!< 0x00000002 */
#define SAI_xCR2_FTH_2 (0x4UL << SAI_xCR2_FTH_Pos) /*!< 0x00000004 */
#define SAI_xCR2_FFLUSH_Pos (3U)
#define SAI_xCR2_FFLUSH_Msk (0x1UL << SAI_xCR2_FFLUSH_Pos) /*!< 0x00000008 */
#define SAI_xCR2_FFLUSH SAI_xCR2_FFLUSH_Msk /*!<Fifo FLUSH */
#define SAI_xCR2_TRIS_Pos (4U)
#define SAI_xCR2_TRIS_Msk (0x1UL << SAI_xCR2_TRIS_Pos) /*!< 0x00000010 */
#define SAI_xCR2_TRIS SAI_xCR2_TRIS_Msk /*!<TRIState Management on data line */
#define SAI_xCR2_MUTE_Pos (5U)
#define SAI_xCR2_MUTE_Msk (0x1UL << SAI_xCR2_MUTE_Pos) /*!< 0x00000020 */
#define SAI_xCR2_MUTE SAI_xCR2_MUTE_Msk /*!<Mute mode */
#define SAI_xCR2_MUTEVAL_Pos (6U)
#define SAI_xCR2_MUTEVAL_Msk (0x1UL << SAI_xCR2_MUTEVAL_Pos) /*!< 0x00000040 */
#define SAI_xCR2_MUTEVAL SAI_xCR2_MUTEVAL_Msk /*!<Muate value */
#define SAI_xCR2_MUTECNT_Pos (7U)
#define SAI_xCR2_MUTECNT_Msk (0x3FUL << SAI_xCR2_MUTECNT_Pos) /*!< 0x00001F80 */
#define SAI_xCR2_MUTECNT SAI_xCR2_MUTECNT_Msk /*!<MUTECNT[5:0] (MUTE counter) */
#define SAI_xCR2_MUTECNT_0 (0x01UL << SAI_xCR2_MUTECNT_Pos) /*!< 0x00000080 */
#define SAI_xCR2_MUTECNT_1 (0x02UL << SAI_xCR2_MUTECNT_Pos) /*!< 0x00000100 */
#define SAI_xCR2_MUTECNT_2 (0x04UL << SAI_xCR2_MUTECNT_Pos) /*!< 0x00000200 */
#define SAI_xCR2_MUTECNT_3 (0x08UL << SAI_xCR2_MUTECNT_Pos) /*!< 0x00000400 */
#define SAI_xCR2_MUTECNT_4 (0x10UL << SAI_xCR2_MUTECNT_Pos) /*!< 0x00000800 */
#define SAI_xCR2_MUTECNT_5 (0x20UL << SAI_xCR2_MUTECNT_Pos) /*!< 0x00001000 */
#define SAI_xCR2_CPL_Pos (13U)
#define SAI_xCR2_CPL_Msk (0x1UL << SAI_xCR2_CPL_Pos) /*!< 0x00002000 */
#define SAI_xCR2_CPL SAI_xCR2_CPL_Msk /*!<CPL mode */
#define SAI_xCR2_COMP_Pos (14U)
#define SAI_xCR2_COMP_Msk (0x3UL << SAI_xCR2_COMP_Pos) /*!< 0x0000C000 */
#define SAI_xCR2_COMP SAI_xCR2_COMP_Msk /*!<COMP[1:0] (Companding mode) */
#define SAI_xCR2_COMP_0 (0x1UL << SAI_xCR2_COMP_Pos) /*!< 0x00004000 */
#define SAI_xCR2_COMP_1 (0x2UL << SAI_xCR2_COMP_Pos) /*!< 0x00008000 */
/****************** Bit definition for SAI_xFRCR register *******************/
#define SAI_xFRCR_FRL_Pos (0U)
#define SAI_xFRCR_FRL_Msk (0xFFUL << SAI_xFRCR_FRL_Pos) /*!< 0x000000FF */
#define SAI_xFRCR_FRL SAI_xFRCR_FRL_Msk /*!<FRL[7:0](Frame length) */
#define SAI_xFRCR_FRL_0 (0x01UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000001 */
#define SAI_xFRCR_FRL_1 (0x02UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000002 */
#define SAI_xFRCR_FRL_2 (0x04UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000004 */
#define SAI_xFRCR_FRL_3 (0x08UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000008 */
#define SAI_xFRCR_FRL_4 (0x10UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000010 */
#define SAI_xFRCR_FRL_5 (0x20UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000020 */
#define SAI_xFRCR_FRL_6 (0x40UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000040 */
#define SAI_xFRCR_FRL_7 (0x80UL << SAI_xFRCR_FRL_Pos) /*!< 0x00000080 */
#define SAI_xFRCR_FSALL_Pos (8U)
#define SAI_xFRCR_FSALL_Msk (0x7FUL << SAI_xFRCR_FSALL_Pos) /*!< 0x00007F00 */
#define SAI_xFRCR_FSALL SAI_xFRCR_FSALL_Msk /*!<FRL[6:0] (Frame synchronization active level length) */
#define SAI_xFRCR_FSALL_0 (0x01UL << SAI_xFRCR_FSALL_Pos) /*!< 0x00000100 */
#define SAI_xFRCR_FSALL_1 (0x02UL << SAI_xFRCR_FSALL_Pos) /*!< 0x00000200 */
#define SAI_xFRCR_FSALL_2 (0x04UL << SAI_xFRCR_FSALL_Pos) /*!< 0x00000400 */
#define SAI_xFRCR_FSALL_3 (0x08UL << SAI_xFRCR_FSALL_Pos) /*!< 0x00000800 */
#define SAI_xFRCR_FSALL_4 (0x10UL << SAI_xFRCR_FSALL_Pos) /*!< 0x00001000 */
#define SAI_xFRCR_FSALL_5 (0x20UL << SAI_xFRCR_FSALL_Pos) /*!< 0x00002000 */
#define SAI_xFRCR_FSALL_6 (0x40UL << SAI_xFRCR_FSALL_Pos) /*!< 0x00004000 */
#define SAI_xFRCR_FSDEF_Pos (16U)
#define SAI_xFRCR_FSDEF_Msk (0x1UL << SAI_xFRCR_FSDEF_Pos) /*!< 0x00010000 */
#define SAI_xFRCR_FSDEF SAI_xFRCR_FSDEF_Msk /*!< Frame Synchronization Definition */
#define SAI_xFRCR_FSPOL_Pos (17U)
#define SAI_xFRCR_FSPOL_Msk (0x1UL << SAI_xFRCR_FSPOL_Pos) /*!< 0x00020000 */
#define SAI_xFRCR_FSPOL SAI_xFRCR_FSPOL_Msk /*!<Frame Synchronization POLarity */
#define SAI_xFRCR_FSOFF_Pos (18U)
#define SAI_xFRCR_FSOFF_Msk (0x1UL << SAI_xFRCR_FSOFF_Pos) /*!< 0x00040000 */
#define SAI_xFRCR_FSOFF SAI_xFRCR_FSOFF_Msk /*!<Frame Synchronization OFFset */
/****************** Bit definition for SAI_xSLOTR register *******************/
#define SAI_xSLOTR_FBOFF_Pos (0U)
#define SAI_xSLOTR_FBOFF_Msk (0x1FUL << SAI_xSLOTR_FBOFF_Pos) /*!< 0x0000001F */
#define SAI_xSLOTR_FBOFF SAI_xSLOTR_FBOFF_Msk /*!<FRL[4:0](First Bit Offset) */
#define SAI_xSLOTR_FBOFF_0 (0x01UL << SAI_xSLOTR_FBOFF_Pos) /*!< 0x00000001 */
#define SAI_xSLOTR_FBOFF_1 (0x02UL << SAI_xSLOTR_FBOFF_Pos) /*!< 0x00000002 */
#define SAI_xSLOTR_FBOFF_2 (0x04UL << SAI_xSLOTR_FBOFF_Pos) /*!< 0x00000004 */
#define SAI_xSLOTR_FBOFF_3 (0x08UL << SAI_xSLOTR_FBOFF_Pos) /*!< 0x00000008 */
#define SAI_xSLOTR_FBOFF_4 (0x10UL << SAI_xSLOTR_FBOFF_Pos) /*!< 0x00000010 */
#define SAI_xSLOTR_SLOTSZ_Pos (6U)
#define SAI_xSLOTR_SLOTSZ_Msk (0x3UL << SAI_xSLOTR_SLOTSZ_Pos) /*!< 0x000000C0 */
#define SAI_xSLOTR_SLOTSZ SAI_xSLOTR_SLOTSZ_Msk /*!<SLOTSZ[1:0] (Slot size) */
#define SAI_xSLOTR_SLOTSZ_0 (0x1UL << SAI_xSLOTR_SLOTSZ_Pos) /*!< 0x00000040 */
#define SAI_xSLOTR_SLOTSZ_1 (0x2UL << SAI_xSLOTR_SLOTSZ_Pos) /*!< 0x00000080 */
#define SAI_xSLOTR_NBSLOT_Pos (8U)
#define SAI_xSLOTR_NBSLOT_Msk (0xFUL << SAI_xSLOTR_NBSLOT_Pos) /*!< 0x00000F00 */
#define SAI_xSLOTR_NBSLOT SAI_xSLOTR_NBSLOT_Msk /*!<NBSLOT[3:0] (Number of Slot in audio Frame) */
#define SAI_xSLOTR_NBSLOT_0 (0x1UL << SAI_xSLOTR_NBSLOT_Pos) /*!< 0x00000100 */
#define SAI_xSLOTR_NBSLOT_1 (0x2UL << SAI_xSLOTR_NBSLOT_Pos) /*!< 0x00000200 */
#define SAI_xSLOTR_NBSLOT_2 (0x4UL << SAI_xSLOTR_NBSLOT_Pos) /*!< 0x00000400 */
#define SAI_xSLOTR_NBSLOT_3 (0x8UL << SAI_xSLOTR_NBSLOT_Pos) /*!< 0x00000800 */
#define SAI_xSLOTR_SLOTEN_Pos (16U)
#define SAI_xSLOTR_SLOTEN_Msk (0xFFFFUL << SAI_xSLOTR_SLOTEN_Pos) /*!< 0xFFFF0000 */
#define SAI_xSLOTR_SLOTEN SAI_xSLOTR_SLOTEN_Msk /*!<SLOTEN[15:0] (Slot Enable) */
/******************* Bit definition for SAI_xIMR register *******************/
#define SAI_xIMR_OVRUDRIE_Pos (0U)
#define SAI_xIMR_OVRUDRIE_Msk (0x1UL << SAI_xIMR_OVRUDRIE_Pos) /*!< 0x00000001 */
#define SAI_xIMR_OVRUDRIE SAI_xIMR_OVRUDRIE_Msk /*!<Overrun underrun interrupt enable */
#define SAI_xIMR_MUTEDETIE_Pos (1U)
#define SAI_xIMR_MUTEDETIE_Msk (0x1UL << SAI_xIMR_MUTEDETIE_Pos) /*!< 0x00000002 */
#define SAI_xIMR_MUTEDETIE SAI_xIMR_MUTEDETIE_Msk /*!<Mute detection interrupt enable */
#define SAI_xIMR_WCKCFGIE_Pos (2U)
#define SAI_xIMR_WCKCFGIE_Msk (0x1UL << SAI_xIMR_WCKCFGIE_Pos) /*!< 0x00000004 */
#define SAI_xIMR_WCKCFGIE SAI_xIMR_WCKCFGIE_Msk /*!<Wrong Clock Configuration interrupt enable */
#define SAI_xIMR_FREQIE_Pos (3U)
#define SAI_xIMR_FREQIE_Msk (0x1UL << SAI_xIMR_FREQIE_Pos) /*!< 0x00000008 */
#define SAI_xIMR_FREQIE SAI_xIMR_FREQIE_Msk /*!<FIFO request interrupt enable */
#define SAI_xIMR_CNRDYIE_Pos (4U)
#define SAI_xIMR_CNRDYIE_Msk (0x1UL << SAI_xIMR_CNRDYIE_Pos) /*!< 0x00000010 */
#define SAI_xIMR_CNRDYIE SAI_xIMR_CNRDYIE_Msk /*!<Codec not ready interrupt enable */
#define SAI_xIMR_AFSDETIE_Pos (5U)
#define SAI_xIMR_AFSDETIE_Msk (0x1UL << SAI_xIMR_AFSDETIE_Pos) /*!< 0x00000020 */
#define SAI_xIMR_AFSDETIE SAI_xIMR_AFSDETIE_Msk /*!<Anticipated frame synchronization detection interrupt enable */
#define SAI_xIMR_LFSDETIE_Pos (6U)
#define SAI_xIMR_LFSDETIE_Msk (0x1UL << SAI_xIMR_LFSDETIE_Pos) /*!< 0x00000040 */
#define SAI_xIMR_LFSDETIE SAI_xIMR_LFSDETIE_Msk /*!<Late frame synchronization detection interrupt enable */
/******************** Bit definition for SAI_xSR register *******************/
#define SAI_xSR_OVRUDR_Pos (0U)
#define SAI_xSR_OVRUDR_Msk (0x1UL << SAI_xSR_OVRUDR_Pos) /*!< 0x00000001 */
#define SAI_xSR_OVRUDR SAI_xSR_OVRUDR_Msk /*!<Overrun underrun */
#define SAI_xSR_MUTEDET_Pos (1U)
#define SAI_xSR_MUTEDET_Msk (0x1UL << SAI_xSR_MUTEDET_Pos) /*!< 0x00000002 */
#define SAI_xSR_MUTEDET SAI_xSR_MUTEDET_Msk /*!<Mute detection */
#define SAI_xSR_WCKCFG_Pos (2U)
#define SAI_xSR_WCKCFG_Msk (0x1UL << SAI_xSR_WCKCFG_Pos) /*!< 0x00000004 */
#define SAI_xSR_WCKCFG SAI_xSR_WCKCFG_Msk /*!<Wrong Clock Configuration */
#define SAI_xSR_FREQ_Pos (3U)
#define SAI_xSR_FREQ_Msk (0x1UL << SAI_xSR_FREQ_Pos) /*!< 0x00000008 */
#define SAI_xSR_FREQ SAI_xSR_FREQ_Msk /*!<FIFO request */
#define SAI_xSR_CNRDY_Pos (4U)
#define SAI_xSR_CNRDY_Msk (0x1UL << SAI_xSR_CNRDY_Pos) /*!< 0x00000010 */
#define SAI_xSR_CNRDY SAI_xSR_CNRDY_Msk /*!<Codec not ready */
#define SAI_xSR_AFSDET_Pos (5U)
#define SAI_xSR_AFSDET_Msk (0x1UL << SAI_xSR_AFSDET_Pos) /*!< 0x00000020 */
#define SAI_xSR_AFSDET SAI_xSR_AFSDET_Msk /*!<Anticipated frame synchronization detection */
#define SAI_xSR_LFSDET_Pos (6U)
#define SAI_xSR_LFSDET_Msk (0x1UL << SAI_xSR_LFSDET_Pos) /*!< 0x00000040 */
#define SAI_xSR_LFSDET SAI_xSR_LFSDET_Msk /*!<Late frame synchronization detection */
#define SAI_xSR_FLVL_Pos (16U)
#define SAI_xSR_FLVL_Msk (0x7UL << SAI_xSR_FLVL_Pos) /*!< 0x00070000 */
#define SAI_xSR_FLVL SAI_xSR_FLVL_Msk /*!<FLVL[2:0] (FIFO Level Threshold) */
#define SAI_xSR_FLVL_0 (0x1UL << SAI_xSR_FLVL_Pos) /*!< 0x00010000 */
#define SAI_xSR_FLVL_1 (0x2UL << SAI_xSR_FLVL_Pos) /*!< 0x00020000 */
#define SAI_xSR_FLVL_2 (0x4UL << SAI_xSR_FLVL_Pos) /*!< 0x00040000 */
/****************** Bit definition for SAI_xCLRFR register ******************/
#define SAI_xCLRFR_COVRUDR_Pos (0U)
#define SAI_xCLRFR_COVRUDR_Msk (0x1UL << SAI_xCLRFR_COVRUDR_Pos) /*!< 0x00000001 */
#define SAI_xCLRFR_COVRUDR SAI_xCLRFR_COVRUDR_Msk /*!<Clear Overrun underrun */
#define SAI_xCLRFR_CMUTEDET_Pos (1U)
#define SAI_xCLRFR_CMUTEDET_Msk (0x1UL << SAI_xCLRFR_CMUTEDET_Pos) /*!< 0x00000002 */
#define SAI_xCLRFR_CMUTEDET SAI_xCLRFR_CMUTEDET_Msk /*!<Clear Mute detection */
#define SAI_xCLRFR_CWCKCFG_Pos (2U)
#define SAI_xCLRFR_CWCKCFG_Msk (0x1UL << SAI_xCLRFR_CWCKCFG_Pos) /*!< 0x00000004 */
#define SAI_xCLRFR_CWCKCFG SAI_xCLRFR_CWCKCFG_Msk /*!<Clear Wrong Clock Configuration */
#define SAI_xCLRFR_CFREQ_Pos (3U)
#define SAI_xCLRFR_CFREQ_Msk (0x1UL << SAI_xCLRFR_CFREQ_Pos) /*!< 0x00000008 */
#define SAI_xCLRFR_CFREQ SAI_xCLRFR_CFREQ_Msk /*!<Clear FIFO request */
#define SAI_xCLRFR_CCNRDY_Pos (4U)
#define SAI_xCLRFR_CCNRDY_Msk (0x1UL << SAI_xCLRFR_CCNRDY_Pos) /*!< 0x00000010 */
#define SAI_xCLRFR_CCNRDY SAI_xCLRFR_CCNRDY_Msk /*!<Clear Codec not ready */
#define SAI_xCLRFR_CAFSDET_Pos (5U)
#define SAI_xCLRFR_CAFSDET_Msk (0x1UL << SAI_xCLRFR_CAFSDET_Pos) /*!< 0x00000020 */
#define SAI_xCLRFR_CAFSDET SAI_xCLRFR_CAFSDET_Msk /*!<Clear Anticipated frame synchronization detection */
#define SAI_xCLRFR_CLFSDET_Pos (6U)
#define SAI_xCLRFR_CLFSDET_Msk (0x1UL << SAI_xCLRFR_CLFSDET_Pos) /*!< 0x00000040 */
#define SAI_xCLRFR_CLFSDET SAI_xCLRFR_CLFSDET_Msk /*!<Clear Late frame synchronization detection */
/****************** Bit definition for SAI_xDR register ******************/
#define SAI_xDR_DATA_Pos (0U)
#define SAI_xDR_DATA_Msk (0xFFFFFFFFUL << SAI_xDR_DATA_Pos) /*!< 0xFFFFFFFF */
#define SAI_xDR_DATA SAI_xDR_DATA_Msk
/****************** Bit definition for SAI_PDMCR register *******************/
#define SAI_PDMCR_PDMEN_Pos (0U)
#define SAI_PDMCR_PDMEN_Msk (0x1UL << SAI_PDMCR_PDMEN_Pos) /*!< 0x00000001 */
#define SAI_PDMCR_PDMEN SAI_PDMCR_PDMEN_Msk /*!<PDM enable */
#define SAI_PDMCR_MICNBR_Pos (4U)
#define SAI_PDMCR_MICNBR_Msk (0x3UL << SAI_PDMCR_MICNBR_Pos) /*!< 0x00000030 */
#define SAI_PDMCR_MICNBR SAI_PDMCR_MICNBR_Msk /*!<MICNBR[1:0] (Number of microphones) */
#define SAI_PDMCR_MICNBR_0 (0x1UL << SAI_PDMCR_MICNBR_Pos) /*!< 0x00000010 */
#define SAI_PDMCR_MICNBR_1 (0x2UL << SAI_PDMCR_MICNBR_Pos) /*!< 0x00000020 */
#define SAI_PDMCR_CKEN1_Pos (8U)
#define SAI_PDMCR_CKEN1_Msk (0x1UL << SAI_PDMCR_CKEN1_Pos) /*!< 0x00000100 */
#define SAI_PDMCR_CKEN1 SAI_PDMCR_CKEN1_Msk /*!<Clock 1 enable */
#define SAI_PDMCR_CKEN2_Pos (9U)
#define SAI_PDMCR_CKEN2_Msk (0x1UL << SAI_PDMCR_CKEN2_Pos) /*!< 0x00000200 */
#define SAI_PDMCR_CKEN2 SAI_PDMCR_CKEN2_Msk /*!<Clock 2 enable */
#define SAI_PDMCR_CKEN3_Pos (10U)
#define SAI_PDMCR_CKEN3_Msk (0x1UL << SAI_PDMCR_CKEN3_Pos) /*!< 0x00000400 */
#define SAI_PDMCR_CKEN3 SAI_PDMCR_CKEN3_Msk /*!<Clock 3 enable */
#define SAI_PDMCR_CKEN4_Pos (11U)
#define SAI_PDMCR_CKEN4_Msk (0x1UL << SAI_PDMCR_CKEN4_Pos) /*!< 0x00000800 */
#define SAI_PDMCR_CKEN4 SAI_PDMCR_CKEN4_Msk /*!<Clock 4 enable */
/****************** Bit definition for SAI_PDMDLY register ******************/
#define SAI_PDMDLY_DLYM1L_Pos (0U)
#define SAI_PDMDLY_DLYM1L_Msk (0x7UL << SAI_PDMDLY_DLYM1L_Pos) /*!< 0x00000007 */
#define SAI_PDMDLY_DLYM1L SAI_PDMDLY_DLYM1L_Msk /*!<DLYM1L[2:0] (Delay line adjust for left microphone of pair 1) */
#define SAI_PDMDLY_DLYM1L_0 (0x1UL << SAI_PDMDLY_DLYM1L_Pos) /*!< 0x00000001 */
#define SAI_PDMDLY_DLYM1L_1 (0x2UL << SAI_PDMDLY_DLYM1L_Pos) /*!< 0x00000002 */
#define SAI_PDMDLY_DLYM1L_2 (0x4UL << SAI_PDMDLY_DLYM1L_Pos) /*!< 0x00000004 */
#define SAI_PDMDLY_DLYM1R_Pos (4U)
#define SAI_PDMDLY_DLYM1R_Msk (0x7UL << SAI_PDMDLY_DLYM1R_Pos) /*!< 0x00000070 */
#define SAI_PDMDLY_DLYM1R SAI_PDMDLY_DLYM1R_Msk /*!<DLYM1R[2:0] (Delay line adjust for right microphone of pair 1) */
#define SAI_PDMDLY_DLYM1R_0 (0x1UL << SAI_PDMDLY_DLYM1R_Pos) /*!< 0x00000010 */
#define SAI_PDMDLY_DLYM1R_1 (0x2UL << SAI_PDMDLY_DLYM1R_Pos) /*!< 0x00000020 */
#define SAI_PDMDLY_DLYM1R_2 (0x4UL << SAI_PDMDLY_DLYM1R_Pos) /*!< 0x00000040 */
#define SAI_PDMDLY_DLYM2L_Pos (8U)
#define SAI_PDMDLY_DLYM2L_Msk (0x7UL << SAI_PDMDLY_DLYM2L_Pos) /*!< 0x00000700 */
#define SAI_PDMDLY_DLYM2L SAI_PDMDLY_DLYM2L_Msk /*!<DLYM2L[2:0] (Delay line adjust for left microphone of pair 2) */
#define SAI_PDMDLY_DLYM2L_0 (0x1UL << SAI_PDMDLY_DLYM2L_Pos) /*!< 0x00000100 */
#define SAI_PDMDLY_DLYM2L_1 (0x2UL << SAI_PDMDLY_DLYM2L_Pos) /*!< 0x00000200 */
#define SAI_PDMDLY_DLYM2L_2 (0x4UL << SAI_PDMDLY_DLYM2L_Pos) /*!< 0x00000400 */
#define SAI_PDMDLY_DLYM2R_Pos (12U)
#define SAI_PDMDLY_DLYM2R_Msk (0x7UL << SAI_PDMDLY_DLYM2R_Pos) /*!< 0x00007000 */
#define SAI_PDMDLY_DLYM2R SAI_PDMDLY_DLYM2R_Msk /*!<DLYM2R[2:0] (Delay line adjust for right microphone of pair 2) */
#define SAI_PDMDLY_DLYM2R_0 (0x1UL << SAI_PDMDLY_DLYM2R_Pos) /*!< 0x00001000 */
#define SAI_PDMDLY_DLYM2R_1 (0x2UL << SAI_PDMDLY_DLYM2R_Pos) /*!< 0x00002000 */
#define SAI_PDMDLY_DLYM2R_2 (0x4UL << SAI_PDMDLY_DLYM2R_Pos) /*!< 0x00004000 */
#define SAI_PDMDLY_DLYM3L_Pos (16U)
#define SAI_PDMDLY_DLYM3L_Msk (0x7UL << SAI_PDMDLY_DLYM3L_Pos) /*!< 0x00070000 */
#define SAI_PDMDLY_DLYM3L SAI_PDMDLY_DLYM3L_Msk /*!<DLYM3L[2:0] (Delay line adjust for left microphone of pair 3) */
#define SAI_PDMDLY_DLYM3L_0 (0x1UL << SAI_PDMDLY_DLYM3L_Pos) /*!< 0x00010000 */
#define SAI_PDMDLY_DLYM3L_1 (0x2UL << SAI_PDMDLY_DLYM3L_Pos) /*!< 0x00020000 */
#define SAI_PDMDLY_DLYM3L_2 (0x4UL << SAI_PDMDLY_DLYM3L_Pos) /*!< 0x00040000 */
#define SAI_PDMDLY_DLYM3R_Pos (20U)
#define SAI_PDMDLY_DLYM3R_Msk (0x7UL << SAI_PDMDLY_DLYM3R_Pos) /*!< 0x00700000 */
#define SAI_PDMDLY_DLYM3R SAI_PDMDLY_DLYM3R_Msk /*!<DLYM3R[2:0] (Delay line adjust for right microphone of pair 3) */
#define SAI_PDMDLY_DLYM3R_0 (0x1UL << SAI_PDMDLY_DLYM3R_Pos) /*!< 0x00100000 */
#define SAI_PDMDLY_DLYM3R_1 (0x2UL << SAI_PDMDLY_DLYM3R_Pos) /*!< 0x00200000 */
#define SAI_PDMDLY_DLYM3R_2 (0x4UL << SAI_PDMDLY_DLYM3R_Pos) /*!< 0x00400000 */
#define SAI_PDMDLY_DLYM4L_Pos (24U)
#define SAI_PDMDLY_DLYM4L_Msk (0x7UL << SAI_PDMDLY_DLYM4L_Pos) /*!< 0x07000000 */
#define SAI_PDMDLY_DLYM4L SAI_PDMDLY_DLYM4L_Msk /*!<DLYM4L[2:0] (Delay line adjust for left microphone of pair 4) */
#define SAI_PDMDLY_DLYM4L_0 (0x1UL << SAI_PDMDLY_DLYM4L_Pos) /*!< 0x01000000 */
#define SAI_PDMDLY_DLYM4L_1 (0x2UL << SAI_PDMDLY_DLYM4L_Pos) /*!< 0x02000000 */
#define SAI_PDMDLY_DLYM4L_2 (0x4UL << SAI_PDMDLY_DLYM4L_Pos) /*!< 0x04000000 */
#define SAI_PDMDLY_DLYM4R_Pos (28U)
#define SAI_PDMDLY_DLYM4R_Msk (0x7UL << SAI_PDMDLY_DLYM4R_Pos) /*!< 0x70000000 */
#define SAI_PDMDLY_DLYM4R SAI_PDMDLY_DLYM4R_Msk /*!<DLYM4R[2:0] (Delay line adjust for right microphone of pair 4) */
#define SAI_PDMDLY_DLYM4R_0 (0x1UL << SAI_PDMDLY_DLYM4R_Pos) /*!< 0x10000000 */
#define SAI_PDMDLY_DLYM4R_1 (0x2UL << SAI_PDMDLY_DLYM4R_Pos) /*!< 0x20000000 */
#define SAI_PDMDLY_DLYM4R_2 (0x4UL << SAI_PDMDLY_DLYM4R_Pos) /*!< 0x40000000 */
/******************************************************************************/
/* */
/* Serial Peripheral Interface (SPI) */
/* */
/******************************************************************************/
/*
* @brief Specific device feature definitions (not present on all devices in the STM32G4 series)
*/
#define SPI_I2S_SUPPORT /*!< I2S support */
/******************* Bit definition for SPI_CR1 register ********************/
#define SPI_CR1_CPHA_Pos (0U)
#define SPI_CR1_CPHA_Msk (0x1UL << SPI_CR1_CPHA_Pos) /*!< 0x00000001 */
#define SPI_CR1_CPHA SPI_CR1_CPHA_Msk /*!<Clock Phase */
#define SPI_CR1_CPOL_Pos (1U)
#define SPI_CR1_CPOL_Msk (0x1UL << SPI_CR1_CPOL_Pos) /*!< 0x00000002 */
#define SPI_CR1_CPOL SPI_CR1_CPOL_Msk /*!<Clock Polarity */
#define SPI_CR1_MSTR_Pos (2U)
#define SPI_CR1_MSTR_Msk (0x1UL << SPI_CR1_MSTR_Pos) /*!< 0x00000004 */
#define SPI_CR1_MSTR SPI_CR1_MSTR_Msk /*!<Master Selection */
#define SPI_CR1_BR_Pos (3U)
#define SPI_CR1_BR_Msk (0x7UL << SPI_CR1_BR_Pos) /*!< 0x00000038 */
#define SPI_CR1_BR SPI_CR1_BR_Msk /*!<BR[2:0] bits (Baud Rate Control) */
#define SPI_CR1_BR_0 (0x1UL << SPI_CR1_BR_Pos) /*!< 0x00000008 */
#define SPI_CR1_BR_1 (0x2UL << SPI_CR1_BR_Pos) /*!< 0x00000010 */
#define SPI_CR1_BR_2 (0x4UL << SPI_CR1_BR_Pos) /*!< 0x00000020 */
#define SPI_CR1_SPE_Pos (6U)
#define SPI_CR1_SPE_Msk (0x1UL << SPI_CR1_SPE_Pos) /*!< 0x00000040 */
#define SPI_CR1_SPE SPI_CR1_SPE_Msk /*!<SPI Enable */
#define SPI_CR1_LSBFIRST_Pos (7U)
#define SPI_CR1_LSBFIRST_Msk (0x1UL << SPI_CR1_LSBFIRST_Pos) /*!< 0x00000080 */
#define SPI_CR1_LSBFIRST SPI_CR1_LSBFIRST_Msk /*!<Frame Format */
#define SPI_CR1_SSI_Pos (8U)
#define SPI_CR1_SSI_Msk (0x1UL << SPI_CR1_SSI_Pos) /*!< 0x00000100 */
#define SPI_CR1_SSI SPI_CR1_SSI_Msk /*!<Internal slave select */
#define SPI_CR1_SSM_Pos (9U)
#define SPI_CR1_SSM_Msk (0x1UL << SPI_CR1_SSM_Pos) /*!< 0x00000200 */
#define SPI_CR1_SSM SPI_CR1_SSM_Msk /*!<Software slave management */
#define SPI_CR1_RXONLY_Pos (10U)
#define SPI_CR1_RXONLY_Msk (0x1UL << SPI_CR1_RXONLY_Pos) /*!< 0x00000400 */
#define SPI_CR1_RXONLY SPI_CR1_RXONLY_Msk /*!<Receive only */
#define SPI_CR1_CRCL_Pos (11U)
#define SPI_CR1_CRCL_Msk (0x1UL << SPI_CR1_CRCL_Pos) /*!< 0x00000800 */
#define SPI_CR1_CRCL SPI_CR1_CRCL_Msk /*!< CRC Length */
#define SPI_CR1_CRCNEXT_Pos (12U)
#define SPI_CR1_CRCNEXT_Msk (0x1UL << SPI_CR1_CRCNEXT_Pos) /*!< 0x00001000 */
#define SPI_CR1_CRCNEXT SPI_CR1_CRCNEXT_Msk /*!<Transmit CRC next */
#define SPI_CR1_CRCEN_Pos (13U)
#define SPI_CR1_CRCEN_Msk (0x1UL << SPI_CR1_CRCEN_Pos) /*!< 0x00002000 */
#define SPI_CR1_CRCEN SPI_CR1_CRCEN_Msk /*!<Hardware CRC calculation enable */
#define SPI_CR1_BIDIOE_Pos (14U)
#define SPI_CR1_BIDIOE_Msk (0x1UL << SPI_CR1_BIDIOE_Pos) /*!< 0x00004000 */
#define SPI_CR1_BIDIOE SPI_CR1_BIDIOE_Msk /*!<Output enable in bidirectional mode */
#define SPI_CR1_BIDIMODE_Pos (15U)
#define SPI_CR1_BIDIMODE_Msk (0x1UL << SPI_CR1_BIDIMODE_Pos) /*!< 0x00008000 */
#define SPI_CR1_BIDIMODE SPI_CR1_BIDIMODE_Msk /*!<Bidirectional data mode enable */
/******************* Bit definition for SPI_CR2 register ********************/
#define SPI_CR2_RXDMAEN_Pos (0U)
#define SPI_CR2_RXDMAEN_Msk (0x1UL << SPI_CR2_RXDMAEN_Pos) /*!< 0x00000001 */
#define SPI_CR2_RXDMAEN SPI_CR2_RXDMAEN_Msk /*!< Rx Buffer DMA Enable */
#define SPI_CR2_TXDMAEN_Pos (1U)
#define SPI_CR2_TXDMAEN_Msk (0x1UL << SPI_CR2_TXDMAEN_Pos) /*!< 0x00000002 */
#define SPI_CR2_TXDMAEN SPI_CR2_TXDMAEN_Msk /*!< Tx Buffer DMA Enable */
#define SPI_CR2_SSOE_Pos (2U)
#define SPI_CR2_SSOE_Msk (0x1UL << SPI_CR2_SSOE_Pos) /*!< 0x00000004 */
#define SPI_CR2_SSOE SPI_CR2_SSOE_Msk /*!< SS Output Enable */
#define SPI_CR2_NSSP_Pos (3U)
#define SPI_CR2_NSSP_Msk (0x1UL << SPI_CR2_NSSP_Pos) /*!< 0x00000008 */
#define SPI_CR2_NSSP SPI_CR2_NSSP_Msk /*!< NSS pulse management Enable */
#define SPI_CR2_FRF_Pos (4U)
#define SPI_CR2_FRF_Msk (0x1UL << SPI_CR2_FRF_Pos) /*!< 0x00000010 */
#define SPI_CR2_FRF SPI_CR2_FRF_Msk /*!< Frame Format Enable */
#define SPI_CR2_ERRIE_Pos (5U)
#define SPI_CR2_ERRIE_Msk (0x1UL << SPI_CR2_ERRIE_Pos) /*!< 0x00000020 */
#define SPI_CR2_ERRIE SPI_CR2_ERRIE_Msk /*!< Error Interrupt Enable */
#define SPI_CR2_RXNEIE_Pos (6U)
#define SPI_CR2_RXNEIE_Msk (0x1UL << SPI_CR2_RXNEIE_Pos) /*!< 0x00000040 */
#define SPI_CR2_RXNEIE SPI_CR2_RXNEIE_Msk /*!< RX buffer Not Empty Interrupt Enable */
#define SPI_CR2_TXEIE_Pos (7U)
#define SPI_CR2_TXEIE_Msk (0x1UL << SPI_CR2_TXEIE_Pos) /*!< 0x00000080 */
#define SPI_CR2_TXEIE SPI_CR2_TXEIE_Msk /*!< Tx buffer Empty Interrupt Enable */
#define SPI_CR2_DS_Pos (8U)
#define SPI_CR2_DS_Msk (0xFUL << SPI_CR2_DS_Pos) /*!< 0x00000F00 */
#define SPI_CR2_DS SPI_CR2_DS_Msk /*!< DS[3:0] Data Size */
#define SPI_CR2_DS_0 (0x1UL << SPI_CR2_DS_Pos) /*!< 0x00000100 */
#define SPI_CR2_DS_1 (0x2UL << SPI_CR2_DS_Pos) /*!< 0x00000200 */
#define SPI_CR2_DS_2 (0x4UL << SPI_CR2_DS_Pos) /*!< 0x00000400 */
#define SPI_CR2_DS_3 (0x8UL << SPI_CR2_DS_Pos) /*!< 0x00000800 */
#define SPI_CR2_FRXTH_Pos (12U)
#define SPI_CR2_FRXTH_Msk (0x1UL << SPI_CR2_FRXTH_Pos) /*!< 0x00001000 */
#define SPI_CR2_FRXTH SPI_CR2_FRXTH_Msk /*!< FIFO reception Threshold */
#define SPI_CR2_LDMARX_Pos (13U)
#define SPI_CR2_LDMARX_Msk (0x1UL << SPI_CR2_LDMARX_Pos) /*!< 0x00002000 */
#define SPI_CR2_LDMARX SPI_CR2_LDMARX_Msk /*!< Last DMA transfer for reception */
#define SPI_CR2_LDMATX_Pos (14U)
#define SPI_CR2_LDMATX_Msk (0x1UL << SPI_CR2_LDMATX_Pos) /*!< 0x00004000 */
#define SPI_CR2_LDMATX SPI_CR2_LDMATX_Msk /*!< Last DMA transfer for transmission */
/******************** Bit definition for SPI_SR register ********************/
#define SPI_SR_RXNE_Pos (0U)
#define SPI_SR_RXNE_Msk (0x1UL << SPI_SR_RXNE_Pos) /*!< 0x00000001 */
#define SPI_SR_RXNE SPI_SR_RXNE_Msk /*!< Receive buffer Not Empty */
#define SPI_SR_TXE_Pos (1U)
#define SPI_SR_TXE_Msk (0x1UL << SPI_SR_TXE_Pos) /*!< 0x00000002 */
#define SPI_SR_TXE SPI_SR_TXE_Msk /*!< Transmit buffer Empty */
#define SPI_SR_CHSIDE_Pos (2U)
#define SPI_SR_CHSIDE_Msk (0x1UL << SPI_SR_CHSIDE_Pos) /*!< 0x00000004 */
#define SPI_SR_CHSIDE SPI_SR_CHSIDE_Msk /*!< Channel side */
#define SPI_SR_UDR_Pos (3U)
#define SPI_SR_UDR_Msk (0x1UL << SPI_SR_UDR_Pos) /*!< 0x00000008 */
#define SPI_SR_UDR SPI_SR_UDR_Msk /*!< Underrun flag */
#define SPI_SR_CRCERR_Pos (4U)
#define SPI_SR_CRCERR_Msk (0x1UL << SPI_SR_CRCERR_Pos) /*!< 0x00000010 */
#define SPI_SR_CRCERR SPI_SR_CRCERR_Msk /*!< CRC Error flag */
#define SPI_SR_MODF_Pos (5U)
#define SPI_SR_MODF_Msk (0x1UL << SPI_SR_MODF_Pos) /*!< 0x00000020 */
#define SPI_SR_MODF SPI_SR_MODF_Msk /*!< Mode fault */
#define SPI_SR_OVR_Pos (6U)
#define SPI_SR_OVR_Msk (0x1UL << SPI_SR_OVR_Pos) /*!< 0x00000040 */
#define SPI_SR_OVR SPI_SR_OVR_Msk /*!< Overrun flag */
#define SPI_SR_BSY_Pos (7U)
#define SPI_SR_BSY_Msk (0x1UL << SPI_SR_BSY_Pos) /*!< 0x00000080 */
#define SPI_SR_BSY SPI_SR_BSY_Msk /*!< Busy flag */
#define SPI_SR_FRE_Pos (8U)
#define SPI_SR_FRE_Msk (0x1UL << SPI_SR_FRE_Pos) /*!< 0x00000100 */
#define SPI_SR_FRE SPI_SR_FRE_Msk /*!< TI frame format error */
#define SPI_SR_FRLVL_Pos (9U)
#define SPI_SR_FRLVL_Msk (0x3UL << SPI_SR_FRLVL_Pos) /*!< 0x00000600 */
#define SPI_SR_FRLVL SPI_SR_FRLVL_Msk /*!< FIFO Reception Level */
#define SPI_SR_FRLVL_0 (0x1UL << SPI_SR_FRLVL_Pos) /*!< 0x00000200 */
#define SPI_SR_FRLVL_1 (0x2UL << SPI_SR_FRLVL_Pos) /*!< 0x00000400 */
#define SPI_SR_FTLVL_Pos (11U)
#define SPI_SR_FTLVL_Msk (0x3UL << SPI_SR_FTLVL_Pos) /*!< 0x00001800 */
#define SPI_SR_FTLVL SPI_SR_FTLVL_Msk /*!< FIFO Transmission Level */
#define SPI_SR_FTLVL_0 (0x1UL << SPI_SR_FTLVL_Pos) /*!< 0x00000800 */
#define SPI_SR_FTLVL_1 (0x2UL << SPI_SR_FTLVL_Pos) /*!< 0x00001000 */
/******************** Bit definition for SPI_DR register ********************/
#define SPI_DR_DR_Pos (0U)
#define SPI_DR_DR_Msk (0xFFFFUL << SPI_DR_DR_Pos) /*!< 0x0000FFFF */
#define SPI_DR_DR SPI_DR_DR_Msk /*!<Data Register */
/******************* Bit definition for SPI_CRCPR register ******************/
#define SPI_CRCPR_CRCPOLY_Pos (0U)
#define SPI_CRCPR_CRCPOLY_Msk (0xFFFFUL << SPI_CRCPR_CRCPOLY_Pos) /*!< 0x0000FFFF */
#define SPI_CRCPR_CRCPOLY SPI_CRCPR_CRCPOLY_Msk /*!<CRC polynomial register */
/****************** Bit definition for SPI_RXCRCR register ******************/
#define SPI_RXCRCR_RXCRC_Pos (0U)
#define SPI_RXCRCR_RXCRC_Msk (0xFFFFUL << SPI_RXCRCR_RXCRC_Pos) /*!< 0x0000FFFF */
#define SPI_RXCRCR_RXCRC SPI_RXCRCR_RXCRC_Msk /*!<Rx CRC Register */
/****************** Bit definition for SPI_TXCRCR register ******************/
#define SPI_TXCRCR_TXCRC_Pos (0U)
#define SPI_TXCRCR_TXCRC_Msk (0xFFFFUL << SPI_TXCRCR_TXCRC_Pos) /*!< 0x0000FFFF */
#define SPI_TXCRCR_TXCRC SPI_TXCRCR_TXCRC_Msk /*!<Tx CRC Register */
/****************** Bit definition for SPI_I2SCFGR register *****************/
#define SPI_I2SCFGR_CHLEN_Pos (0U)
#define SPI_I2SCFGR_CHLEN_Msk (0x1UL << SPI_I2SCFGR_CHLEN_Pos) /*!< 0x00000001 */
#define SPI_I2SCFGR_CHLEN SPI_I2SCFGR_CHLEN_Msk /*!<Channel length (number of bits per audio channel) */
#define SPI_I2SCFGR_DATLEN_Pos (1U)
#define SPI_I2SCFGR_DATLEN_Msk (0x3UL << SPI_I2SCFGR_DATLEN_Pos) /*!< 0x00000006 */
#define SPI_I2SCFGR_DATLEN SPI_I2SCFGR_DATLEN_Msk /*!<DATLEN[1:0] bits (Data length to be transferred) */
#define SPI_I2SCFGR_DATLEN_0 (0x1UL << SPI_I2SCFGR_DATLEN_Pos) /*!< 0x00000002 */
#define SPI_I2SCFGR_DATLEN_1 (0x2UL << SPI_I2SCFGR_DATLEN_Pos) /*!< 0x00000004 */
#define SPI_I2SCFGR_CKPOL_Pos (3U)
#define SPI_I2SCFGR_CKPOL_Msk (0x1UL << SPI_I2SCFGR_CKPOL_Pos) /*!< 0x00000008 */
#define SPI_I2SCFGR_CKPOL SPI_I2SCFGR_CKPOL_Msk /*!<steady state clock polarity */
#define SPI_I2SCFGR_I2SSTD_Pos (4U)
#define SPI_I2SCFGR_I2SSTD_Msk (0x3UL << SPI_I2SCFGR_I2SSTD_Pos) /*!< 0x00000030 */
#define SPI_I2SCFGR_I2SSTD SPI_I2SCFGR_I2SSTD_Msk /*!<I2SSTD[1:0] bits (I2S standard selection) */
#define SPI_I2SCFGR_I2SSTD_0 (0x1UL << SPI_I2SCFGR_I2SSTD_Pos) /*!< 0x00000010 */
#define SPI_I2SCFGR_I2SSTD_1 (0x2UL << SPI_I2SCFGR_I2SSTD_Pos) /*!< 0x00000020 */
#define SPI_I2SCFGR_PCMSYNC_Pos (7U)
#define SPI_I2SCFGR_PCMSYNC_Msk (0x1UL << SPI_I2SCFGR_PCMSYNC_Pos) /*!< 0x00000080 */
#define SPI_I2SCFGR_PCMSYNC SPI_I2SCFGR_PCMSYNC_Msk /*!<PCM frame synchronization */
#define SPI_I2SCFGR_I2SCFG_Pos (8U)
#define SPI_I2SCFGR_I2SCFG_Msk (0x3UL << SPI_I2SCFGR_I2SCFG_Pos) /*!< 0x00000300 */
#define SPI_I2SCFGR_I2SCFG SPI_I2SCFGR_I2SCFG_Msk /*!<I2SCFG[1:0] bits (I2S configuration mode) */
#define SPI_I2SCFGR_I2SCFG_0 (0x1UL << SPI_I2SCFGR_I2SCFG_Pos) /*!< 0x00000100 */
#define SPI_I2SCFGR_I2SCFG_1 (0x2UL << SPI_I2SCFGR_I2SCFG_Pos) /*!< 0x00000200 */
#define SPI_I2SCFGR_I2SE_Pos (10U)
#define SPI_I2SCFGR_I2SE_Msk (0x1UL << SPI_I2SCFGR_I2SE_Pos) /*!< 0x00000400 */
#define SPI_I2SCFGR_I2SE SPI_I2SCFGR_I2SE_Msk /*!<I2S Enable */
#define SPI_I2SCFGR_I2SMOD_Pos (11U)
#define SPI_I2SCFGR_I2SMOD_Msk (0x1UL << SPI_I2SCFGR_I2SMOD_Pos) /*!< 0x00000800 */
#define SPI_I2SCFGR_I2SMOD SPI_I2SCFGR_I2SMOD_Msk /*!<I2S mode selection */
#define SPI_I2SCFGR_ASTRTEN_Pos (12U)
#define SPI_I2SCFGR_ASTRTEN_Msk (0x1UL << SPI_I2SCFGR_ASTRTEN_Pos) /*!< 0x00001000 */
#define SPI_I2SCFGR_ASTRTEN SPI_I2SCFGR_ASTRTEN_Msk /*!<Asynchronous start enable */
/****************** Bit definition for SPI_I2SPR register *******************/
#define SPI_I2SPR_I2SDIV_Pos (0U)
#define SPI_I2SPR_I2SDIV_Msk (0xFFUL << SPI_I2SPR_I2SDIV_Pos) /*!< 0x000000FF */
#define SPI_I2SPR_I2SDIV SPI_I2SPR_I2SDIV_Msk /*!<I2S Linear prescaler */
#define SPI_I2SPR_ODD_Pos (8U)
#define SPI_I2SPR_ODD_Msk (0x1UL << SPI_I2SPR_ODD_Pos) /*!< 0x00000100 */
#define SPI_I2SPR_ODD SPI_I2SPR_ODD_Msk /*!<Odd factor for the prescaler */
#define SPI_I2SPR_MCKOE_Pos (9U)
#define SPI_I2SPR_MCKOE_Msk (0x1UL << SPI_I2SPR_MCKOE_Pos) /*!< 0x00000200 */
#define SPI_I2SPR_MCKOE SPI_I2SPR_MCKOE_Msk /*!<Master Clock Output Enable */
/******************************************************************************/
/* */
/* SYSCFG */
/* */
/******************************************************************************/
/****************** Bit definition for SYSCFG_MEMRMP register ***************/
#define SYSCFG_MEMRMP_MEM_MODE_Pos (0U)
#define SYSCFG_MEMRMP_MEM_MODE_Msk (0x7UL << SYSCFG_MEMRMP_MEM_MODE_Pos) /*!< 0x00000007 */
#define SYSCFG_MEMRMP_MEM_MODE SYSCFG_MEMRMP_MEM_MODE_Msk /*!< SYSCFG_Memory Remap Config */
#define SYSCFG_MEMRMP_MEM_MODE_0 (0x1UL << SYSCFG_MEMRMP_MEM_MODE_Pos) /*!< 0x00000001 */
#define SYSCFG_MEMRMP_MEM_MODE_1 (0x2UL << SYSCFG_MEMRMP_MEM_MODE_Pos) /*!< 0x00000002 */
#define SYSCFG_MEMRMP_MEM_MODE_2 (0x4UL << SYSCFG_MEMRMP_MEM_MODE_Pos) /*!< 0x00000004 */
#define SYSCFG_MEMRMP_FB_MODE_Pos (8U)
#define SYSCFG_MEMRMP_FB_MODE_Msk (0x1UL << SYSCFG_MEMRMP_FB_MODE_Pos) /*!< 0x00000100 */
#define SYSCFG_MEMRMP_FB_MODE SYSCFG_MEMRMP_FB_MODE_Msk /*!< User Flash Bank mode selection */
/****************** Bit definition for SYSCFG_CFGR1 register ******************/
#define SYSCFG_CFGR1_BOOSTEN_Pos (8U)
#define SYSCFG_CFGR1_BOOSTEN_Msk (0x1UL << SYSCFG_CFGR1_BOOSTEN_Pos) /*!< 0x00000100 */
#define SYSCFG_CFGR1_BOOSTEN SYSCFG_CFGR1_BOOSTEN_Msk /*!< I/O analog switch voltage booster enable */
#define SYSCFG_CFGR1_ANASWVDD_Pos (9U)
#define SYSCFG_CFGR1_ANASWVDD_Msk (0x1UL << SYSCFG_CFGR1_ANASWVDD_Pos) /*!< 0x00000200 */
#define SYSCFG_CFGR1_ANASWVDD SYSCFG_CFGR1_ANASWVDD_Msk /*!< GPIO analog switch control voltage selection */
#define SYSCFG_CFGR1_I2C_PB6_FMP_Pos (16U)
#define SYSCFG_CFGR1_I2C_PB6_FMP_Msk (0x1UL << SYSCFG_CFGR1_I2C_PB6_FMP_Pos)/*!< 0x00010000 */
#define SYSCFG_CFGR1_I2C_PB6_FMP SYSCFG_CFGR1_I2C_PB6_FMP_Msk /*!< I2C PB6 Fast mode plus */
#define SYSCFG_CFGR1_I2C_PB7_FMP_Pos (17U)
#define SYSCFG_CFGR1_I2C_PB7_FMP_Msk (0x1UL << SYSCFG_CFGR1_I2C_PB7_FMP_Pos)/*!< 0x00020000 */
#define SYSCFG_CFGR1_I2C_PB7_FMP SYSCFG_CFGR1_I2C_PB7_FMP_Msk /*!< I2C PB7 Fast mode plus */
#define SYSCFG_CFGR1_I2C_PB8_FMP_Pos (18U)
#define SYSCFG_CFGR1_I2C_PB8_FMP_Msk (0x1UL << SYSCFG_CFGR1_I2C_PB8_FMP_Pos)/*!< 0x00040000 */
#define SYSCFG_CFGR1_I2C_PB8_FMP SYSCFG_CFGR1_I2C_PB8_FMP_Msk /*!< I2C PB8 Fast mode plus */
#define SYSCFG_CFGR1_I2C_PB9_FMP_Pos (19U)
#define SYSCFG_CFGR1_I2C_PB9_FMP_Msk (0x1UL << SYSCFG_CFGR1_I2C_PB9_FMP_Pos)/*!< 0x00080000 */
#define SYSCFG_CFGR1_I2C_PB9_FMP SYSCFG_CFGR1_I2C_PB9_FMP_Msk /*!< I2C PB9 Fast mode plus */
#define SYSCFG_CFGR1_I2C1_FMP_Pos (20U)
#define SYSCFG_CFGR1_I2C1_FMP_Msk (0x1UL << SYSCFG_CFGR1_I2C1_FMP_Pos) /*!< 0x00100000 */
#define SYSCFG_CFGR1_I2C1_FMP SYSCFG_CFGR1_I2C1_FMP_Msk /*!< I2C1 Fast mode plus */
#define SYSCFG_CFGR1_I2C2_FMP_Pos (21U)
#define SYSCFG_CFGR1_I2C2_FMP_Msk (0x1UL << SYSCFG_CFGR1_I2C2_FMP_Pos) /*!< 0x00200000 */
#define SYSCFG_CFGR1_I2C2_FMP SYSCFG_CFGR1_I2C2_FMP_Msk /*!< I2C2 Fast mode plus */
#define SYSCFG_CFGR1_I2C3_FMP_Pos (22U)
#define SYSCFG_CFGR1_I2C3_FMP_Msk (0x1UL << SYSCFG_CFGR1_I2C3_FMP_Pos) /*!< 0x00400000 */
#define SYSCFG_CFGR1_I2C3_FMP SYSCFG_CFGR1_I2C3_FMP_Msk /*!< I2C3 Fast mode plus */
#define SYSCFG_CFGR1_FPU_IE_0 (0x04000000U) /*!< Invalid operation Interrupt enable */
#define SYSCFG_CFGR1_FPU_IE_1 (0x08000000U) /*!< Divide-by-zero Interrupt enable */
#define SYSCFG_CFGR1_FPU_IE_2 (0x10000000U) /*!< Underflow Interrupt enable */
#define SYSCFG_CFGR1_FPU_IE_3 (0x20000000U) /*!< Overflow Interrupt enable */
#define SYSCFG_CFGR1_FPU_IE_4 (0x40000000U) /*!< Input denormal Interrupt enable */
#define SYSCFG_CFGR1_FPU_IE_5 (0x80000000U) /*!< Inexact Interrupt enable (interrupt disabled at reset) */
/***************** Bit definition for SYSCFG_EXTICR1 register ***************/
#define SYSCFG_EXTICR1_EXTI0_Pos (0U)
#define SYSCFG_EXTICR1_EXTI0_Msk (0x7UL << SYSCFG_EXTICR1_EXTI0_Pos) /*!< 0x0000000F */
#define SYSCFG_EXTICR1_EXTI0 SYSCFG_EXTICR1_EXTI0_Msk /*!<EXTI 0 configuration */
#define SYSCFG_EXTICR1_EXTI1_Pos (4U)
#define SYSCFG_EXTICR1_EXTI1_Msk (0x7UL << SYSCFG_EXTICR1_EXTI1_Pos) /*!< 0x000000F0 */
#define SYSCFG_EXTICR1_EXTI1 SYSCFG_EXTICR1_EXTI1_Msk /*!<EXTI 1 configuration */
#define SYSCFG_EXTICR1_EXTI2_Pos (8U)
#define SYSCFG_EXTICR1_EXTI2_Msk (0x7UL << SYSCFG_EXTICR1_EXTI2_Pos) /*!< 0x00000F00 */
#define SYSCFG_EXTICR1_EXTI2 SYSCFG_EXTICR1_EXTI2_Msk /*!<EXTI 2 configuration */
#define SYSCFG_EXTICR1_EXTI3_Pos (12U)
#define SYSCFG_EXTICR1_EXTI3_Msk (0x7UL << SYSCFG_EXTICR1_EXTI3_Pos) /*!< 0x0000F000 */
#define SYSCFG_EXTICR1_EXTI3 SYSCFG_EXTICR1_EXTI3_Msk /*!<EXTI 3 configuration */
/**
* @brief EXTI0 configuration
*/
#define SYSCFG_EXTICR1_EXTI0_PA (0x00000000U) /*!<PA[0] pin */
#define SYSCFG_EXTICR1_EXTI0_PB (0x00000001U) /*!<PB[0] pin */
#define SYSCFG_EXTICR1_EXTI0_PC (0x00000002U) /*!<PC[0] pin */
#define SYSCFG_EXTICR1_EXTI0_PD (0x00000003U) /*!<PD[0] pin */
#define SYSCFG_EXTICR1_EXTI0_PE (0x00000004U) /*!<PE[0] pin */
#define SYSCFG_EXTICR1_EXTI0_PF (0x00000005U) /*!<PF[0] pin */
#define SYSCFG_EXTICR1_EXTI0_PG (0x00000006U) /*!<PG[0] pin */
/**
* @brief EXTI1 configuration
*/
#define SYSCFG_EXTICR1_EXTI1_PA (0x00000000U) /*!<PA[1] pin */
#define SYSCFG_EXTICR1_EXTI1_PB (0x00000010U) /*!<PB[1] pin */
#define SYSCFG_EXTICR1_EXTI1_PC (0x00000020U) /*!<PC[1] pin */
#define SYSCFG_EXTICR1_EXTI1_PD (0x00000030U) /*!<PD[1] pin */
#define SYSCFG_EXTICR1_EXTI1_PE (0x00000040U) /*!<PE[1] pin */
#define SYSCFG_EXTICR1_EXTI1_PF (0x00000050U) /*!<PF[1] pin */
#define SYSCFG_EXTICR1_EXTI1_PG (0x00000060U) /*!<PG[1] pin */
/**
* @brief EXTI2 configuration
*/
#define SYSCFG_EXTICR1_EXTI2_PA (0x00000000U) /*!<PA[2] pin */
#define SYSCFG_EXTICR1_EXTI2_PB (0x00000100U) /*!<PB[2] pin */
#define SYSCFG_EXTICR1_EXTI2_PC (0x00000200U) /*!<PC[2] pin */
#define SYSCFG_EXTICR1_EXTI2_PD (0x00000300U) /*!<PD[2] pin */
#define SYSCFG_EXTICR1_EXTI2_PE (0x00000400U) /*!<PE[2] pin */
#define SYSCFG_EXTICR1_EXTI2_PF (0x00000500U) /*!<PF[2] pin */
#define SYSCFG_EXTICR1_EXTI2_PG (0x00000600U) /*!<PG[2] pin */
/**
* @brief EXTI3 configuration
*/
#define SYSCFG_EXTICR1_EXTI3_PA (0x00000000U) /*!<PA[3] pin */
#define SYSCFG_EXTICR1_EXTI3_PB (0x00001000U) /*!<PB[3] pin */
#define SYSCFG_EXTICR1_EXTI3_PC (0x00002000U) /*!<PC[3] pin */
#define SYSCFG_EXTICR1_EXTI3_PD (0x00003000U) /*!<PD[3] pin */
#define SYSCFG_EXTICR1_EXTI3_PE (0x00004000U) /*!<PE[3] pin */
#define SYSCFG_EXTICR1_EXTI3_PF (0x00005000U) /*!<PF[3] pin */
#define SYSCFG_EXTICR1_EXTI3_PG (0x00006000U) /*!<PG[3] pin */
/***************** Bit definition for SYSCFG_EXTICR2 register ***************/
#define SYSCFG_EXTICR2_EXTI4_Pos (0U)
#define SYSCFG_EXTICR2_EXTI4_Msk (0x7UL << SYSCFG_EXTICR2_EXTI4_Pos) /*!< 0x0000000F */
#define SYSCFG_EXTICR2_EXTI4 SYSCFG_EXTICR2_EXTI4_Msk /*!<EXTI 4 configuration */
#define SYSCFG_EXTICR2_EXTI5_Pos (4U)
#define SYSCFG_EXTICR2_EXTI5_Msk (0x7UL << SYSCFG_EXTICR2_EXTI5_Pos) /*!< 0x000000F0 */
#define SYSCFG_EXTICR2_EXTI5 SYSCFG_EXTICR2_EXTI5_Msk /*!<EXTI 5 configuration */
#define SYSCFG_EXTICR2_EXTI6_Pos (8U)
#define SYSCFG_EXTICR2_EXTI6_Msk (0x7UL << SYSCFG_EXTICR2_EXTI6_Pos) /*!< 0x00000F00 */
#define SYSCFG_EXTICR2_EXTI6 SYSCFG_EXTICR2_EXTI6_Msk /*!<EXTI 6 configuration */
#define SYSCFG_EXTICR2_EXTI7_Pos (12U)
#define SYSCFG_EXTICR2_EXTI7_Msk (0x7UL << SYSCFG_EXTICR2_EXTI7_Pos) /*!< 0x0000F000 */
#define SYSCFG_EXTICR2_EXTI7 SYSCFG_EXTICR2_EXTI7_Msk /*!<EXTI 7 configuration */
/**
* @brief EXTI4 configuration
*/
#define SYSCFG_EXTICR2_EXTI4_PA (0x00000000U) /*!<PA[4] pin */
#define SYSCFG_EXTICR2_EXTI4_PB (0x00000001U) /*!<PB[4] pin */
#define SYSCFG_EXTICR2_EXTI4_PC (0x00000002U) /*!<PC[4] pin */
#define SYSCFG_EXTICR2_EXTI4_PD (0x00000003U) /*!<PD[4] pin */
#define SYSCFG_EXTICR2_EXTI4_PE (0x00000004U) /*!<PE[4] pin */
#define SYSCFG_EXTICR2_EXTI4_PF (0x00000005U) /*!<PF[4] pin */
#define SYSCFG_EXTICR2_EXTI4_PG (0x00000006U) /*!<PG[4] pin */
/**
* @brief EXTI5 configuration
*/
#define SYSCFG_EXTICR2_EXTI5_PA (0x00000000U) /*!<PA[5] pin */
#define SYSCFG_EXTICR2_EXTI5_PB (0x00000010U) /*!<PB[5] pin */
#define SYSCFG_EXTICR2_EXTI5_PC (0x00000020U) /*!<PC[5] pin */
#define SYSCFG_EXTICR2_EXTI5_PD (0x00000030U) /*!<PD[5] pin */
#define SYSCFG_EXTICR2_EXTI5_PE (0x00000040U) /*!<PE[5] pin */
#define SYSCFG_EXTICR2_EXTI5_PF (0x00000050U) /*!<PF[5] pin */
#define SYSCFG_EXTICR2_EXTI5_PG (0x00000060U) /*!<PG[5] pin */
/**
* @brief EXTI6 configuration
*/
#define SYSCFG_EXTICR2_EXTI6_PA (0x00000000U) /*!<PA[6] pin */
#define SYSCFG_EXTICR2_EXTI6_PB (0x00000100U) /*!<PB[6] pin */
#define SYSCFG_EXTICR2_EXTI6_PC (0x00000200U) /*!<PC[6] pin */
#define SYSCFG_EXTICR2_EXTI6_PD (0x00000300U) /*!<PD[6] pin */
#define SYSCFG_EXTICR2_EXTI6_PE (0x00000400U) /*!<PE[6] pin */
#define SYSCFG_EXTICR2_EXTI6_PF (0x00000500U) /*!<PF[6] pin */
#define SYSCFG_EXTICR2_EXTI6_PG (0x00000600U) /*!<PG[6] pin */
/**
* @brief EXTI7 configuration
*/
#define SYSCFG_EXTICR2_EXTI7_PA (0x00000000U) /*!<PA[7] pin */
#define SYSCFG_EXTICR2_EXTI7_PB (0x00001000U) /*!<PB[7] pin */
#define SYSCFG_EXTICR2_EXTI7_PC (0x00002000U) /*!<PC[7] pin */
#define SYSCFG_EXTICR2_EXTI7_PD (0x00003000U) /*!<PD[7] pin */
#define SYSCFG_EXTICR2_EXTI7_PE (0x00004000U) /*!<PE[7] pin */
#define SYSCFG_EXTICR2_EXTI7_PF (0x00005000U) /*!<PF[7] pin */
#define SYSCFG_EXTICR2_EXTI7_PG (0x00006000U) /*!<PG[7] pin */
/***************** Bit definition for SYSCFG_EXTICR3 register ***************/
#define SYSCFG_EXTICR3_EXTI8_Pos (0U)
#define SYSCFG_EXTICR3_EXTI8_Msk (0x7UL << SYSCFG_EXTICR3_EXTI8_Pos) /*!< 0x0000000F */
#define SYSCFG_EXTICR3_EXTI8 SYSCFG_EXTICR3_EXTI8_Msk /*!<EXTI 8 configuration */
#define SYSCFG_EXTICR3_EXTI9_Pos (4U)
#define SYSCFG_EXTICR3_EXTI9_Msk (0x7UL << SYSCFG_EXTICR3_EXTI9_Pos) /*!< 0x000000F0 */
#define SYSCFG_EXTICR3_EXTI9 SYSCFG_EXTICR3_EXTI9_Msk /*!<EXTI 9 configuration */
#define SYSCFG_EXTICR3_EXTI10_Pos (8U)
#define SYSCFG_EXTICR3_EXTI10_Msk (0x7UL << SYSCFG_EXTICR3_EXTI10_Pos) /*!< 0x00000F00 */
#define SYSCFG_EXTICR3_EXTI10 SYSCFG_EXTICR3_EXTI10_Msk /*!<EXTI 10 configuration */
#define SYSCFG_EXTICR3_EXTI11_Pos (12U)
#define SYSCFG_EXTICR3_EXTI11_Msk (0x7UL << SYSCFG_EXTICR3_EXTI11_Pos) /*!< 0x0000F000 */
#define SYSCFG_EXTICR3_EXTI11 SYSCFG_EXTICR3_EXTI11_Msk /*!<EXTI 11 configuration */
/**
* @brief EXTI8 configuration
*/
#define SYSCFG_EXTICR3_EXTI8_PA (0x00000000U) /*!<PA[8] pin */
#define SYSCFG_EXTICR3_EXTI8_PB (0x00000001U) /*!<PB[8] pin */
#define SYSCFG_EXTICR3_EXTI8_PC (0x00000002U) /*!<PC[8] pin */
#define SYSCFG_EXTICR3_EXTI8_PD (0x00000003U) /*!<PD[8] pin */
#define SYSCFG_EXTICR3_EXTI8_PE (0x00000004U) /*!<PE[8] pin */
#define SYSCFG_EXTICR3_EXTI8_PF (0x00000005U) /*!<PF[8] pin */
#define SYSCFG_EXTICR3_EXTI8_PG (0x00000006U) /*!<PG[8] pin */
/**
* @brief EXTI9 configuration
*/
#define SYSCFG_EXTICR3_EXTI9_PA (0x00000000U) /*!<PA[9] pin */
#define SYSCFG_EXTICR3_EXTI9_PB (0x00000010U) /*!<PB[9] pin */
#define SYSCFG_EXTICR3_EXTI9_PC (0x00000020U) /*!<PC[9] pin */
#define SYSCFG_EXTICR3_EXTI9_PD (0x00000030U) /*!<PD[9] pin */
#define SYSCFG_EXTICR3_EXTI9_PE (0x00000040U) /*!<PE[9] pin */
#define SYSCFG_EXTICR3_EXTI9_PF (0x00000050U) /*!<PF[9] pin */
#define SYSCFG_EXTICR3_EXTI9_PG (0x00000060U) /*!<PG[9] pin */
/**
* @brief EXTI10 configuration
*/
#define SYSCFG_EXTICR3_EXTI10_PA (0x00000000U) /*!<PA[10] pin */
#define SYSCFG_EXTICR3_EXTI10_PB (0x00000100U) /*!<PB[10] pin */
#define SYSCFG_EXTICR3_EXTI10_PC (0x00000200U) /*!<PC[10] pin */
#define SYSCFG_EXTICR3_EXTI10_PD (0x00000300U) /*!<PD[10] pin */
#define SYSCFG_EXTICR3_EXTI10_PE (0x00000400U) /*!<PE[10] pin */
#define SYSCFG_EXTICR3_EXTI10_PF (0x00000500U) /*!<PF[10] pin */
/**
* @brief EXTI11 configuration
*/
#define SYSCFG_EXTICR3_EXTI11_PA (0x00000000U) /*!<PA[11] pin */
#define SYSCFG_EXTICR3_EXTI11_PB (0x00001000U) /*!<PB[11] pin */
#define SYSCFG_EXTICR3_EXTI11_PC (0x00002000U) /*!<PC[11] pin */
#define SYSCFG_EXTICR3_EXTI11_PD (0x00003000U) /*!<PD[11] pin */
#define SYSCFG_EXTICR3_EXTI11_PE (0x00004000U) /*!<PE[11] pin */
#define SYSCFG_EXTICR3_EXTI11_PF (0x00005000U) /*!<PF[11] pin */
/***************** Bit definition for SYSCFG_EXTICR4 register ***************/
#define SYSCFG_EXTICR4_EXTI12_Pos (0U)
#define SYSCFG_EXTICR4_EXTI12_Msk (0x7UL << SYSCFG_EXTICR4_EXTI12_Pos) /*!< 0x00000007 */
#define SYSCFG_EXTICR4_EXTI12 SYSCFG_EXTICR4_EXTI12_Msk /*!<EXTI 12 configuration */
#define SYSCFG_EXTICR4_EXTI13_Pos (4U)
#define SYSCFG_EXTICR4_EXTI13_Msk (0x7UL << SYSCFG_EXTICR4_EXTI13_Pos) /*!< 0x00000070 */
#define SYSCFG_EXTICR4_EXTI13 SYSCFG_EXTICR4_EXTI13_Msk /*!<EXTI 13 configuration */
#define SYSCFG_EXTICR4_EXTI14_Pos (8U)
#define SYSCFG_EXTICR4_EXTI14_Msk (0x7UL << SYSCFG_EXTICR4_EXTI14_Pos) /*!< 0x00000700 */
#define SYSCFG_EXTICR4_EXTI14 SYSCFG_EXTICR4_EXTI14_Msk /*!<EXTI 14 configuration */
#define SYSCFG_EXTICR4_EXTI15_Pos (12U)
#define SYSCFG_EXTICR4_EXTI15_Msk (0x7UL << SYSCFG_EXTICR4_EXTI15_Pos) /*!< 0x00007000 */
#define SYSCFG_EXTICR4_EXTI15 SYSCFG_EXTICR4_EXTI15_Msk /*!<EXTI 15 configuration */
/**
* @brief EXTI12 configuration
*/
#define SYSCFG_EXTICR4_EXTI12_PA (0x00000000U) /*!<PA[12] pin */
#define SYSCFG_EXTICR4_EXTI12_PB (0x00000001U) /*!<PB[12] pin */
#define SYSCFG_EXTICR4_EXTI12_PC (0x00000002U) /*!<PC[12] pin */
#define SYSCFG_EXTICR4_EXTI12_PD (0x00000003U) /*!<PD[12] pin */
#define SYSCFG_EXTICR4_EXTI12_PE (0x00000004U) /*!<PE[12] pin */
#define SYSCFG_EXTICR4_EXTI12_PF (0x00000005U) /*!<PF[12] pin */
/**
* @brief EXTI13 configuration
*/
#define SYSCFG_EXTICR4_EXTI13_PA (0x00000000U) /*!<PA[13] pin */
#define SYSCFG_EXTICR4_EXTI13_PB (0x00000010U) /*!<PB[13] pin */
#define SYSCFG_EXTICR4_EXTI13_PC (0x00000020U) /*!<PC[13] pin */
#define SYSCFG_EXTICR4_EXTI13_PD (0x00000030U) /*!<PD[13] pin */
#define SYSCFG_EXTICR4_EXTI13_PE (0x00000040U) /*!<PE[13] pin */
#define SYSCFG_EXTICR4_EXTI13_PF (0x00000050U) /*!<PF[13] pin */
/**
* @brief EXTI14 configuration
*/
#define SYSCFG_EXTICR4_EXTI14_PA (0x00000000U) /*!<PA[14] pin */
#define SYSCFG_EXTICR4_EXTI14_PB (0x00000100U) /*!<PB[14] pin */
#define SYSCFG_EXTICR4_EXTI14_PC (0x00000200U) /*!<PC[14] pin */
#define SYSCFG_EXTICR4_EXTI14_PD (0x00000300U) /*!<PD[14] pin */
#define SYSCFG_EXTICR4_EXTI14_PE (0x00000400U) /*!<PE[14] pin */
#define SYSCFG_EXTICR4_EXTI14_PF (0x00000500U) /*!<PF[14] pin */
/**
* @brief EXTI15 configuration
*/
#define SYSCFG_EXTICR4_EXTI15_PA (0x00000000U) /*!<PA[15] pin */
#define SYSCFG_EXTICR4_EXTI15_PB (0x00001000U) /*!<PB[15] pin */
#define SYSCFG_EXTICR4_EXTI15_PC (0x00002000U) /*!<PC[15] pin */
#define SYSCFG_EXTICR4_EXTI15_PD (0x00003000U) /*!<PD[15] pin */
#define SYSCFG_EXTICR4_EXTI15_PE (0x00004000U) /*!<PE[15] pin */
#define SYSCFG_EXTICR4_EXTI15_PF (0x00005000U) /*!<PF[15] pin */
/****************** Bit definition for SYSCFG_SCSR register ****************/
#define SYSCFG_SCSR_CCMER_Pos (0U)
#define SYSCFG_SCSR_CCMER_Msk (0x1UL << SYSCFG_SCSR_CCMER_Pos) /*!< 0x00000001 */
#define SYSCFG_SCSR_CCMER SYSCFG_SCSR_CCMER_Msk /*!< CCMSRAM Erase Request */
#define SYSCFG_SCSR_CCMBSY_Pos (1U)
#define SYSCFG_SCSR_CCMBSY_Msk (0x1UL << SYSCFG_SCSR_CCMBSY_Pos) /*!< 0x00000002 */
#define SYSCFG_SCSR_CCMBSY SYSCFG_SCSR_CCMBSY_Msk /*!< CCMSRAM Erase Ongoing */
/****************** Bit definition for SYSCFG_CFGR2 register ****************/
#define SYSCFG_CFGR2_CLL_Pos (0U)
#define SYSCFG_CFGR2_CLL_Msk (0x1UL << SYSCFG_CFGR2_CLL_Pos) /*!< 0x00000001 */
#define SYSCFG_CFGR2_CLL SYSCFG_CFGR2_CLL_Msk /*!< Core Lockup Lock */
#define SYSCFG_CFGR2_SPL_Pos (1U)
#define SYSCFG_CFGR2_SPL_Msk (0x1UL << SYSCFG_CFGR2_SPL_Pos) /*!< 0x00000002 */
#define SYSCFG_CFGR2_SPL SYSCFG_CFGR2_SPL_Msk /*!< SRAM Parity Lock*/
#define SYSCFG_CFGR2_PVDL_Pos (2U)
#define SYSCFG_CFGR2_PVDL_Msk (0x1UL << SYSCFG_CFGR2_PVDL_Pos) /*!< 0x00000004 */
#define SYSCFG_CFGR2_PVDL SYSCFG_CFGR2_PVDL_Msk /*!< PVD Lock */
#define SYSCFG_CFGR2_ECCL_Pos (3U)
#define SYSCFG_CFGR2_ECCL_Msk (0x1UL << SYSCFG_CFGR2_ECCL_Pos) /*!< 0x00000008 */
#define SYSCFG_CFGR2_ECCL SYSCFG_CFGR2_ECCL_Msk /*!< ECC Lock*/
#define SYSCFG_CFGR2_SPF_Pos (8U)
#define SYSCFG_CFGR2_SPF_Msk (0x1UL << SYSCFG_CFGR2_SPF_Pos) /*!< 0x00000100 */
#define SYSCFG_CFGR2_SPF SYSCFG_CFGR2_SPF_Msk /*!< SRAM Parity Flag */
/****************** Bit definition for SYSCFG_SWPR register ****************/
#define SYSCFG_SWPR_PAGE0_Pos (0U)
#define SYSCFG_SWPR_PAGE0_Msk (0x1UL << SYSCFG_SWPR_PAGE0_Pos) /*!< 0x00000001 */
#define SYSCFG_SWPR_PAGE0 (SYSCFG_SWPR_PAGE0_Msk) /*!< CCMSRAM Write protection page 0 */
#define SYSCFG_SWPR_PAGE1_Pos (1U)
#define SYSCFG_SWPR_PAGE1_Msk (0x1UL << SYSCFG_SWPR_PAGE1_Pos) /*!< 0x00000002 */
#define SYSCFG_SWPR_PAGE1 (SYSCFG_SWPR_PAGE1_Msk) /*!< CCMSRAM Write protection page 1 */
#define SYSCFG_SWPR_PAGE2_Pos (2U)
#define SYSCFG_SWPR_PAGE2_Msk (0x1UL << SYSCFG_SWPR_PAGE2_Pos) /*!< 0x00000004 */
#define SYSCFG_SWPR_PAGE2 (SYSCFG_SWPR_PAGE2_Msk) /*!< CCMSRAM Write protection page 2 */
#define SYSCFG_SWPR_PAGE3_Pos (3U)
#define SYSCFG_SWPR_PAGE3_Msk (0x1UL << SYSCFG_SWPR_PAGE3_Pos) /*!< 0x00000008 */
#define SYSCFG_SWPR_PAGE3 (SYSCFG_SWPR_PAGE3_Msk) /*!< CCMSRAM Write protection page 3 */
#define SYSCFG_SWPR_PAGE4_Pos (4U)
#define SYSCFG_SWPR_PAGE4_Msk (0x1UL << SYSCFG_SWPR_PAGE4_Pos) /*!< 0x00000010 */
#define SYSCFG_SWPR_PAGE4 (SYSCFG_SWPR_PAGE4_Msk) /*!< CCMSRAM Write protection page 4 */
#define SYSCFG_SWPR_PAGE5_Pos (5U)
#define SYSCFG_SWPR_PAGE5_Msk (0x1UL << SYSCFG_SWPR_PAGE5_Pos) /*!< 0x00000020 */
#define SYSCFG_SWPR_PAGE5 (SYSCFG_SWPR_PAGE5_Msk) /*!< CCMSRAM Write protection page 5 */
#define SYSCFG_SWPR_PAGE6_Pos (6U)
#define SYSCFG_SWPR_PAGE6_Msk (0x1UL << SYSCFG_SWPR_PAGE6_Pos) /*!< 0x00000040 */
#define SYSCFG_SWPR_PAGE6 (SYSCFG_SWPR_PAGE6_Msk) /*!< CCMSRAM Write protection page 6 */
#define SYSCFG_SWPR_PAGE7_Pos (7U)
#define SYSCFG_SWPR_PAGE7_Msk (0x1UL << SYSCFG_SWPR_PAGE7_Pos) /*!< 0x00000080 */
#define SYSCFG_SWPR_PAGE7 (SYSCFG_SWPR_PAGE7_Msk) /*!< CCMSRAM Write protection page 7 */
#define SYSCFG_SWPR_PAGE8_Pos (8U)
#define SYSCFG_SWPR_PAGE8_Msk (0x1UL << SYSCFG_SWPR_PAGE8_Pos) /*!< 0x00000100 */
#define SYSCFG_SWPR_PAGE8 (SYSCFG_SWPR_PAGE8_Msk) /*!< CCMSRAM Write protection page 8 */
#define SYSCFG_SWPR_PAGE9_Pos (9U)
#define SYSCFG_SWPR_PAGE9_Msk (0x1UL << SYSCFG_SWPR_PAGE9_Pos) /*!< 0x00000200 */
#define SYSCFG_SWPR_PAGE9 (SYSCFG_SWPR_PAGE9_Msk) /*!< CCMSRAM Write protection page 9 */
/****************** Bit definition for SYSCFG_SKR register ****************/
#define SYSCFG_SKR_KEY_Pos (0U)
#define SYSCFG_SKR_KEY_Msk (0xFFUL << SYSCFG_SKR_KEY_Pos) /*!< 0x000000FF */
#define SYSCFG_SKR_KEY SYSCFG_SKR_KEY_Msk /*!< CCMSRAM write protection key for software erase */
/******************************************************************************/
/* */
/* TIM */
/* */
/******************************************************************************/
/******************* Bit definition for TIM_CR1 register ********************/
#define TIM_CR1_CEN_Pos (0U)
#define TIM_CR1_CEN_Msk (0x1UL << TIM_CR1_CEN_Pos) /*!< 0x00000001 */
#define TIM_CR1_CEN TIM_CR1_CEN_Msk /*!<Counter enable */
#define TIM_CR1_UDIS_Pos (1U)
#define TIM_CR1_UDIS_Msk (0x1UL << TIM_CR1_UDIS_Pos) /*!< 0x00000002 */
#define TIM_CR1_UDIS TIM_CR1_UDIS_Msk /*!<Update disable */
#define TIM_CR1_URS_Pos (2U)
#define TIM_CR1_URS_Msk (0x1UL << TIM_CR1_URS_Pos) /*!< 0x00000004 */
#define TIM_CR1_URS TIM_CR1_URS_Msk /*!<Update request source */
#define TIM_CR1_OPM_Pos (3U)
#define TIM_CR1_OPM_Msk (0x1UL << TIM_CR1_OPM_Pos) /*!< 0x00000008 */
#define TIM_CR1_OPM TIM_CR1_OPM_Msk /*!<One pulse mode */
#define TIM_CR1_DIR_Pos (4U)
#define TIM_CR1_DIR_Msk (0x1UL << TIM_CR1_DIR_Pos) /*!< 0x00000010 */
#define TIM_CR1_DIR TIM_CR1_DIR_Msk /*!<Direction */
#define TIM_CR1_CMS_Pos (5U)
#define TIM_CR1_CMS_Msk (0x3UL << TIM_CR1_CMS_Pos) /*!< 0x00000060 */
#define TIM_CR1_CMS TIM_CR1_CMS_Msk /*!<CMS[1:0] bits (Center-aligned mode selection) */
#define TIM_CR1_CMS_0 (0x1UL << TIM_CR1_CMS_Pos) /*!< 0x00000020 */
#define TIM_CR1_CMS_1 (0x2UL << TIM_CR1_CMS_Pos) /*!< 0x00000040 */
#define TIM_CR1_ARPE_Pos (7U)
#define TIM_CR1_ARPE_Msk (0x1UL << TIM_CR1_ARPE_Pos) /*!< 0x00000080 */
#define TIM_CR1_ARPE TIM_CR1_ARPE_Msk /*!<Auto-reload preload enable */
#define TIM_CR1_CKD_Pos (8U)
#define TIM_CR1_CKD_Msk (0x3UL << TIM_CR1_CKD_Pos) /*!< 0x00000300 */
#define TIM_CR1_CKD TIM_CR1_CKD_Msk /*!<CKD[1:0] bits (clock division) */
#define TIM_CR1_CKD_0 (0x1UL << TIM_CR1_CKD_Pos) /*!< 0x00000100 */
#define TIM_CR1_CKD_1 (0x2UL << TIM_CR1_CKD_Pos) /*!< 0x00000200 */
#define TIM_CR1_UIFREMAP_Pos (11U)
#define TIM_CR1_UIFREMAP_Msk (0x1UL << TIM_CR1_UIFREMAP_Pos) /*!< 0x00000800 */
#define TIM_CR1_UIFREMAP TIM_CR1_UIFREMAP_Msk /*!<Update interrupt flag remap */
#define TIM_CR1_DITHEN_Pos (12U)
#define TIM_CR1_DITHEN_Msk (0x1UL << TIM_CR1_DITHEN_Pos) /*!< 0x00001000 */
#define TIM_CR1_DITHEN TIM_CR1_DITHEN_Msk /*!<Dithering enable */
/******************* Bit definition for TIM_CR2 register ********************/
#define TIM_CR2_CCPC_Pos (0U)
#define TIM_CR2_CCPC_Msk (0x1UL << TIM_CR2_CCPC_Pos) /*!< 0x00000001 */
#define TIM_CR2_CCPC TIM_CR2_CCPC_Msk /*!<Capture/Compare Preloaded Control */
#define TIM_CR2_CCUS_Pos (2U)
#define TIM_CR2_CCUS_Msk (0x1UL << TIM_CR2_CCUS_Pos) /*!< 0x00000004 */
#define TIM_CR2_CCUS TIM_CR2_CCUS_Msk /*!<Capture/Compare Control Update Selection */
#define TIM_CR2_CCDS_Pos (3U)
#define TIM_CR2_CCDS_Msk (0x1UL << TIM_CR2_CCDS_Pos) /*!< 0x00000008 */
#define TIM_CR2_CCDS TIM_CR2_CCDS_Msk /*!<Capture/Compare DMA Selection */
#define TIM_CR2_MMS_Pos (4U)
#define TIM_CR2_MMS_Msk (0x200007UL << TIM_CR2_MMS_Pos) /*!< 0x02000070 */
#define TIM_CR2_MMS TIM_CR2_MMS_Msk /*!<MMS[3:0] bits (Master Mode Selection) */
#define TIM_CR2_MMS_0 (0x000001UL << TIM_CR2_MMS_Pos) /*!< 0x00000010 */
#define TIM_CR2_MMS_1 (0x000002UL << TIM_CR2_MMS_Pos) /*!< 0x00000020 */
#define TIM_CR2_MMS_2 (0x000004UL << TIM_CR2_MMS_Pos) /*!< 0x00000040 */
#define TIM_CR2_MMS_3 (0x200000UL << TIM_CR2_MMS_Pos) /*!< 0x02000000 */
#define TIM_CR2_TI1S_Pos (7U)
#define TIM_CR2_TI1S_Msk (0x1UL << TIM_CR2_TI1S_Pos) /*!< 0x00000080 */
#define TIM_CR2_TI1S TIM_CR2_TI1S_Msk /*!<TI1 Selection */
#define TIM_CR2_OIS1_Pos (8U)
#define TIM_CR2_OIS1_Msk (0x1UL << TIM_CR2_OIS1_Pos) /*!< 0x00000100 */
#define TIM_CR2_OIS1 TIM_CR2_OIS1_Msk /*!<Output Idle state 1 (OC1 output) */
#define TIM_CR2_OIS1N_Pos (9U)
#define TIM_CR2_OIS1N_Msk (0x1UL << TIM_CR2_OIS1N_Pos) /*!< 0x00000200 */
#define TIM_CR2_OIS1N TIM_CR2_OIS1N_Msk /*!<Output Idle state 1 (OC1N output) */
#define TIM_CR2_OIS2_Pos (10U)
#define TIM_CR2_OIS2_Msk (0x1UL << TIM_CR2_OIS2_Pos) /*!< 0x00000400 */
#define TIM_CR2_OIS2 TIM_CR2_OIS2_Msk /*!<Output Idle state 2 (OC2 output) */
#define TIM_CR2_OIS2N_Pos (11U)
#define TIM_CR2_OIS2N_Msk (0x1UL << TIM_CR2_OIS2N_Pos) /*!< 0x00000800 */
#define TIM_CR2_OIS2N TIM_CR2_OIS2N_Msk /*!<Output Idle state 2 (OC2N output) */
#define TIM_CR2_OIS3_Pos (12U)
#define TIM_CR2_OIS3_Msk (0x1UL << TIM_CR2_OIS3_Pos) /*!< 0x00001000 */
#define TIM_CR2_OIS3 TIM_CR2_OIS3_Msk /*!<Output Idle state 3 (OC3 output) */
#define TIM_CR2_OIS3N_Pos (13U)
#define TIM_CR2_OIS3N_Msk (0x1UL << TIM_CR2_OIS3N_Pos) /*!< 0x00002000 */
#define TIM_CR2_OIS3N TIM_CR2_OIS3N_Msk /*!<Output Idle state 3 (OC3N output) */
#define TIM_CR2_OIS4_Pos (14U)
#define TIM_CR2_OIS4_Msk (0x1UL << TIM_CR2_OIS4_Pos) /*!< 0x00004000 */
#define TIM_CR2_OIS4 TIM_CR2_OIS4_Msk /*!<Output Idle state 4 (OC4 output) */
#define TIM_CR2_OIS4N_Pos (15U)
#define TIM_CR2_OIS4N_Msk (0x1UL << TIM_CR2_OIS4N_Pos) /*!< 0x00008000 */
#define TIM_CR2_OIS4N TIM_CR2_OIS4N_Msk /*!<Output Idle state 4 (OC4N output) */
#define TIM_CR2_OIS5_Pos (16U)
#define TIM_CR2_OIS5_Msk (0x1UL << TIM_CR2_OIS5_Pos) /*!< 0x00010000 */
#define TIM_CR2_OIS5 TIM_CR2_OIS5_Msk /*!<Output Idle state 5 (OC5 output) */
#define TIM_CR2_OIS6_Pos (18U)
#define TIM_CR2_OIS6_Msk (0x1UL << TIM_CR2_OIS6_Pos) /*!< 0x00040000 */
#define TIM_CR2_OIS6 TIM_CR2_OIS6_Msk /*!<Output Idle state 6 (OC6 output) */
#define TIM_CR2_MMS2_Pos (20U)
#define TIM_CR2_MMS2_Msk (0xFUL << TIM_CR2_MMS2_Pos) /*!< 0x00F00000 */
#define TIM_CR2_MMS2 TIM_CR2_MMS2_Msk /*!<MMS[2:0] bits (Master Mode Selection) */
#define TIM_CR2_MMS2_0 (0x1UL << TIM_CR2_MMS2_Pos) /*!< 0x00100000 */
#define TIM_CR2_MMS2_1 (0x2UL << TIM_CR2_MMS2_Pos) /*!< 0x00200000 */
#define TIM_CR2_MMS2_2 (0x4UL << TIM_CR2_MMS2_Pos) /*!< 0x00400000 */
#define TIM_CR2_MMS2_3 (0x8UL << TIM_CR2_MMS2_Pos) /*!< 0x00800000 */
/******************* Bit definition for TIM_SMCR register *******************/
#define TIM_SMCR_SMS_Pos (0U)
#define TIM_SMCR_SMS_Msk (0x10007UL << TIM_SMCR_SMS_Pos) /*!< 0x00010007 */
#define TIM_SMCR_SMS TIM_SMCR_SMS_Msk /*!<SMS[2:0] bits (Slave mode selection) */
#define TIM_SMCR_SMS_0 (0x00001UL << TIM_SMCR_SMS_Pos) /*!< 0x00000001 */
#define TIM_SMCR_SMS_1 (0x00002UL << TIM_SMCR_SMS_Pos) /*!< 0x00000002 */
#define TIM_SMCR_SMS_2 (0x00004UL << TIM_SMCR_SMS_Pos) /*!< 0x00000004 */
#define TIM_SMCR_SMS_3 (0x10000UL << TIM_SMCR_SMS_Pos) /*!< 0x00010000 */
#define TIM_SMCR_OCCS_Pos (3U)
#define TIM_SMCR_OCCS_Msk (0x1UL << TIM_SMCR_OCCS_Pos) /*!< 0x00000008 */
#define TIM_SMCR_OCCS TIM_SMCR_OCCS_Msk /*!< OCREF clear selection */
#define TIM_SMCR_TS_Pos (4U)
#define TIM_SMCR_TS_Msk (0x30007UL << TIM_SMCR_TS_Pos) /*!< 0x00300070 */
#define TIM_SMCR_TS TIM_SMCR_TS_Msk /*!<TS[2:0] bits (Trigger selection) */
#define TIM_SMCR_TS_0 (0x00001UL << TIM_SMCR_TS_Pos) /*!< 0x00000010 */
#define TIM_SMCR_TS_1 (0x00002UL << TIM_SMCR_TS_Pos) /*!< 0x00000020 */
#define TIM_SMCR_TS_2 (0x00004UL << TIM_SMCR_TS_Pos) /*!< 0x00000040 */
#define TIM_SMCR_TS_3 (0x10000UL << TIM_SMCR_TS_Pos) /*!< 0x00100000 */
#define TIM_SMCR_TS_4 (0x20000UL << TIM_SMCR_TS_Pos) /*!< 0x00200000 */
#define TIM_SMCR_MSM_Pos (7U)
#define TIM_SMCR_MSM_Msk (0x1UL << TIM_SMCR_MSM_Pos) /*!< 0x00000080 */
#define TIM_SMCR_MSM TIM_SMCR_MSM_Msk /*!<Master/slave mode */
#define TIM_SMCR_ETF_Pos (8U)
#define TIM_SMCR_ETF_Msk (0xFUL << TIM_SMCR_ETF_Pos) /*!< 0x00000F00 */
#define TIM_SMCR_ETF TIM_SMCR_ETF_Msk /*!<ETF[3:0] bits (External trigger filter) */
#define TIM_SMCR_ETF_0 (0x1UL << TIM_SMCR_ETF_Pos) /*!< 0x00000100 */
#define TIM_SMCR_ETF_1 (0x2UL << TIM_SMCR_ETF_Pos) /*!< 0x00000200 */
#define TIM_SMCR_ETF_2 (0x4UL << TIM_SMCR_ETF_Pos) /*!< 0x00000400 */
#define TIM_SMCR_ETF_3 (0x8UL << TIM_SMCR_ETF_Pos) /*!< 0x00000800 */
#define TIM_SMCR_ETPS_Pos (12U)
#define TIM_SMCR_ETPS_Msk (0x3UL << TIM_SMCR_ETPS_Pos) /*!< 0x00003000 */
#define TIM_SMCR_ETPS TIM_SMCR_ETPS_Msk /*!<ETPS[1:0] bits (External trigger prescaler) */
#define TIM_SMCR_ETPS_0 (0x1UL << TIM_SMCR_ETPS_Pos) /*!< 0x00001000 */
#define TIM_SMCR_ETPS_1 (0x2UL << TIM_SMCR_ETPS_Pos) /*!< 0x00002000 */
#define TIM_SMCR_ECE_Pos (14U)
#define TIM_SMCR_ECE_Msk (0x1UL << TIM_SMCR_ECE_Pos) /*!< 0x00004000 */
#define TIM_SMCR_ECE TIM_SMCR_ECE_Msk /*!<External clock enable */
#define TIM_SMCR_ETP_Pos (15U)
#define TIM_SMCR_ETP_Msk (0x1UL << TIM_SMCR_ETP_Pos) /*!< 0x00008000 */
#define TIM_SMCR_ETP TIM_SMCR_ETP_Msk /*!<External trigger polarity */
#define TIM_SMCR_SMSPE_Pos (24U)
#define TIM_SMCR_SMSPE_Msk (0x1UL << TIM_SMCR_SMSPE_Pos) /*!< 0x02000000 */
#define TIM_SMCR_SMSPE TIM_SMCR_SMSPE_Msk /*!<SMS preload enable */
#define TIM_SMCR_SMSPS_Pos (25U)
#define TIM_SMCR_SMSPS_Msk (0x1UL << TIM_SMCR_SMSPS_Pos) /*!< 0x04000000 */
#define TIM_SMCR_SMSPS TIM_SMCR_SMSPS_Msk /*!<SMS preload source */
/******************* Bit definition for TIM_DIER register *******************/
#define TIM_DIER_UIE_Pos (0U)
#define TIM_DIER_UIE_Msk (0x1UL << TIM_DIER_UIE_Pos) /*!< 0x00000001 */
#define TIM_DIER_UIE TIM_DIER_UIE_Msk /*!<Update interrupt enable */
#define TIM_DIER_CC1IE_Pos (1U)
#define TIM_DIER_CC1IE_Msk (0x1UL << TIM_DIER_CC1IE_Pos) /*!< 0x00000002 */
#define TIM_DIER_CC1IE TIM_DIER_CC1IE_Msk /*!<Capture/Compare 1 interrupt enable */
#define TIM_DIER_CC2IE_Pos (2U)
#define TIM_DIER_CC2IE_Msk (0x1UL << TIM_DIER_CC2IE_Pos) /*!< 0x00000004 */
#define TIM_DIER_CC2IE TIM_DIER_CC2IE_Msk /*!<Capture/Compare 2 interrupt enable */
#define TIM_DIER_CC3IE_Pos (3U)
#define TIM_DIER_CC3IE_Msk (0x1UL << TIM_DIER_CC3IE_Pos) /*!< 0x00000008 */
#define TIM_DIER_CC3IE TIM_DIER_CC3IE_Msk /*!<Capture/Compare 3 interrupt enable */
#define TIM_DIER_CC4IE_Pos (4U)
#define TIM_DIER_CC4IE_Msk (0x1UL << TIM_DIER_CC4IE_Pos) /*!< 0x00000010 */
#define TIM_DIER_CC4IE TIM_DIER_CC4IE_Msk /*!<Capture/Compare 4 interrupt enable */
#define TIM_DIER_COMIE_Pos (5U)
#define TIM_DIER_COMIE_Msk (0x1UL << TIM_DIER_COMIE_Pos) /*!< 0x00000020 */
#define TIM_DIER_COMIE TIM_DIER_COMIE_Msk /*!<COM interrupt enable */
#define TIM_DIER_TIE_Pos (6U)
#define TIM_DIER_TIE_Msk (0x1UL << TIM_DIER_TIE_Pos) /*!< 0x00000040 */
#define TIM_DIER_TIE TIM_DIER_TIE_Msk /*!<Trigger interrupt enable */
#define TIM_DIER_BIE_Pos (7U)
#define TIM_DIER_BIE_Msk (0x1UL << TIM_DIER_BIE_Pos) /*!< 0x00000080 */
#define TIM_DIER_BIE TIM_DIER_BIE_Msk /*!<Break interrupt enable */
#define TIM_DIER_UDE_Pos (8U)
#define TIM_DIER_UDE_Msk (0x1UL << TIM_DIER_UDE_Pos) /*!< 0x00000100 */
#define TIM_DIER_UDE TIM_DIER_UDE_Msk /*!<Update DMA request enable */
#define TIM_DIER_CC1DE_Pos (9U)
#define TIM_DIER_CC1DE_Msk (0x1UL << TIM_DIER_CC1DE_Pos) /*!< 0x00000200 */
#define TIM_DIER_CC1DE TIM_DIER_CC1DE_Msk /*!<Capture/Compare 1 DMA request enable */
#define TIM_DIER_CC2DE_Pos (10U)
#define TIM_DIER_CC2DE_Msk (0x1UL << TIM_DIER_CC2DE_Pos) /*!< 0x00000400 */
#define TIM_DIER_CC2DE TIM_DIER_CC2DE_Msk /*!<Capture/Compare 2 DMA request enable */
#define TIM_DIER_CC3DE_Pos (11U)
#define TIM_DIER_CC3DE_Msk (0x1UL << TIM_DIER_CC3DE_Pos) /*!< 0x00000800 */
#define TIM_DIER_CC3DE TIM_DIER_CC3DE_Msk /*!<Capture/Compare 3 DMA request enable */
#define TIM_DIER_CC4DE_Pos (12U)
#define TIM_DIER_CC4DE_Msk (0x1UL << TIM_DIER_CC4DE_Pos) /*!< 0x00001000 */
#define TIM_DIER_CC4DE TIM_DIER_CC4DE_Msk /*!<Capture/Compare 4 DMA request enable */
#define TIM_DIER_COMDE_Pos (13U)
#define TIM_DIER_COMDE_Msk (0x1UL << TIM_DIER_COMDE_Pos) /*!< 0x00002000 */
#define TIM_DIER_COMDE TIM_DIER_COMDE_Msk /*!<COM DMA request enable */
#define TIM_DIER_TDE_Pos (14U)
#define TIM_DIER_TDE_Msk (0x1UL << TIM_DIER_TDE_Pos) /*!< 0x00004000 */
#define TIM_DIER_TDE TIM_DIER_TDE_Msk /*!<Trigger DMA request enable */
#define TIM_DIER_IDXIE_Pos (20U)
#define TIM_DIER_IDXIE_Msk (0x1UL << TIM_DIER_IDXIE_Pos) /*!< 0x00100000 */
#define TIM_DIER_IDXIE TIM_DIER_IDXIE_Msk /*!<Encoder index interrupt enable */
#define TIM_DIER_DIRIE_Pos (21U)
#define TIM_DIER_DIRIE_Msk (0x1UL << TIM_DIER_DIRIE_Pos) /*!< 0x00200000 */
#define TIM_DIER_DIRIE TIM_DIER_DIRIE_Msk /*!<Encoder direction change interrupt enable */
#define TIM_DIER_IERRIE_Pos (22U)
#define TIM_DIER_IERRIE_Msk (0x1UL << TIM_DIER_IERRIE_Pos) /*!< 0x00400000 */
#define TIM_DIER_IERRIE TIM_DIER_IERRIE_Msk /*!<Encoder index error enable */
#define TIM_DIER_TERRIE_Pos (23U)
#define TIM_DIER_TERRIE_Msk (0x1UL << TIM_DIER_TERRIE_Pos) /*!< 0x00800000 */
#define TIM_DIER_TERRIE TIM_DIER_TERRIE_Msk /*!<Encoder transition error enable */
/******************** Bit definition for TIM_SR register ********************/
#define TIM_SR_UIF_Pos (0U)
#define TIM_SR_UIF_Msk (0x1UL << TIM_SR_UIF_Pos) /*!< 0x00000001 */
#define TIM_SR_UIF TIM_SR_UIF_Msk /*!<Update interrupt Flag */
#define TIM_SR_CC1IF_Pos (1U)
#define TIM_SR_CC1IF_Msk (0x1UL << TIM_SR_CC1IF_Pos) /*!< 0x00000002 */
#define TIM_SR_CC1IF TIM_SR_CC1IF_Msk /*!<Capture/Compare 1 interrupt Flag */
#define TIM_SR_CC2IF_Pos (2U)
#define TIM_SR_CC2IF_Msk (0x1UL << TIM_SR_CC2IF_Pos) /*!< 0x00000004 */
#define TIM_SR_CC2IF TIM_SR_CC2IF_Msk /*!<Capture/Compare 2 interrupt Flag */
#define TIM_SR_CC3IF_Pos (3U)
#define TIM_SR_CC3IF_Msk (0x1UL << TIM_SR_CC3IF_Pos) /*!< 0x00000008 */
#define TIM_SR_CC3IF TIM_SR_CC3IF_Msk /*!<Capture/Compare 3 interrupt Flag */
#define TIM_SR_CC4IF_Pos (4U)
#define TIM_SR_CC4IF_Msk (0x1UL << TIM_SR_CC4IF_Pos) /*!< 0x00000010 */
#define TIM_SR_CC4IF TIM_SR_CC4IF_Msk /*!<Capture/Compare 4 interrupt Flag */
#define TIM_SR_COMIF_Pos (5U)
#define TIM_SR_COMIF_Msk (0x1UL << TIM_SR_COMIF_Pos) /*!< 0x00000020 */
#define TIM_SR_COMIF TIM_SR_COMIF_Msk /*!<COM interrupt Flag */
#define TIM_SR_TIF_Pos (6U)
#define TIM_SR_TIF_Msk (0x1UL << TIM_SR_TIF_Pos) /*!< 0x00000040 */
#define TIM_SR_TIF TIM_SR_TIF_Msk /*!<Trigger interrupt Flag */
#define TIM_SR_BIF_Pos (7U)
#define TIM_SR_BIF_Msk (0x1UL << TIM_SR_BIF_Pos) /*!< 0x00000080 */
#define TIM_SR_BIF TIM_SR_BIF_Msk /*!<Break interrupt Flag */
#define TIM_SR_B2IF_Pos (8U)
#define TIM_SR_B2IF_Msk (0x1UL << TIM_SR_B2IF_Pos) /*!< 0x00000100 */
#define TIM_SR_B2IF TIM_SR_B2IF_Msk /*!<Break 2 interrupt Flag */
#define TIM_SR_CC1OF_Pos (9U)
#define TIM_SR_CC1OF_Msk (0x1UL << TIM_SR_CC1OF_Pos) /*!< 0x00000200 */
#define TIM_SR_CC1OF TIM_SR_CC1OF_Msk /*!<Capture/Compare 1 Overcapture Flag */
#define TIM_SR_CC2OF_Pos (10U)
#define TIM_SR_CC2OF_Msk (0x1UL << TIM_SR_CC2OF_Pos) /*!< 0x00000400 */
#define TIM_SR_CC2OF TIM_SR_CC2OF_Msk /*!<Capture/Compare 2 Overcapture Flag */
#define TIM_SR_CC3OF_Pos (11U)
#define TIM_SR_CC3OF_Msk (0x1UL << TIM_SR_CC3OF_Pos) /*!< 0x00000800 */
#define TIM_SR_CC3OF TIM_SR_CC3OF_Msk /*!<Capture/Compare 3 Overcapture Flag */
#define TIM_SR_CC4OF_Pos (12U)
#define TIM_SR_CC4OF_Msk (0x1UL << TIM_SR_CC4OF_Pos) /*!< 0x00001000 */
#define TIM_SR_CC4OF TIM_SR_CC4OF_Msk /*!<Capture/Compare 4 Overcapture Flag */
#define TIM_SR_SBIF_Pos (13U)
#define TIM_SR_SBIF_Msk (0x1UL << TIM_SR_SBIF_Pos) /*!< 0x00002000 */
#define TIM_SR_SBIF TIM_SR_SBIF_Msk /*!<System Break interrupt Flag */
#define TIM_SR_CC5IF_Pos (16U)
#define TIM_SR_CC5IF_Msk (0x1UL << TIM_SR_CC5IF_Pos) /*!< 0x00010000 */
#define TIM_SR_CC5IF TIM_SR_CC5IF_Msk /*!<Capture/Compare 5 interrupt Flag */
#define TIM_SR_CC6IF_Pos (17U)
#define TIM_SR_CC6IF_Msk (0x1UL << TIM_SR_CC6IF_Pos) /*!< 0x00020000 */
#define TIM_SR_CC6IF TIM_SR_CC6IF_Msk /*!<Capture/Compare 6 interrupt Flag */
#define TIM_SR_IDXF_Pos (20U)
#define TIM_SR_IDXF_Msk (0x1UL << TIM_SR_IDXF_Pos) /*!< 0x00100000 */
#define TIM_SR_IDXF TIM_SR_IDXF_Msk /*!<Encoder index interrupt flag */
#define TIM_SR_DIRF_Pos (21U)
#define TIM_SR_DIRF_Msk (0x1UL << TIM_SR_DIRF_Pos) /*!< 0x00200000 */
#define TIM_SR_DIRF TIM_SR_DIRF_Msk /*!<Encoder direction change interrupt flag */
#define TIM_SR_IERRF_Pos (22U)
#define TIM_SR_IERRF_Msk (0x1UL << TIM_SR_IERRF_Pos) /*!< 0x00400000 */
#define TIM_SR_IERRF TIM_SR_IERRF_Msk /*!<Encoder index error flag */
#define TIM_SR_TERRF_Pos (23U)
#define TIM_SR_TERRF_Msk (0x1UL << TIM_SR_TERRF_Pos) /*!< 0x00800000 */
#define TIM_SR_TERRF TIM_SR_TERRF_Msk /*!<Encoder transition error flag */
/******************* Bit definition for TIM_EGR register ********************/
#define TIM_EGR_UG_Pos (0U)
#define TIM_EGR_UG_Msk (0x1UL << TIM_EGR_UG_Pos) /*!< 0x00000001 */
#define TIM_EGR_UG TIM_EGR_UG_Msk /*!<Update Generation */
#define TIM_EGR_CC1G_Pos (1U)
#define TIM_EGR_CC1G_Msk (0x1UL << TIM_EGR_CC1G_Pos) /*!< 0x00000002 */
#define TIM_EGR_CC1G TIM_EGR_CC1G_Msk /*!<Capture/Compare 1 Generation */
#define TIM_EGR_CC2G_Pos (2U)
#define TIM_EGR_CC2G_Msk (0x1UL << TIM_EGR_CC2G_Pos) /*!< 0x00000004 */
#define TIM_EGR_CC2G TIM_EGR_CC2G_Msk /*!<Capture/Compare 2 Generation */
#define TIM_EGR_CC3G_Pos (3U)
#define TIM_EGR_CC3G_Msk (0x1UL << TIM_EGR_CC3G_Pos) /*!< 0x00000008 */
#define TIM_EGR_CC3G TIM_EGR_CC3G_Msk /*!<Capture/Compare 3 Generation */
#define TIM_EGR_CC4G_Pos (4U)
#define TIM_EGR_CC4G_Msk (0x1UL << TIM_EGR_CC4G_Pos) /*!< 0x00000010 */
#define TIM_EGR_CC4G TIM_EGR_CC4G_Msk /*!<Capture/Compare 4 Generation */
#define TIM_EGR_COMG_Pos (5U)
#define TIM_EGR_COMG_Msk (0x1UL << TIM_EGR_COMG_Pos) /*!< 0x00000020 */
#define TIM_EGR_COMG TIM_EGR_COMG_Msk /*!<Capture/Compare Control Update Generation */
#define TIM_EGR_TG_Pos (6U)
#define TIM_EGR_TG_Msk (0x1UL << TIM_EGR_TG_Pos) /*!< 0x00000040 */
#define TIM_EGR_TG TIM_EGR_TG_Msk /*!<Trigger Generation */
#define TIM_EGR_BG_Pos (7U)
#define TIM_EGR_BG_Msk (0x1UL << TIM_EGR_BG_Pos) /*!< 0x00000080 */
#define TIM_EGR_BG TIM_EGR_BG_Msk /*!<Break Generation */
#define TIM_EGR_B2G_Pos (8U)
#define TIM_EGR_B2G_Msk (0x1UL << TIM_EGR_B2G_Pos) /*!< 0x00000100 */
#define TIM_EGR_B2G TIM_EGR_B2G_Msk /*!<Break 2 Generation */
/****************** Bit definition for TIM_CCMR1 register *******************/
#define TIM_CCMR1_CC1S_Pos (0U)
#define TIM_CCMR1_CC1S_Msk (0x3UL << TIM_CCMR1_CC1S_Pos) /*!< 0x00000003 */
#define TIM_CCMR1_CC1S TIM_CCMR1_CC1S_Msk /*!<CC1S[1:0] bits (Capture/Compare 1 Selection) */
#define TIM_CCMR1_CC1S_0 (0x1UL << TIM_CCMR1_CC1S_Pos) /*!< 0x00000001 */
#define TIM_CCMR1_CC1S_1 (0x2UL << TIM_CCMR1_CC1S_Pos) /*!< 0x00000002 */
#define TIM_CCMR1_OC1FE_Pos (2U)
#define TIM_CCMR1_OC1FE_Msk (0x1UL << TIM_CCMR1_OC1FE_Pos) /*!< 0x00000004 */
#define TIM_CCMR1_OC1FE TIM_CCMR1_OC1FE_Msk /*!<Output Compare 1 Fast enable */
#define TIM_CCMR1_OC1PE_Pos (3U)
#define TIM_CCMR1_OC1PE_Msk (0x1UL << TIM_CCMR1_OC1PE_Pos) /*!< 0x00000008 */
#define TIM_CCMR1_OC1PE TIM_CCMR1_OC1PE_Msk /*!<Output Compare 1 Preload enable */
#define TIM_CCMR1_OC1M_Pos (4U)
#define TIM_CCMR1_OC1M_Msk (0x1007UL << TIM_CCMR1_OC1M_Pos) /*!< 0x00010070 */
#define TIM_CCMR1_OC1M TIM_CCMR1_OC1M_Msk /*!<OC1M[2:0] bits (Output Compare 1 Mode) */
#define TIM_CCMR1_OC1M_0 (0x0001UL << TIM_CCMR1_OC1M_Pos) /*!< 0x00000010 */
#define TIM_CCMR1_OC1M_1 (0x0002UL << TIM_CCMR1_OC1M_Pos) /*!< 0x00000020 */
#define TIM_CCMR1_OC1M_2 (0x0004UL << TIM_CCMR1_OC1M_Pos) /*!< 0x00000040 */
#define TIM_CCMR1_OC1M_3 (0x1000UL << TIM_CCMR1_OC1M_Pos) /*!< 0x00010000 */
#define TIM_CCMR1_OC1CE_Pos (7U)
#define TIM_CCMR1_OC1CE_Msk (0x1UL << TIM_CCMR1_OC1CE_Pos) /*!< 0x00000080 */
#define TIM_CCMR1_OC1CE TIM_CCMR1_OC1CE_Msk /*!<Output Compare 1 Clear Enable */
#define TIM_CCMR1_CC2S_Pos (8U)
#define TIM_CCMR1_CC2S_Msk (0x3UL << TIM_CCMR1_CC2S_Pos) /*!< 0x00000300 */
#define TIM_CCMR1_CC2S TIM_CCMR1_CC2S_Msk /*!<CC2S[1:0] bits (Capture/Compare 2 Selection) */
#define TIM_CCMR1_CC2S_0 (0x1UL << TIM_CCMR1_CC2S_Pos) /*!< 0x00000100 */
#define TIM_CCMR1_CC2S_1 (0x2UL << TIM_CCMR1_CC2S_Pos) /*!< 0x00000200 */
#define TIM_CCMR1_OC2FE_Pos (10U)
#define TIM_CCMR1_OC2FE_Msk (0x1UL << TIM_CCMR1_OC2FE_Pos) /*!< 0x00000400 */
#define TIM_CCMR1_OC2FE TIM_CCMR1_OC2FE_Msk /*!<Output Compare 2 Fast enable */
#define TIM_CCMR1_OC2PE_Pos (11U)
#define TIM_CCMR1_OC2PE_Msk (0x1UL << TIM_CCMR1_OC2PE_Pos) /*!< 0x00000800 */
#define TIM_CCMR1_OC2PE TIM_CCMR1_OC2PE_Msk /*!<Output Compare 2 Preload enable */
#define TIM_CCMR1_OC2M_Pos (12U)
#define TIM_CCMR1_OC2M_Msk (0x1007UL << TIM_CCMR1_OC2M_Pos) /*!< 0x01007000 */
#define TIM_CCMR1_OC2M TIM_CCMR1_OC2M_Msk /*!<OC2M[2:0] bits (Output Compare 2 Mode) */
#define TIM_CCMR1_OC2M_0 (0x0001UL << TIM_CCMR1_OC2M_Pos) /*!< 0x00001000 */
#define TIM_CCMR1_OC2M_1 (0x0002UL << TIM_CCMR1_OC2M_Pos) /*!< 0x00002000 */
#define TIM_CCMR1_OC2M_2 (0x0004UL << TIM_CCMR1_OC2M_Pos) /*!< 0x00004000 */
#define TIM_CCMR1_OC2M_3 (0x1000UL << TIM_CCMR1_OC2M_Pos) /*!< 0x01000000 */
#define TIM_CCMR1_OC2CE_Pos (15U)
#define TIM_CCMR1_OC2CE_Msk (0x1UL << TIM_CCMR1_OC2CE_Pos) /*!< 0x00008000 */
#define TIM_CCMR1_OC2CE TIM_CCMR1_OC2CE_Msk /*!<Output Compare 2 Clear Enable */
/*----------------------------------------------------------------------------*/
#define TIM_CCMR1_IC1PSC_Pos (2U)
#define TIM_CCMR1_IC1PSC_Msk (0x3UL << TIM_CCMR1_IC1PSC_Pos) /*!< 0x0000000C */
#define TIM_CCMR1_IC1PSC TIM_CCMR1_IC1PSC_Msk /*!<IC1PSC[1:0] bits (Input Capture 1 Prescaler) */
#define TIM_CCMR1_IC1PSC_0 (0x1UL << TIM_CCMR1_IC1PSC_Pos) /*!< 0x00000004 */
#define TIM_CCMR1_IC1PSC_1 (0x2UL << TIM_CCMR1_IC1PSC_Pos) /*!< 0x00000008 */
#define TIM_CCMR1_IC1F_Pos (4U)
#define TIM_CCMR1_IC1F_Msk (0xFUL << TIM_CCMR1_IC1F_Pos) /*!< 0x000000F0 */
#define TIM_CCMR1_IC1F TIM_CCMR1_IC1F_Msk /*!<IC1F[3:0] bits (Input Capture 1 Filter) */
#define TIM_CCMR1_IC1F_0 (0x1UL << TIM_CCMR1_IC1F_Pos) /*!< 0x00000010 */
#define TIM_CCMR1_IC1F_1 (0x2UL << TIM_CCMR1_IC1F_Pos) /*!< 0x00000020 */
#define TIM_CCMR1_IC1F_2 (0x4UL << TIM_CCMR1_IC1F_Pos) /*!< 0x00000040 */
#define TIM_CCMR1_IC1F_3 (0x8UL << TIM_CCMR1_IC1F_Pos) /*!< 0x00000080 */
#define TIM_CCMR1_IC2PSC_Pos (10U)
#define TIM_CCMR1_IC2PSC_Msk (0x3UL << TIM_CCMR1_IC2PSC_Pos) /*!< 0x00000C00 */
#define TIM_CCMR1_IC2PSC TIM_CCMR1_IC2PSC_Msk /*!<IC2PSC[1:0] bits (Input Capture 2 Prescaler) */
#define TIM_CCMR1_IC2PSC_0 (0x1UL << TIM_CCMR1_IC2PSC_Pos) /*!< 0x00000400 */
#define TIM_CCMR1_IC2PSC_1 (0x2UL << TIM_CCMR1_IC2PSC_Pos) /*!< 0x00000800 */
#define TIM_CCMR1_IC2F_Pos (12U)
#define TIM_CCMR1_IC2F_Msk (0xFUL << TIM_CCMR1_IC2F_Pos) /*!< 0x0000F000 */
#define TIM_CCMR1_IC2F TIM_CCMR1_IC2F_Msk /*!<IC2F[3:0] bits (Input Capture 2 Filter) */
#define TIM_CCMR1_IC2F_0 (0x1UL << TIM_CCMR1_IC2F_Pos) /*!< 0x00001000 */
#define TIM_CCMR1_IC2F_1 (0x2UL << TIM_CCMR1_IC2F_Pos) /*!< 0x00002000 */
#define TIM_CCMR1_IC2F_2 (0x4UL << TIM_CCMR1_IC2F_Pos) /*!< 0x00004000 */
#define TIM_CCMR1_IC2F_3 (0x8UL << TIM_CCMR1_IC2F_Pos) /*!< 0x00008000 */
/****************** Bit definition for TIM_CCMR2 register *******************/
#define TIM_CCMR2_CC3S_Pos (0U)
#define TIM_CCMR2_CC3S_Msk (0x3UL << TIM_CCMR2_CC3S_Pos) /*!< 0x00000003 */
#define TIM_CCMR2_CC3S TIM_CCMR2_CC3S_Msk /*!<CC3S[1:0] bits (Capture/Compare 3 Selection) */
#define TIM_CCMR2_CC3S_0 (0x1UL << TIM_CCMR2_CC3S_Pos) /*!< 0x00000001 */
#define TIM_CCMR2_CC3S_1 (0x2UL << TIM_CCMR2_CC3S_Pos) /*!< 0x00000002 */
#define TIM_CCMR2_OC3FE_Pos (2U)
#define TIM_CCMR2_OC3FE_Msk (0x1UL << TIM_CCMR2_OC3FE_Pos) /*!< 0x00000004 */
#define TIM_CCMR2_OC3FE TIM_CCMR2_OC3FE_Msk /*!<Output Compare 3 Fast enable */
#define TIM_CCMR2_OC3PE_Pos (3U)
#define TIM_CCMR2_OC3PE_Msk (0x1UL << TIM_CCMR2_OC3PE_Pos) /*!< 0x00000008 */
#define TIM_CCMR2_OC3PE TIM_CCMR2_OC3PE_Msk /*!<Output Compare 3 Preload enable */
#define TIM_CCMR2_OC3M_Pos (4U)
#define TIM_CCMR2_OC3M_Msk (0x1007UL << TIM_CCMR2_OC3M_Pos) /*!< 0x00010070 */
#define TIM_CCMR2_OC3M TIM_CCMR2_OC3M_Msk /*!<OC3M[2:0] bits (Output Compare 3 Mode) */
#define TIM_CCMR2_OC3M_0 (0x0001UL << TIM_CCMR2_OC3M_Pos) /*!< 0x00000010 */
#define TIM_CCMR2_OC3M_1 (0x0002UL << TIM_CCMR2_OC3M_Pos) /*!< 0x00000020 */
#define TIM_CCMR2_OC3M_2 (0x0004UL << TIM_CCMR2_OC3M_Pos) /*!< 0x00000040 */
#define TIM_CCMR2_OC3M_3 (0x1000UL << TIM_CCMR2_OC3M_Pos) /*!< 0x00010000 */
#define TIM_CCMR2_OC3CE_Pos (7U)
#define TIM_CCMR2_OC3CE_Msk (0x1UL << TIM_CCMR2_OC3CE_Pos) /*!< 0x00000080 */
#define TIM_CCMR2_OC3CE TIM_CCMR2_OC3CE_Msk /*!<Output Compare 3 Clear Enable */
#define TIM_CCMR2_CC4S_Pos (8U)
#define TIM_CCMR2_CC4S_Msk (0x3UL << TIM_CCMR2_CC4S_Pos) /*!< 0x00000300 */
#define TIM_CCMR2_CC4S TIM_CCMR2_CC4S_Msk /*!<CC4S[1:0] bits (Capture/Compare 4 Selection) */
#define TIM_CCMR2_CC4S_0 (0x1UL << TIM_CCMR2_CC4S_Pos) /*!< 0x00000100 */
#define TIM_CCMR2_CC4S_1 (0x2UL << TIM_CCMR2_CC4S_Pos) /*!< 0x00000200 */
#define TIM_CCMR2_OC4FE_Pos (10U)
#define TIM_CCMR2_OC4FE_Msk (0x1UL << TIM_CCMR2_OC4FE_Pos) /*!< 0x00000400 */
#define TIM_CCMR2_OC4FE TIM_CCMR2_OC4FE_Msk /*!<Output Compare 4 Fast enable */
#define TIM_CCMR2_OC4PE_Pos (11U)
#define TIM_CCMR2_OC4PE_Msk (0x1UL << TIM_CCMR2_OC4PE_Pos) /*!< 0x00000800 */
#define TIM_CCMR2_OC4PE TIM_CCMR2_OC4PE_Msk /*!<Output Compare 4 Preload enable */
#define TIM_CCMR2_OC4M_Pos (12U)
#define TIM_CCMR2_OC4M_Msk (0x1007UL << TIM_CCMR2_OC4M_Pos) /*!< 0x01007000 */
#define TIM_CCMR2_OC4M TIM_CCMR2_OC4M_Msk /*!<OC4M[2:0] bits (Output Compare 4 Mode) */
#define TIM_CCMR2_OC4M_0 (0x0001UL << TIM_CCMR2_OC4M_Pos) /*!< 0x00001000 */
#define TIM_CCMR2_OC4M_1 (0x0002UL << TIM_CCMR2_OC4M_Pos) /*!< 0x00002000 */
#define TIM_CCMR2_OC4M_2 (0x0004UL << TIM_CCMR2_OC4M_Pos) /*!< 0x00004000 */
#define TIM_CCMR2_OC4M_3 (0x1000UL << TIM_CCMR2_OC4M_Pos) /*!< 0x01000000 */
#define TIM_CCMR2_OC4CE_Pos (15U)
#define TIM_CCMR2_OC4CE_Msk (0x1UL << TIM_CCMR2_OC4CE_Pos) /*!< 0x00008000 */
#define TIM_CCMR2_OC4CE TIM_CCMR2_OC4CE_Msk /*!<Output Compare 4 Clear Enable */
/*----------------------------------------------------------------------------*/
#define TIM_CCMR2_IC3PSC_Pos (2U)
#define TIM_CCMR2_IC3PSC_Msk (0x3UL << TIM_CCMR2_IC3PSC_Pos) /*!< 0x0000000C */
#define TIM_CCMR2_IC3PSC TIM_CCMR2_IC3PSC_Msk /*!<IC3PSC[1:0] bits (Input Capture 3 Prescaler) */
#define TIM_CCMR2_IC3PSC_0 (0x1UL << TIM_CCMR2_IC3PSC_Pos) /*!< 0x00000004 */
#define TIM_CCMR2_IC3PSC_1 (0x2UL << TIM_CCMR2_IC3PSC_Pos) /*!< 0x00000008 */
#define TIM_CCMR2_IC3F_Pos (4U)
#define TIM_CCMR2_IC3F_Msk (0xFUL << TIM_CCMR2_IC3F_Pos) /*!< 0x000000F0 */
#define TIM_CCMR2_IC3F TIM_CCMR2_IC3F_Msk /*!<IC3F[3:0] bits (Input Capture 3 Filter) */
#define TIM_CCMR2_IC3F_0 (0x1UL << TIM_CCMR2_IC3F_Pos) /*!< 0x00000010 */
#define TIM_CCMR2_IC3F_1 (0x2UL << TIM_CCMR2_IC3F_Pos) /*!< 0x00000020 */
#define TIM_CCMR2_IC3F_2 (0x4UL << TIM_CCMR2_IC3F_Pos) /*!< 0x00000040 */
#define TIM_CCMR2_IC3F_3 (0x8UL << TIM_CCMR2_IC3F_Pos) /*!< 0x00000080 */
#define TIM_CCMR2_IC4PSC_Pos (10U)
#define TIM_CCMR2_IC4PSC_Msk (0x3UL << TIM_CCMR2_IC4PSC_Pos) /*!< 0x00000C00 */
#define TIM_CCMR2_IC4PSC TIM_CCMR2_IC4PSC_Msk /*!<IC4PSC[1:0] bits (Input Capture 4 Prescaler) */
#define TIM_CCMR2_IC4PSC_0 (0x1UL << TIM_CCMR2_IC4PSC_Pos) /*!< 0x00000400 */
#define TIM_CCMR2_IC4PSC_1 (0x2UL << TIM_CCMR2_IC4PSC_Pos) /*!< 0x00000800 */
#define TIM_CCMR2_IC4F_Pos (12U)
#define TIM_CCMR2_IC4F_Msk (0xFUL << TIM_CCMR2_IC4F_Pos) /*!< 0x0000F000 */
#define TIM_CCMR2_IC4F TIM_CCMR2_IC4F_Msk /*!<IC4F[3:0] bits (Input Capture 4 Filter) */
#define TIM_CCMR2_IC4F_0 (0x1UL << TIM_CCMR2_IC4F_Pos) /*!< 0x00001000 */
#define TIM_CCMR2_IC4F_1 (0x2UL << TIM_CCMR2_IC4F_Pos) /*!< 0x00002000 */
#define TIM_CCMR2_IC4F_2 (0x4UL << TIM_CCMR2_IC4F_Pos) /*!< 0x00004000 */
#define TIM_CCMR2_IC4F_3 (0x8UL << TIM_CCMR2_IC4F_Pos) /*!< 0x00008000 */
/****************** Bit definition for TIM_CCMR3 register *******************/
#define TIM_CCMR3_OC5FE_Pos (2U)
#define TIM_CCMR3_OC5FE_Msk (0x1UL << TIM_CCMR3_OC5FE_Pos) /*!< 0x00000004 */
#define TIM_CCMR3_OC5FE TIM_CCMR3_OC5FE_Msk /*!<Output Compare 5 Fast enable */
#define TIM_CCMR3_OC5PE_Pos (3U)
#define TIM_CCMR3_OC5PE_Msk (0x1UL << TIM_CCMR3_OC5PE_Pos) /*!< 0x00000008 */
#define TIM_CCMR3_OC5PE TIM_CCMR3_OC5PE_Msk /*!<Output Compare 5 Preload enable */
#define TIM_CCMR3_OC5M_Pos (4U)
#define TIM_CCMR3_OC5M_Msk (0x1007UL << TIM_CCMR3_OC5M_Pos) /*!< 0x00010070 */
#define TIM_CCMR3_OC5M TIM_CCMR3_OC5M_Msk /*!<OC5M[3:0] bits (Output Compare 5 Mode) */
#define TIM_CCMR3_OC5M_0 (0x0001UL << TIM_CCMR3_OC5M_Pos) /*!< 0x00000010 */
#define TIM_CCMR3_OC5M_1 (0x0002UL << TIM_CCMR3_OC5M_Pos) /*!< 0x00000020 */
#define TIM_CCMR3_OC5M_2 (0x0004UL << TIM_CCMR3_OC5M_Pos) /*!< 0x00000040 */
#define TIM_CCMR3_OC5M_3 (0x1000UL << TIM_CCMR3_OC5M_Pos) /*!< 0x00010000 */
#define TIM_CCMR3_OC5CE_Pos (7U)
#define TIM_CCMR3_OC5CE_Msk (0x1UL << TIM_CCMR3_OC5CE_Pos) /*!< 0x00000080 */
#define TIM_CCMR3_OC5CE TIM_CCMR3_OC5CE_Msk /*!<Output Compare 5 Clear Enable */
#define TIM_CCMR3_OC6FE_Pos (10U)
#define TIM_CCMR3_OC6FE_Msk (0x1UL << TIM_CCMR3_OC6FE_Pos) /*!< 0x00000400 */
#define TIM_CCMR3_OC6FE TIM_CCMR3_OC6FE_Msk /*!<Output Compare 6 Fast enable */
#define TIM_CCMR3_OC6PE_Pos (11U)
#define TIM_CCMR3_OC6PE_Msk (0x1UL << TIM_CCMR3_OC6PE_Pos) /*!< 0x00000800 */
#define TIM_CCMR3_OC6PE TIM_CCMR3_OC6PE_Msk /*!<Output Compare 6 Preload enable */
#define TIM_CCMR3_OC6M_Pos (12U)
#define TIM_CCMR3_OC6M_Msk (0x1007UL << TIM_CCMR3_OC6M_Pos) /*!< 0x01007000 */
#define TIM_CCMR3_OC6M TIM_CCMR3_OC6M_Msk /*!<OC6M[3:0] bits (Output Compare 6 Mode) */
#define TIM_CCMR3_OC6M_0 (0x0001UL << TIM_CCMR3_OC6M_Pos) /*!< 0x00001000 */
#define TIM_CCMR3_OC6M_1 (0x0002UL << TIM_CCMR3_OC6M_Pos) /*!< 0x00002000 */
#define TIM_CCMR3_OC6M_2 (0x0004UL << TIM_CCMR3_OC6M_Pos) /*!< 0x00004000 */
#define TIM_CCMR3_OC6M_3 (0x1000UL << TIM_CCMR3_OC6M_Pos) /*!< 0x01000000 */
#define TIM_CCMR3_OC6CE_Pos (15U)
#define TIM_CCMR3_OC6CE_Msk (0x1UL << TIM_CCMR3_OC6CE_Pos) /*!< 0x00008000 */
#define TIM_CCMR3_OC6CE TIM_CCMR3_OC6CE_Msk /*!<Output Compare 6 Clear Enable */
/******************* Bit definition for TIM_CCER register *******************/
#define TIM_CCER_CC1E_Pos (0U)
#define TIM_CCER_CC1E_Msk (0x1UL << TIM_CCER_CC1E_Pos) /*!< 0x00000001 */
#define TIM_CCER_CC1E TIM_CCER_CC1E_Msk /*!<Capture/Compare 1 output enable */
#define TIM_CCER_CC1P_Pos (1U)
#define TIM_CCER_CC1P_Msk (0x1UL << TIM_CCER_CC1P_Pos) /*!< 0x00000002 */
#define TIM_CCER_CC1P TIM_CCER_CC1P_Msk /*!<Capture/Compare 1 output Polarity */
#define TIM_CCER_CC1NE_Pos (2U)
#define TIM_CCER_CC1NE_Msk (0x1UL << TIM_CCER_CC1NE_Pos) /*!< 0x00000004 */
#define TIM_CCER_CC1NE TIM_CCER_CC1NE_Msk /*!<Capture/Compare 1 Complementary output enable */
#define TIM_CCER_CC1NP_Pos (3U)
#define TIM_CCER_CC1NP_Msk (0x1UL << TIM_CCER_CC1NP_Pos) /*!< 0x00000008 */
#define TIM_CCER_CC1NP TIM_CCER_CC1NP_Msk /*!<Capture/Compare 1 Complementary output Polarity */
#define TIM_CCER_CC2E_Pos (4U)
#define TIM_CCER_CC2E_Msk (0x1UL << TIM_CCER_CC2E_Pos) /*!< 0x00000010 */
#define TIM_CCER_CC2E TIM_CCER_CC2E_Msk /*!<Capture/Compare 2 output enable */
#define TIM_CCER_CC2P_Pos (5U)
#define TIM_CCER_CC2P_Msk (0x1UL << TIM_CCER_CC2P_Pos) /*!< 0x00000020 */
#define TIM_CCER_CC2P TIM_CCER_CC2P_Msk /*!<Capture/Compare 2 output Polarity */
#define TIM_CCER_CC2NE_Pos (6U)
#define TIM_CCER_CC2NE_Msk (0x1UL << TIM_CCER_CC2NE_Pos) /*!< 0x00000040 */
#define TIM_CCER_CC2NE TIM_CCER_CC2NE_Msk /*!<Capture/Compare 2 Complementary output enable */
#define TIM_CCER_CC2NP_Pos (7U)
#define TIM_CCER_CC2NP_Msk (0x1UL << TIM_CCER_CC2NP_Pos) /*!< 0x00000080 */
#define TIM_CCER_CC2NP TIM_CCER_CC2NP_Msk /*!<Capture/Compare 2 Complementary output Polarity */
#define TIM_CCER_CC3E_Pos (8U)
#define TIM_CCER_CC3E_Msk (0x1UL << TIM_CCER_CC3E_Pos) /*!< 0x00000100 */
#define TIM_CCER_CC3E TIM_CCER_CC3E_Msk /*!<Capture/Compare 3 output enable */
#define TIM_CCER_CC3P_Pos (9U)
#define TIM_CCER_CC3P_Msk (0x1UL << TIM_CCER_CC3P_Pos) /*!< 0x00000200 */
#define TIM_CCER_CC3P TIM_CCER_CC3P_Msk /*!<Capture/Compare 3 output Polarity */
#define TIM_CCER_CC3NE_Pos (10U)
#define TIM_CCER_CC3NE_Msk (0x1UL << TIM_CCER_CC3NE_Pos) /*!< 0x00000400 */
#define TIM_CCER_CC3NE TIM_CCER_CC3NE_Msk /*!<Capture/Compare 3 Complementary output enable */
#define TIM_CCER_CC3NP_Pos (11U)
#define TIM_CCER_CC3NP_Msk (0x1UL << TIM_CCER_CC3NP_Pos) /*!< 0x00000800 */
#define TIM_CCER_CC3NP TIM_CCER_CC3NP_Msk /*!<Capture/Compare 3 Complementary output Polarity */
#define TIM_CCER_CC4E_Pos (12U)
#define TIM_CCER_CC4E_Msk (0x1UL << TIM_CCER_CC4E_Pos) /*!< 0x00001000 */
#define TIM_CCER_CC4E TIM_CCER_CC4E_Msk /*!<Capture/Compare 4 output enable */
#define TIM_CCER_CC4P_Pos (13U)
#define TIM_CCER_CC4P_Msk (0x1UL << TIM_CCER_CC4P_Pos) /*!< 0x00002000 */
#define TIM_CCER_CC4P TIM_CCER_CC4P_Msk /*!<Capture/Compare 4 output Polarity */
#define TIM_CCER_CC4NE_Pos (14U)
#define TIM_CCER_CC4NE_Msk (0x1UL << TIM_CCER_CC4NE_Pos) /*!< 0x00004000 */
#define TIM_CCER_CC4NE TIM_CCER_CC4NE_Msk /*!<Capture/Compare 4 Complementary output enable */
#define TIM_CCER_CC4NP_Pos (15U)
#define TIM_CCER_CC4NP_Msk (0x1UL << TIM_CCER_CC4NP_Pos) /*!< 0x00008000 */
#define TIM_CCER_CC4NP TIM_CCER_CC4NP_Msk /*!<Capture/Compare 4 Complementary output Polarity */
#define TIM_CCER_CC5E_Pos (16U)
#define TIM_CCER_CC5E_Msk (0x1UL << TIM_CCER_CC5E_Pos) /*!< 0x00010000 */
#define TIM_CCER_CC5E TIM_CCER_CC5E_Msk /*!<Capture/Compare 5 output enable */
#define TIM_CCER_CC5P_Pos (17U)
#define TIM_CCER_CC5P_Msk (0x1UL << TIM_CCER_CC5P_Pos) /*!< 0x00020000 */
#define TIM_CCER_CC5P TIM_CCER_CC5P_Msk /*!<Capture/Compare 5 output Polarity */
#define TIM_CCER_CC6E_Pos (20U)
#define TIM_CCER_CC6E_Msk (0x1UL << TIM_CCER_CC6E_Pos) /*!< 0x00100000 */
#define TIM_CCER_CC6E TIM_CCER_CC6E_Msk /*!<Capture/Compare 6 output enable */
#define TIM_CCER_CC6P_Pos (21U)
#define TIM_CCER_CC6P_Msk (0x1UL << TIM_CCER_CC6P_Pos) /*!< 0x00200000 */
#define TIM_CCER_CC6P TIM_CCER_CC6P_Msk /*!<Capture/Compare 6 output Polarity */
/******************* Bit definition for TIM_CNT register ********************/
#define TIM_CNT_CNT_Pos (0U)
#define TIM_CNT_CNT_Msk (0xFFFFFFFFUL << TIM_CNT_CNT_Pos) /*!< 0xFFFFFFFF */
#define TIM_CNT_CNT TIM_CNT_CNT_Msk /*!<Counter Value */
#define TIM_CNT_UIFCPY_Pos (31U)
#define TIM_CNT_UIFCPY_Msk (0x1UL << TIM_CNT_UIFCPY_Pos) /*!< 0x80000000 */
#define TIM_CNT_UIFCPY TIM_CNT_UIFCPY_Msk /*!<Update interrupt flag copy (if UIFREMAP=1) */
/******************* Bit definition for TIM_PSC register ********************/
#define TIM_PSC_PSC_Pos (0U)
#define TIM_PSC_PSC_Msk (0xFFFFUL << TIM_PSC_PSC_Pos) /*!< 0x0000FFFF */
#define TIM_PSC_PSC TIM_PSC_PSC_Msk /*!<Prescaler Value */
/******************* Bit definition for TIM_ARR register ********************/
#define TIM_ARR_ARR_Pos (0U)
#define TIM_ARR_ARR_Msk (0xFFFFFFFFUL << TIM_ARR_ARR_Pos) /*!< 0xFFFFFFFF */
#define TIM_ARR_ARR TIM_ARR_ARR_Msk /*!<Actual auto-reload Value */
/******************* Bit definition for TIM_RCR register ********************/
#define TIM_RCR_REP_Pos (0U)
#define TIM_RCR_REP_Msk (0xFFFFUL << TIM_RCR_REP_Pos) /*!< 0x0000FFFF */
#define TIM_RCR_REP TIM_RCR_REP_Msk /*!<Repetition Counter Value */
/******************* Bit definition for TIM_CCR1 register *******************/
#define TIM_CCR1_CCR1_Pos (0U)
#define TIM_CCR1_CCR1_Msk (0xFFFFUL << TIM_CCR1_CCR1_Pos) /*!< 0x0000FFFF */
#define TIM_CCR1_CCR1 TIM_CCR1_CCR1_Msk /*!<Capture/Compare 1 Value */
/******************* Bit definition for TIM_CCR2 register *******************/
#define TIM_CCR2_CCR2_Pos (0U)
#define TIM_CCR2_CCR2_Msk (0xFFFFUL << TIM_CCR2_CCR2_Pos) /*!< 0x0000FFFF */
#define TIM_CCR2_CCR2 TIM_CCR2_CCR2_Msk /*!<Capture/Compare 2 Value */
/******************* Bit definition for TIM_CCR3 register *******************/
#define TIM_CCR3_CCR3_Pos (0U)
#define TIM_CCR3_CCR3_Msk (0xFFFFUL << TIM_CCR3_CCR3_Pos) /*!< 0x0000FFFF */
#define TIM_CCR3_CCR3 TIM_CCR3_CCR3_Msk /*!<Capture/Compare 3 Value */
/******************* Bit definition for TIM_CCR4 register *******************/
#define TIM_CCR4_CCR4_Pos (0U)
#define TIM_CCR4_CCR4_Msk (0xFFFFUL << TIM_CCR4_CCR4_Pos) /*!< 0x0000FFFF */
#define TIM_CCR4_CCR4 TIM_CCR4_CCR4_Msk /*!<Capture/Compare 4 Value */
/******************* Bit definition for TIM_CCR5 register *******************/
#define TIM_CCR5_CCR5_Pos (0U)
#define TIM_CCR5_CCR5_Msk (0xFFFFFFFFUL << TIM_CCR5_CCR5_Pos) /*!< 0xFFFFFFFF */
#define TIM_CCR5_CCR5 TIM_CCR5_CCR5_Msk /*!<Capture/Compare 5 Value */
#define TIM_CCR5_GC5C1_Pos (29U)
#define TIM_CCR5_GC5C1_Msk (0x1UL << TIM_CCR5_GC5C1_Pos) /*!< 0x20000000 */
#define TIM_CCR5_GC5C1 TIM_CCR5_GC5C1_Msk /*!<Group Channel 5 and Channel 1 */
#define TIM_CCR5_GC5C2_Pos (30U)
#define TIM_CCR5_GC5C2_Msk (0x1UL << TIM_CCR5_GC5C2_Pos) /*!< 0x40000000 */
#define TIM_CCR5_GC5C2 TIM_CCR5_GC5C2_Msk /*!<Group Channel 5 and Channel 2 */
#define TIM_CCR5_GC5C3_Pos (31U)
#define TIM_CCR5_GC5C3_Msk (0x1UL << TIM_CCR5_GC5C3_Pos) /*!< 0x80000000 */
#define TIM_CCR5_GC5C3 TIM_CCR5_GC5C3_Msk /*!<Group Channel 5 and Channel 3 */
/******************* Bit definition for TIM_CCR6 register *******************/
#define TIM_CCR6_CCR6_Pos (0U)
#define TIM_CCR6_CCR6_Msk (0xFFFFUL << TIM_CCR6_CCR6_Pos) /*!< 0x0000FFFF */
#define TIM_CCR6_CCR6 TIM_CCR6_CCR6_Msk /*!<Capture/Compare 6 Value */
/******************* Bit definition for TIM_BDTR register *******************/
#define TIM_BDTR_DTG_Pos (0U)
#define TIM_BDTR_DTG_Msk (0xFFUL << TIM_BDTR_DTG_Pos) /*!< 0x000000FF */
#define TIM_BDTR_DTG TIM_BDTR_DTG_Msk /*!<DTG[0:7] bits (Dead-Time Generator set-up) */
#define TIM_BDTR_DTG_0 (0x01UL << TIM_BDTR_DTG_Pos) /*!< 0x00000001 */
#define TIM_BDTR_DTG_1 (0x02UL << TIM_BDTR_DTG_Pos) /*!< 0x00000002 */
#define TIM_BDTR_DTG_2 (0x04UL << TIM_BDTR_DTG_Pos) /*!< 0x00000004 */
#define TIM_BDTR_DTG_3 (0x08UL << TIM_BDTR_DTG_Pos) /*!< 0x00000008 */
#define TIM_BDTR_DTG_4 (0x10UL << TIM_BDTR_DTG_Pos) /*!< 0x00000010 */
#define TIM_BDTR_DTG_5 (0x20UL << TIM_BDTR_DTG_Pos) /*!< 0x00000020 */
#define TIM_BDTR_DTG_6 (0x40UL << TIM_BDTR_DTG_Pos) /*!< 0x00000040 */
#define TIM_BDTR_DTG_7 (0x80UL << TIM_BDTR_DTG_Pos) /*!< 0x00000080 */
#define TIM_BDTR_LOCK_Pos (8U)
#define TIM_BDTR_LOCK_Msk (0x3UL << TIM_BDTR_LOCK_Pos) /*!< 0x00000300 */
#define TIM_BDTR_LOCK TIM_BDTR_LOCK_Msk /*!<LOCK[1:0] bits (Lock Configuration) */
#define TIM_BDTR_LOCK_0 (0x1UL << TIM_BDTR_LOCK_Pos) /*!< 0x00000100 */
#define TIM_BDTR_LOCK_1 (0x2UL << TIM_BDTR_LOCK_Pos) /*!< 0x00000200 */
#define TIM_BDTR_OSSI_Pos (10U)
#define TIM_BDTR_OSSI_Msk (0x1UL << TIM_BDTR_OSSI_Pos) /*!< 0x00000400 */
#define TIM_BDTR_OSSI TIM_BDTR_OSSI_Msk /*!<Off-State Selection for Idle mode */
#define TIM_BDTR_OSSR_Pos (11U)
#define TIM_BDTR_OSSR_Msk (0x1UL << TIM_BDTR_OSSR_Pos) /*!< 0x00000800 */
#define TIM_BDTR_OSSR TIM_BDTR_OSSR_Msk /*!<Off-State Selection for Run mode */
#define TIM_BDTR_BKE_Pos (12U)
#define TIM_BDTR_BKE_Msk (0x1UL << TIM_BDTR_BKE_Pos) /*!< 0x00001000 */
#define TIM_BDTR_BKE TIM_BDTR_BKE_Msk /*!<Break enable for Break 1 */
#define TIM_BDTR_BKP_Pos (13U)
#define TIM_BDTR_BKP_Msk (0x1UL << TIM_BDTR_BKP_Pos) /*!< 0x00002000 */
#define TIM_BDTR_BKP TIM_BDTR_BKP_Msk /*!<Break Polarity for Break 1 */
#define TIM_BDTR_AOE_Pos (14U)
#define TIM_BDTR_AOE_Msk (0x1UL << TIM_BDTR_AOE_Pos) /*!< 0x00004000 */
#define TIM_BDTR_AOE TIM_BDTR_AOE_Msk /*!<Automatic Output enable */
#define TIM_BDTR_MOE_Pos (15U)
#define TIM_BDTR_MOE_Msk (0x1UL << TIM_BDTR_MOE_Pos) /*!< 0x00008000 */
#define TIM_BDTR_MOE TIM_BDTR_MOE_Msk /*!<Main Output enable */
#define TIM_BDTR_BKF_Pos (16U)
#define TIM_BDTR_BKF_Msk (0xFUL << TIM_BDTR_BKF_Pos) /*!< 0x000F0000 */
#define TIM_BDTR_BKF TIM_BDTR_BKF_Msk /*!<Break Filter for Break 1 */
#define TIM_BDTR_BK2F_Pos (20U)
#define TIM_BDTR_BK2F_Msk (0xFUL << TIM_BDTR_BK2F_Pos) /*!< 0x00F00000 */
#define TIM_BDTR_BK2F TIM_BDTR_BK2F_Msk /*!<Break Filter for Break 2 */
#define TIM_BDTR_BK2E_Pos (24U)
#define TIM_BDTR_BK2E_Msk (0x1UL << TIM_BDTR_BK2E_Pos) /*!< 0x01000000 */
#define TIM_BDTR_BK2E TIM_BDTR_BK2E_Msk /*!<Break enable for Break 2 */
#define TIM_BDTR_BK2P_Pos (25U)
#define TIM_BDTR_BK2P_Msk (0x1UL << TIM_BDTR_BK2P_Pos) /*!< 0x02000000 */
#define TIM_BDTR_BK2P TIM_BDTR_BK2P_Msk /*!<Break Polarity for Break 2 */
#define TIM_BDTR_BKDSRM_Pos (26U)
#define TIM_BDTR_BKDSRM_Msk (0x1UL << TIM_BDTR_BKDSRM_Pos) /*!< 0x04000000 */
#define TIM_BDTR_BKDSRM TIM_BDTR_BKDSRM_Msk /*!<Break disarming/re-arming */
#define TIM_BDTR_BK2DSRM_Pos (27U)
#define TIM_BDTR_BK2DSRM_Msk (0x1UL << TIM_BDTR_BK2DSRM_Pos) /*!< 0x08000000 */
#define TIM_BDTR_BK2DSRM TIM_BDTR_BK2DSRM_Msk /*!<Break2 disarming/re-arming */
#define TIM_BDTR_BKBID_Pos (28U)
#define TIM_BDTR_BKBID_Msk (0x1UL << TIM_BDTR_BKBID_Pos) /*!< 0x10000000 */
#define TIM_BDTR_BKBID TIM_BDTR_BKBID_Msk /*!<Break BIDirectional */
#define TIM_BDTR_BK2BID_Pos (29U)
#define TIM_BDTR_BK2BID_Msk (0x1UL << TIM_BDTR_BK2BID_Pos) /*!< 0x20000000 */
#define TIM_BDTR_BK2BID TIM_BDTR_BK2BID_Msk /*!<Break2 BIDirectional */
/******************* Bit definition for TIM_DCR register ********************/
#define TIM_DCR_DBA_Pos (0U)
#define TIM_DCR_DBA_Msk (0x1FUL << TIM_DCR_DBA_Pos) /*!< 0x0000001F */
#define TIM_DCR_DBA TIM_DCR_DBA_Msk /*!<DBA[4:0] bits (DMA Base Address) */
#define TIM_DCR_DBA_0 (0x01UL << TIM_DCR_DBA_Pos) /*!< 0x00000001 */
#define TIM_DCR_DBA_1 (0x02UL << TIM_DCR_DBA_Pos) /*!< 0x00000002 */
#define TIM_DCR_DBA_2 (0x04UL << TIM_DCR_DBA_Pos) /*!< 0x00000004 */
#define TIM_DCR_DBA_3 (0x08UL << TIM_DCR_DBA_Pos) /*!< 0x00000008 */
#define TIM_DCR_DBA_4 (0x10UL << TIM_DCR_DBA_Pos) /*!< 0x00000010 */
#define TIM_DCR_DBL_Pos (8U)
#define TIM_DCR_DBL_Msk (0x1FUL << TIM_DCR_DBL_Pos) /*!< 0x00001F00 */
#define TIM_DCR_DBL TIM_DCR_DBL_Msk /*!<DBL[4:0] bits (DMA Burst Length) */
#define TIM_DCR_DBL_0 (0x01UL << TIM_DCR_DBL_Pos) /*!< 0x00000100 */
#define TIM_DCR_DBL_1 (0x02UL << TIM_DCR_DBL_Pos) /*!< 0x00000200 */
#define TIM_DCR_DBL_2 (0x04UL << TIM_DCR_DBL_Pos) /*!< 0x00000400 */
#define TIM_DCR_DBL_3 (0x08UL << TIM_DCR_DBL_Pos) /*!< 0x00000800 */
#define TIM_DCR_DBL_4 (0x10UL << TIM_DCR_DBL_Pos) /*!< 0x00001000 */
/******************* Bit definition for TIM1_AF1 register *******************/
#define TIM1_AF1_BKINE_Pos (0U)
#define TIM1_AF1_BKINE_Msk (0x1UL << TIM1_AF1_BKINE_Pos) /*!< 0x00000001 */
#define TIM1_AF1_BKINE TIM1_AF1_BKINE_Msk /*!<BRK BKIN input enable */
#define TIM1_AF1_BKCMP1E_Pos (1U)
#define TIM1_AF1_BKCMP1E_Msk (0x1UL << TIM1_AF1_BKCMP1E_Pos) /*!< 0x00000002 */
#define TIM1_AF1_BKCMP1E TIM1_AF1_BKCMP1E_Msk /*!<BRK COMP1 enable */
#define TIM1_AF1_BKCMP2E_Pos (2U)
#define TIM1_AF1_BKCMP2E_Msk (0x1UL << TIM1_AF1_BKCMP2E_Pos) /*!< 0x00000004 */
#define TIM1_AF1_BKCMP2E TIM1_AF1_BKCMP2E_Msk /*!<BRK COMP2 enable */
#define TIM1_AF1_BKCMP3E_Pos (3U)
#define TIM1_AF1_BKCMP3E_Msk (0x1UL << TIM1_AF1_BKCMP3E_Pos) /*!< 0x00000008 */
#define TIM1_AF1_BKCMP3E TIM1_AF1_BKCMP3E_Msk /*!<BRK COMP3 enable */
#define TIM1_AF1_BKCMP4E_Pos (4U)
#define TIM1_AF1_BKCMP4E_Msk (0x1UL << TIM1_AF1_BKCMP4E_Pos) /*!< 0x00000010 */
#define TIM1_AF1_BKCMP4E TIM1_AF1_BKCMP4E_Msk /*!<BRK COMP4 enable */
#define TIM1_AF1_BKINP_Pos (9U)
#define TIM1_AF1_BKINP_Msk (0x1UL << TIM1_AF1_BKINP_Pos) /*!< 0x00000200 */
#define TIM1_AF1_BKINP TIM1_AF1_BKINP_Msk /*!<BRK BKIN input polarity */
#define TIM1_AF1_BKCMP1P_Pos (10U)
#define TIM1_AF1_BKCMP1P_Msk (0x1UL << TIM1_AF1_BKCMP1P_Pos) /*!< 0x00000400 */
#define TIM1_AF1_BKCMP1P TIM1_AF1_BKCMP1P_Msk /*!<BRK COMP1 input polarity */
#define TIM1_AF1_BKCMP2P_Pos (11U)
#define TIM1_AF1_BKCMP2P_Msk (0x1UL << TIM1_AF1_BKCMP2P_Pos) /*!< 0x00000800 */
#define TIM1_AF1_BKCMP2P TIM1_AF1_BKCMP2P_Msk /*!<BRK COMP2 input polarity */
#define TIM1_AF1_BKCMP3P_Pos (12U)
#define TIM1_AF1_BKCMP3P_Msk (0x1UL << TIM1_AF1_BKCMP3P_Pos) /*!< 0x00001000 */
#define TIM1_AF1_BKCMP3P TIM1_AF1_BKCMP3P_Msk /*!<BRK COMP3 input polarity */
#define TIM1_AF1_BKCMP4P_Pos (13U)
#define TIM1_AF1_BKCMP4P_Msk (0x1UL << TIM1_AF1_BKCMP4P_Pos) /*!< 0x00002000 */
#define TIM1_AF1_BKCMP4P TIM1_AF1_BKCMP4P_Msk /*!<BRK COMP4 input polarity */
#define TIM1_AF1_ETRSEL_Pos (14U)
#define TIM1_AF1_ETRSEL_Msk (0xFUL << TIM1_AF1_ETRSEL_Pos) /*!< 0x0003C000 */
#define TIM1_AF1_ETRSEL TIM1_AF1_ETRSEL_Msk /*!<ETRSEL[3:0] bits (TIM1 ETR source selection) */
#define TIM1_AF1_ETRSEL_0 (0x1UL << TIM1_AF1_ETRSEL_Pos) /*!< 0x00004000 */
#define TIM1_AF1_ETRSEL_1 (0x2UL << TIM1_AF1_ETRSEL_Pos) /*!< 0x00008000 */
#define TIM1_AF1_ETRSEL_2 (0x4UL << TIM1_AF1_ETRSEL_Pos) /*!< 0x00010000 */
#define TIM1_AF1_ETRSEL_3 (0x8UL << TIM1_AF1_ETRSEL_Pos) /*!< 0x00020000 */
/******************* Bit definition for TIM1_AF2 register *********************/
#define TIM1_AF2_BK2INE_Pos (0U)
#define TIM1_AF2_BK2INE_Msk (0x1UL << TIM1_AF2_BK2INE_Pos) /*!< 0x00000001 */
#define TIM1_AF2_BK2INE TIM1_AF2_BK2INE_Msk /*!<BRK2 BKIN input enable */
#define TIM1_AF2_BK2CMP1E_Pos (1U)
#define TIM1_AF2_BK2CMP1E_Msk (0x1UL << TIM1_AF2_BK2CMP1E_Pos) /*!< 0x00000002 */
#define TIM1_AF2_BK2CMP1E TIM1_AF2_BK2CMP1E_Msk /*!<BRK2 COMP1 enable */
#define TIM1_AF2_BK2CMP2E_Pos (2U)
#define TIM1_AF2_BK2CMP2E_Msk (0x1UL << TIM1_AF2_BK2CMP2E_Pos) /*!< 0x00000004 */
#define TIM1_AF2_BK2CMP2E TIM1_AF2_BK2CMP2E_Msk /*!<BRK2 COMP2 enable */
#define TIM1_AF2_BK2CMP3E_Pos (3U)
#define TIM1_AF2_BK2CMP3E_Msk (0x1UL << TIM1_AF2_BK2CMP3E_Pos) /*!< 0x00000008 */
#define TIM1_AF2_BK2CMP3E TIM1_AF2_BK2CMP3E_Msk /*!<BRK2 COMP3 enable */
#define TIM1_AF2_BK2CMP4E_Pos (4U)
#define TIM1_AF2_BK2CMP4E_Msk (0x1UL << TIM1_AF2_BK2CMP4E_Pos) /*!< 0x00000010 */
#define TIM1_AF2_BK2CMP4E TIM1_AF2_BK2CMP4E_Msk /*!<BRK2 COMP4 enable */
#define TIM1_AF2_BK2INP_Pos (9U)
#define TIM1_AF2_BK2INP_Msk (0x1UL << TIM1_AF2_BK2INP_Pos) /*!< 0x00000200 */
#define TIM1_AF2_BK2INP TIM1_AF2_BK2INP_Msk /*!<BRK2 BKIN input polarity */
#define TIM1_AF2_BK2CMP1P_Pos (10U)
#define TIM1_AF2_BK2CMP1P_Msk (0x1UL << TIM1_AF2_BK2CMP1P_Pos) /*!< 0x00000400 */
#define TIM1_AF2_BK2CMP1P TIM1_AF2_BK2CMP1P_Msk /*!<BRK2 COMP1 input polarity */
#define TIM1_AF2_BK2CMP2P_Pos (11U)
#define TIM1_AF2_BK2CMP2P_Msk (0x1UL << TIM1_AF2_BK2CMP2P_Pos) /*!< 0x00000800 */
#define TIM1_AF2_BK2CMP2P TIM1_AF2_BK2CMP2P_Msk /*!<BRK2 COMP2 input polarity */
#define TIM1_AF2_BK2CMP3P_Pos (12U)
#define TIM1_AF2_BK2CMP3P_Msk (0x1UL << TIM1_AF2_BK2CMP3P_Pos) /*!< 0x00000400 */
#define TIM1_AF2_BK2CMP3P TIM1_AF2_BK2CMP3P_Msk /*!<BRK2 COMP3 input polarity */
#define TIM1_AF2_BK2CMP4P_Pos (13U)
#define TIM1_AF2_BK2CMP4P_Msk (0x1UL << TIM1_AF2_BK2CMP4P_Pos) /*!< 0x00000800 */
#define TIM1_AF2_BK2CMP4P TIM1_AF2_BK2CMP4P_Msk /*!<BRK2 COMP4 input polarity */
#define TIM1_AF2_OCRSEL_Pos (16U)
#define TIM1_AF2_OCRSEL_Msk (0x7UL << TIM1_AF2_OCRSEL_Pos) /*!< 0x00070000 */
#define TIM1_AF2_OCRSEL TIM1_AF2_OCRSEL_Msk /*!<BRK2 COMP2 input polarity */
#define TIM1_AF2_OCRSEL_0 (0x1UL << TIM1_AF2_OCRSEL_Pos) /*!< 0x00010000 */
#define TIM1_AF2_OCRSEL_1 (0x2UL << TIM1_AF2_OCRSEL_Pos) /*!< 0x00020000 */
#define TIM1_AF2_OCRSEL_2 (0x4UL << TIM1_AF2_OCRSEL_Pos) /*!< 0x00040000 */
/******************* Bit definition for TIM_OR register *********************/
#define TIM_OR_HSE32EN_Pos (0U)
#define TIM_OR_HSE32EN_Msk (0x1UL << TIM_OR_HSE32EN_Pos) /*!< 0x00000001 */
#define TIM_OR_HSE32EN TIM_OR_HSE32EN_Msk /*!< HSE/32 clock enable */
/******************* Bit definition for TIM_TISEL register *********************/
#define TIM_TISEL_TI1SEL_Pos (0U)
#define TIM_TISEL_TI1SEL_Msk (0xFUL << TIM_TISEL_TI1SEL_Pos) /*!< 0x0000000F */
#define TIM_TISEL_TI1SEL TIM_TISEL_TI1SEL_Msk /*!<TI1SEL[3:0] bits (TIM1 TI1 SEL)*/
#define TIM_TISEL_TI1SEL_0 (0x1UL << TIM_TISEL_TI1SEL_Pos) /*!< 0x00000001 */
#define TIM_TISEL_TI1SEL_1 (0x2UL << TIM_TISEL_TI1SEL_Pos) /*!< 0x00000002 */
#define TIM_TISEL_TI1SEL_2 (0x4UL << TIM_TISEL_TI1SEL_Pos) /*!< 0x00000004 */
#define TIM_TISEL_TI1SEL_3 (0x8UL << TIM_TISEL_TI1SEL_Pos) /*!< 0x00000008 */
#define TIM_TISEL_TI2SEL_Pos (8U)
#define TIM_TISEL_TI2SEL_Msk (0xFUL << TIM_TISEL_TI2SEL_Pos) /*!< 0x00000F00 */
#define TIM_TISEL_TI2SEL TIM_TISEL_TI2SEL_Msk /*!<TI2SEL[3:0] bits (TIM1 TI2 SEL)*/
#define TIM_TISEL_TI2SEL_0 (0x1UL << TIM_TISEL_TI2SEL_Pos) /*!< 0x00000100 */
#define TIM_TISEL_TI2SEL_1 (0x2UL << TIM_TISEL_TI2SEL_Pos) /*!< 0x00000200 */
#define TIM_TISEL_TI2SEL_2 (0x4UL << TIM_TISEL_TI2SEL_Pos) /*!< 0x00000400 */
#define TIM_TISEL_TI2SEL_3 (0x8UL << TIM_TISEL_TI2SEL_Pos) /*!< 0x00000800 */
#define TIM_TISEL_TI3SEL_Pos (16U)
#define TIM_TISEL_TI3SEL_Msk (0xFUL << TIM_TISEL_TI3SEL_Pos) /*!< 0x000F0000 */
#define TIM_TISEL_TI3SEL TIM_TISEL_TI3SEL_Msk /*!<TI3SEL[3:0] bits (TIM1 TI3 SEL)*/
#define TIM_TISEL_TI3SEL_0 (0x1UL << TIM_TISEL_TI3SEL_Pos) /*!< 0x00010000 */
#define TIM_TISEL_TI3SEL_1 (0x2UL << TIM_TISEL_TI3SEL_Pos) /*!< 0x00020000 */
#define TIM_TISEL_TI3SEL_2 (0x4UL << TIM_TISEL_TI3SEL_Pos) /*!< 0x00040000 */
#define TIM_TISEL_TI3SEL_3 (0x8UL << TIM_TISEL_TI3SEL_Pos) /*!< 0x00080000 */
#define TIM_TISEL_TI4SEL_Pos (24U)
#define TIM_TISEL_TI4SEL_Msk (0xFUL << TIM_TISEL_TI4SEL_Pos) /*!< 0x0F000000 */
#define TIM_TISEL_TI4SEL TIM_TISEL_TI4SEL_Msk /*!<TI4SEL[3:0] bits (TIM1 TI4 SEL)*/
#define TIM_TISEL_TI4SEL_0 (0x1UL << TIM_TISEL_TI4SEL_Pos) /*!< 0x01000000 */
#define TIM_TISEL_TI4SEL_1 (0x2UL << TIM_TISEL_TI4SEL_Pos) /*!< 0x02000000 */
#define TIM_TISEL_TI4SEL_2 (0x4UL << TIM_TISEL_TI4SEL_Pos) /*!< 0x04000000 */
#define TIM_TISEL_TI4SEL_3 (0x8UL << TIM_TISEL_TI4SEL_Pos) /*!< 0x08000000 */
/******************* Bit definition for TIM_DTR2 register *********************/
#define TIM_DTR2_DTGF_Pos (0U)
#define TIM_DTR2_DTGF_Msk (0xFFUL << TIM_DTR2_DTGF_Pos) /*!< 0x0000000F */
#define TIM_DTR2_DTGF TIM_DTR2_DTGF_Msk /*!<DTGF[7:0] bits (Deadtime falling edge generator setup)*/
#define TIM_DTR2_DTGF_0 (0x01UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000001 */
#define TIM_DTR2_DTGF_1 (0x02UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000002 */
#define TIM_DTR2_DTGF_2 (0x04UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000004 */
#define TIM_DTR2_DTGF_3 (0x08UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000008 */
#define TIM_DTR2_DTGF_4 (0x10UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000010 */
#define TIM_DTR2_DTGF_5 (0x20UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000020 */
#define TIM_DTR2_DTGF_6 (0x40UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000040 */
#define TIM_DTR2_DTGF_7 (0x80UL << TIM_DTR2_DTGF_Pos) /*!< 0x00000080 */
#define TIM_DTR2_DTAE_Pos (16U)
#define TIM_DTR2_DTAE_Msk (0x1UL << TIM_DTR2_DTAE_Pos) /*!< 0x00004000 */
#define TIM_DTR2_DTAE TIM_DTR2_DTAE_Msk /*!<Deadtime asymmetric enable */
#define TIM_DTR2_DTPE_Pos (17U)
#define TIM_DTR2_DTPE_Msk (0x1UL << TIM_DTR2_DTPE_Pos) /*!< 0x00008000 */
#define TIM_DTR2_DTPE TIM_DTR2_DTPE_Msk /*!<Deadtime prelaod enable */
/******************* Bit definition for TIM_ECR register *********************/
#define TIM_ECR_IE_Pos (0U)
#define TIM_ECR_IE_Msk (0x1UL << TIM_ECR_IE_Pos) /*!< 0x00000001 */
#define TIM_ECR_IE TIM_ECR_IE_Msk /*!<Index enable */
#define TIM_ECR_IDIR_Pos (1U)
#define TIM_ECR_IDIR_Msk (0x3UL << TIM_ECR_IDIR_Pos) /*!< 0x00000006 */
#define TIM_ECR_IDIR TIM_ECR_IDIR_Msk /*!<IDIR[1:0] bits (Index direction)*/
#define TIM_ECR_IDIR_0 (0x01UL << TIM_ECR_IDIR_Pos) /*!< 0x00000001 */
#define TIM_ECR_IDIR_1 (0x02UL << TIM_ECR_IDIR_Pos) /*!< 0x00000002 */
#define TIM_ECR_FIDX_Pos (5U)
#define TIM_ECR_FIDX_Msk (0x1UL << TIM_ECR_FIDX_Pos) /*!< 0x00000020 */
#define TIM_ECR_FIDX TIM_ECR_FIDX_Msk /*!<First index enable */
#define TIM_ECR_IPOS_Pos (6U)
#define TIM_ECR_IPOS_Msk (0x3UL << TIM_ECR_IPOS_Pos) /*!< 0x0000000C0 */
#define TIM_ECR_IPOS TIM_ECR_IPOS_Msk /*!<IPOS[1:0] bits (Index positioning)*/
#define TIM_ECR_IPOS_0 (0x01UL << TIM_ECR_IPOS_Pos) /*!< 0x00000001 */
#define TIM_ECR_IPOS_1 (0x02UL << TIM_ECR_IPOS_Pos) /*!< 0x00000002 */
#define TIM_ECR_PW_Pos (16U)
#define TIM_ECR_PW_Msk (0xFFUL << TIM_ECR_PW_Pos) /*!< 0x00FF0000 */
#define TIM_ECR_PW TIM_ECR_PW_Msk /*!<PW[7:0] bits (Pulse width)*/
#define TIM_ECR_PW_0 (0x01UL << TIM_ECR_PW_Pos) /*!< 0x00010000 */
#define TIM_ECR_PW_1 (0x02UL << TIM_ECR_PW_Pos) /*!< 0x00020000 */
#define TIM_ECR_PW_2 (0x04UL << TIM_ECR_PW_Pos) /*!< 0x00040000 */
#define TIM_ECR_PW_3 (0x08UL << TIM_ECR_PW_Pos) /*!< 0x00080000 */
#define TIM_ECR_PW_4 (0x10UL << TIM_ECR_PW_Pos) /*!< 0x00100000 */
#define TIM_ECR_PW_5 (0x20UL << TIM_ECR_PW_Pos) /*!< 0x00200000 */
#define TIM_ECR_PW_6 (0x40UL << TIM_ECR_PW_Pos) /*!< 0x00400000 */
#define TIM_ECR_PW_7 (0x80UL << TIM_ECR_PW_Pos) /*!< 0x00800000 */
#define TIM_ECR_PWPRSC_Pos (24U)
#define TIM_ECR_PWPRSC_Msk (0x7UL << TIM_ECR_PWPRSC_Pos) /*!< 0x07000000 */
#define TIM_ECR_PWPRSC TIM_ECR_PWPRSC_Msk /*!<PWPRSC[2:0] bits (Pulse width prescaler)*/
#define TIM_ECR_PWPRSC_0 (0x01UL << TIM_ECR_PWPRSC_Pos) /*!< 0x01000000 */
#define TIM_ECR_PWPRSC_1 (0x02UL << TIM_ECR_PWPRSC_Pos) /*!< 0x02000000 */
#define TIM_ECR_PWPRSC_2 (0x04UL << TIM_ECR_PWPRSC_Pos) /*!< 0x04000000 */
/******************* Bit definition for TIM_DMAR register *******************/
#define TIM_DMAR_DMAB_Pos (0U)
#define TIM_DMAR_DMAB_Msk (0xFFFFFFFFUL << TIM_DMAR_DMAB_Pos) /*!< 0xFFFFFFFF */
#define TIM_DMAR_DMAB TIM_DMAR_DMAB_Msk /*!<DMA register for burst accesses */
/******************************************************************************/
/* */
/* Low Power Timer (LPTIM) */
/* */
/******************************************************************************/
/****************** Bit definition for LPTIM_ISR register *******************/
#define LPTIM_ISR_CMPM_Pos (0U)
#define LPTIM_ISR_CMPM_Msk (0x1UL << LPTIM_ISR_CMPM_Pos) /*!< 0x00000001 */
#define LPTIM_ISR_CMPM LPTIM_ISR_CMPM_Msk /*!< Compare match */
#define LPTIM_ISR_ARRM_Pos (1U)
#define LPTIM_ISR_ARRM_Msk (0x1UL << LPTIM_ISR_ARRM_Pos) /*!< 0x00000002 */
#define LPTIM_ISR_ARRM LPTIM_ISR_ARRM_Msk /*!< Autoreload match */
#define LPTIM_ISR_EXTTRIG_Pos (2U)
#define LPTIM_ISR_EXTTRIG_Msk (0x1UL << LPTIM_ISR_EXTTRIG_Pos) /*!< 0x00000004 */
#define LPTIM_ISR_EXTTRIG LPTIM_ISR_EXTTRIG_Msk /*!< External trigger edge event */
#define LPTIM_ISR_CMPOK_Pos (3U)
#define LPTIM_ISR_CMPOK_Msk (0x1UL << LPTIM_ISR_CMPOK_Pos) /*!< 0x00000008 */
#define LPTIM_ISR_CMPOK LPTIM_ISR_CMPOK_Msk /*!< Compare register update OK */
#define LPTIM_ISR_ARROK_Pos (4U)
#define LPTIM_ISR_ARROK_Msk (0x1UL << LPTIM_ISR_ARROK_Pos) /*!< 0x00000010 */
#define LPTIM_ISR_ARROK LPTIM_ISR_ARROK_Msk /*!< Autoreload register update OK */
#define LPTIM_ISR_UP_Pos (5U)
#define LPTIM_ISR_UP_Msk (0x1UL << LPTIM_ISR_UP_Pos) /*!< 0x00000020 */
#define LPTIM_ISR_UP LPTIM_ISR_UP_Msk /*!< Counter direction change down to up */
#define LPTIM_ISR_DOWN_Pos (6U)
#define LPTIM_ISR_DOWN_Msk (0x1UL << LPTIM_ISR_DOWN_Pos) /*!< 0x00000040 */
#define LPTIM_ISR_DOWN LPTIM_ISR_DOWN_Msk /*!< Counter direction change up to down */
/****************** Bit definition for LPTIM_ICR register *******************/
#define LPTIM_ICR_CMPMCF_Pos (0U)
#define LPTIM_ICR_CMPMCF_Msk (0x1UL << LPTIM_ICR_CMPMCF_Pos) /*!< 0x00000001 */
#define LPTIM_ICR_CMPMCF LPTIM_ICR_CMPMCF_Msk /*!< Compare match Clear Flag */
#define LPTIM_ICR_ARRMCF_Pos (1U)
#define LPTIM_ICR_ARRMCF_Msk (0x1UL << LPTIM_ICR_ARRMCF_Pos) /*!< 0x00000002 */
#define LPTIM_ICR_ARRMCF LPTIM_ICR_ARRMCF_Msk /*!< Autoreload match Clear Flag */
#define LPTIM_ICR_EXTTRIGCF_Pos (2U)
#define LPTIM_ICR_EXTTRIGCF_Msk (0x1UL << LPTIM_ICR_EXTTRIGCF_Pos) /*!< 0x00000004 */
#define LPTIM_ICR_EXTTRIGCF LPTIM_ICR_EXTTRIGCF_Msk /*!< External trigger edge event Clear Flag */
#define LPTIM_ICR_CMPOKCF_Pos (3U)
#define LPTIM_ICR_CMPOKCF_Msk (0x1UL << LPTIM_ICR_CMPOKCF_Pos) /*!< 0x00000008 */
#define LPTIM_ICR_CMPOKCF LPTIM_ICR_CMPOKCF_Msk /*!< Compare register update OK Clear Flag */
#define LPTIM_ICR_ARROKCF_Pos (4U)
#define LPTIM_ICR_ARROKCF_Msk (0x1UL << LPTIM_ICR_ARROKCF_Pos) /*!< 0x00000010 */
#define LPTIM_ICR_ARROKCF LPTIM_ICR_ARROKCF_Msk /*!< Autoreload register update OK Clear Flag */
#define LPTIM_ICR_UPCF_Pos (5U)
#define LPTIM_ICR_UPCF_Msk (0x1UL << LPTIM_ICR_UPCF_Pos) /*!< 0x00000020 */
#define LPTIM_ICR_UPCF LPTIM_ICR_UPCF_Msk /*!< Counter direction change down to up Clear Flag */
#define LPTIM_ICR_DOWNCF_Pos (6U)
#define LPTIM_ICR_DOWNCF_Msk (0x1UL << LPTIM_ICR_DOWNCF_Pos) /*!< 0x00000040 */
#define LPTIM_ICR_DOWNCF LPTIM_ICR_DOWNCF_Msk /*!< Counter direction change up to down Clear Flag */
/****************** Bit definition for LPTIM_IER register ********************/
#define LPTIM_IER_CMPMIE_Pos (0U)
#define LPTIM_IER_CMPMIE_Msk (0x1UL << LPTIM_IER_CMPMIE_Pos) /*!< 0x00000001 */
#define LPTIM_IER_CMPMIE LPTIM_IER_CMPMIE_Msk /*!< Compare match Interrupt Enable */
#define LPTIM_IER_ARRMIE_Pos (1U)
#define LPTIM_IER_ARRMIE_Msk (0x1UL << LPTIM_IER_ARRMIE_Pos) /*!< 0x00000002 */
#define LPTIM_IER_ARRMIE LPTIM_IER_ARRMIE_Msk /*!< Autoreload match Interrupt Enable */
#define LPTIM_IER_EXTTRIGIE_Pos (2U)
#define LPTIM_IER_EXTTRIGIE_Msk (0x1UL << LPTIM_IER_EXTTRIGIE_Pos) /*!< 0x00000004 */
#define LPTIM_IER_EXTTRIGIE LPTIM_IER_EXTTRIGIE_Msk /*!< External trigger edge event Interrupt Enable */
#define LPTIM_IER_CMPOKIE_Pos (3U)
#define LPTIM_IER_CMPOKIE_Msk (0x1UL << LPTIM_IER_CMPOKIE_Pos) /*!< 0x00000008 */
#define LPTIM_IER_CMPOKIE LPTIM_IER_CMPOKIE_Msk /*!< Compare register update OK Interrupt Enable */
#define LPTIM_IER_ARROKIE_Pos (4U)
#define LPTIM_IER_ARROKIE_Msk (0x1UL << LPTIM_IER_ARROKIE_Pos) /*!< 0x00000010 */
#define LPTIM_IER_ARROKIE LPTIM_IER_ARROKIE_Msk /*!< Autoreload register update OK Interrupt Enable */
#define LPTIM_IER_UPIE_Pos (5U)
#define LPTIM_IER_UPIE_Msk (0x1UL << LPTIM_IER_UPIE_Pos) /*!< 0x00000020 */
#define LPTIM_IER_UPIE LPTIM_IER_UPIE_Msk /*!< Counter direction change down to up Interrupt Enable */
#define LPTIM_IER_DOWNIE_Pos (6U)
#define LPTIM_IER_DOWNIE_Msk (0x1UL << LPTIM_IER_DOWNIE_Pos) /*!< 0x00000040 */
#define LPTIM_IER_DOWNIE LPTIM_IER_DOWNIE_Msk /*!< Counter direction change up to down Interrupt Enable */
/****************** Bit definition for LPTIM_CFGR register *******************/
#define LPTIM_CFGR_CKSEL_Pos (0U)
#define LPTIM_CFGR_CKSEL_Msk (0x1UL << LPTIM_CFGR_CKSEL_Pos) /*!< 0x00000001 */
#define LPTIM_CFGR_CKSEL LPTIM_CFGR_CKSEL_Msk /*!< Clock selector */
#define LPTIM_CFGR_CKPOL_Pos (1U)
#define LPTIM_CFGR_CKPOL_Msk (0x3UL << LPTIM_CFGR_CKPOL_Pos) /*!< 0x00000006 */
#define LPTIM_CFGR_CKPOL LPTIM_CFGR_CKPOL_Msk /*!< CKPOL[1:0] bits (Clock polarity) */
#define LPTIM_CFGR_CKPOL_0 (0x1UL << LPTIM_CFGR_CKPOL_Pos) /*!< 0x00000002 */
#define LPTIM_CFGR_CKPOL_1 (0x2UL << LPTIM_CFGR_CKPOL_Pos) /*!< 0x00000004 */
#define LPTIM_CFGR_CKFLT_Pos (3U)
#define LPTIM_CFGR_CKFLT_Msk (0x3UL << LPTIM_CFGR_CKFLT_Pos) /*!< 0x00000018 */
#define LPTIM_CFGR_CKFLT LPTIM_CFGR_CKFLT_Msk /*!< CKFLT[1:0] bits (Configurable digital filter for external clock) */
#define LPTIM_CFGR_CKFLT_0 (0x1UL << LPTIM_CFGR_CKFLT_Pos) /*!< 0x00000008 */
#define LPTIM_CFGR_CKFLT_1 (0x2UL << LPTIM_CFGR_CKFLT_Pos) /*!< 0x00000010 */
#define LPTIM_CFGR_TRGFLT_Pos (6U)
#define LPTIM_CFGR_TRGFLT_Msk (0x3UL << LPTIM_CFGR_TRGFLT_Pos) /*!< 0x000000C0 */
#define LPTIM_CFGR_TRGFLT LPTIM_CFGR_TRGFLT_Msk /*!< TRGFLT[1:0] bits (Configurable digital filter for trigger) */
#define LPTIM_CFGR_TRGFLT_0 (0x1UL << LPTIM_CFGR_TRGFLT_Pos) /*!< 0x00000040 */
#define LPTIM_CFGR_TRGFLT_1 (0x2UL << LPTIM_CFGR_TRGFLT_Pos) /*!< 0x00000080 */
#define LPTIM_CFGR_PRESC_Pos (9U)
#define LPTIM_CFGR_PRESC_Msk (0x7UL << LPTIM_CFGR_PRESC_Pos) /*!< 0x00000E00 */
#define LPTIM_CFGR_PRESC LPTIM_CFGR_PRESC_Msk /*!< PRESC[2:0] bits (Clock prescaler) */
#define LPTIM_CFGR_PRESC_0 (0x1UL << LPTIM_CFGR_PRESC_Pos) /*!< 0x00000200 */
#define LPTIM_CFGR_PRESC_1 (0x2UL << LPTIM_CFGR_PRESC_Pos) /*!< 0x00000400 */
#define LPTIM_CFGR_PRESC_2 (0x4UL << LPTIM_CFGR_PRESC_Pos) /*!< 0x00000800 */
#define LPTIM_CFGR_TRIGSEL_Pos (13U)
#define LPTIM_CFGR_TRIGSEL_Msk (0x10007UL << LPTIM_CFGR_TRIGSEL_Pos) /*!< 0x0200E000 */
#define LPTIM_CFGR_TRIGSEL LPTIM_CFGR_TRIGSEL_Msk /*!< TRIGSEL[2:0]] bits (Trigger selector) */
#define LPTIM_CFGR_TRIGSEL_0 (0x00001UL << LPTIM_CFGR_TRIGSEL_Pos) /*!< 0x00002000 */
#define LPTIM_CFGR_TRIGSEL_1 (0x00002UL << LPTIM_CFGR_TRIGSEL_Pos) /*!< 0x00004000 */
#define LPTIM_CFGR_TRIGSEL_2 (0x00004UL << LPTIM_CFGR_TRIGSEL_Pos) /*!< 0x00008000 */
#define LPTIM_CFGR_TRIGSEL_3 (0x10000UL << LPTIM_CFGR_TRIGSEL_Pos) /*!< 0x02000000 */
#define LPTIM_CFGR_TRIGEN_Pos (17U)
#define LPTIM_CFGR_TRIGEN_Msk (0x3UL << LPTIM_CFGR_TRIGEN_Pos) /*!< 0x00060000 */
#define LPTIM_CFGR_TRIGEN LPTIM_CFGR_TRIGEN_Msk /*!< TRIGEN[1:0] bits (Trigger enable and polarity) */
#define LPTIM_CFGR_TRIGEN_0 (0x1UL << LPTIM_CFGR_TRIGEN_Pos) /*!< 0x00020000 */
#define LPTIM_CFGR_TRIGEN_1 (0x2UL << LPTIM_CFGR_TRIGEN_Pos) /*!< 0x00040000 */
#define LPTIM_CFGR_TIMOUT_Pos (19U)
#define LPTIM_CFGR_TIMOUT_Msk (0x1UL << LPTIM_CFGR_TIMOUT_Pos) /*!< 0x00080000 */
#define LPTIM_CFGR_TIMOUT LPTIM_CFGR_TIMOUT_Msk /*!< Timout enable */
#define LPTIM_CFGR_WAVE_Pos (20U)
#define LPTIM_CFGR_WAVE_Msk (0x1UL << LPTIM_CFGR_WAVE_Pos) /*!< 0x00100000 */
#define LPTIM_CFGR_WAVE LPTIM_CFGR_WAVE_Msk /*!< Waveform shape */
#define LPTIM_CFGR_WAVPOL_Pos (21U)
#define LPTIM_CFGR_WAVPOL_Msk (0x1UL << LPTIM_CFGR_WAVPOL_Pos) /*!< 0x00200000 */
#define LPTIM_CFGR_WAVPOL LPTIM_CFGR_WAVPOL_Msk /*!< Waveform shape polarity */
#define LPTIM_CFGR_PRELOAD_Pos (22U)
#define LPTIM_CFGR_PRELOAD_Msk (0x1UL << LPTIM_CFGR_PRELOAD_Pos) /*!< 0x00400000 */
#define LPTIM_CFGR_PRELOAD LPTIM_CFGR_PRELOAD_Msk /*!< Reg update mode */
#define LPTIM_CFGR_COUNTMODE_Pos (23U)
#define LPTIM_CFGR_COUNTMODE_Msk (0x1UL << LPTIM_CFGR_COUNTMODE_Pos) /*!< 0x00800000 */
#define LPTIM_CFGR_COUNTMODE LPTIM_CFGR_COUNTMODE_Msk /*!< Counter mode enable */
#define LPTIM_CFGR_ENC_Pos (24U)
#define LPTIM_CFGR_ENC_Msk (0x1UL << LPTIM_CFGR_ENC_Pos) /*!< 0x01000000 */
#define LPTIM_CFGR_ENC LPTIM_CFGR_ENC_Msk /*!< Encoder mode enable */
/****************** Bit definition for LPTIM_CR register ********************/
#define LPTIM_CR_ENABLE_Pos (0U)
#define LPTIM_CR_ENABLE_Msk (0x1UL << LPTIM_CR_ENABLE_Pos) /*!< 0x00000001 */
#define LPTIM_CR_ENABLE LPTIM_CR_ENABLE_Msk /*!< LPTIMer enable */
#define LPTIM_CR_SNGSTRT_Pos (1U)
#define LPTIM_CR_SNGSTRT_Msk (0x1UL << LPTIM_CR_SNGSTRT_Pos) /*!< 0x00000002 */
#define LPTIM_CR_SNGSTRT LPTIM_CR_SNGSTRT_Msk /*!< Timer start in single mode */
#define LPTIM_CR_CNTSTRT_Pos (2U)
#define LPTIM_CR_CNTSTRT_Msk (0x1UL << LPTIM_CR_CNTSTRT_Pos) /*!< 0x00000004 */
#define LPTIM_CR_CNTSTRT LPTIM_CR_CNTSTRT_Msk /*!< Timer start in continuous mode */
#define LPTIM_CR_COUNTRST_Pos (3U)
#define LPTIM_CR_COUNTRST_Msk (0x1UL << LPTIM_CR_COUNTRST_Pos) /*!< 0x00000008 */
#define LPTIM_CR_COUNTRST LPTIM_CR_COUNTRST_Msk /*!< Counter reset */
#define LPTIM_CR_RSTARE_Pos (4U)
#define LPTIM_CR_RSTARE_Msk (0x1UL << LPTIM_CR_RSTARE_Pos) /*!< 0x00000010 */
#define LPTIM_CR_RSTARE LPTIM_CR_RSTARE_Msk /*!< Reset after read enable */
/****************** Bit definition for LPTIM_CMP register *******************/
#define LPTIM_CMP_CMP_Pos (0U)
#define LPTIM_CMP_CMP_Msk (0xFFFFUL << LPTIM_CMP_CMP_Pos) /*!< 0x0000FFFF */
#define LPTIM_CMP_CMP LPTIM_CMP_CMP_Msk /*!< Compare register */
/****************** Bit definition for LPTIM_ARR register *******************/
#define LPTIM_ARR_ARR_Pos (0U)
#define LPTIM_ARR_ARR_Msk (0xFFFFUL << LPTIM_ARR_ARR_Pos) /*!< 0x0000FFFF */
#define LPTIM_ARR_ARR LPTIM_ARR_ARR_Msk /*!< Auto reload register */
/****************** Bit definition for LPTIM_CNT register *******************/
#define LPTIM_CNT_CNT_Pos (0U)
#define LPTIM_CNT_CNT_Msk (0xFFFFUL << LPTIM_CNT_CNT_Pos) /*!< 0x0000FFFF */
#define LPTIM_CNT_CNT LPTIM_CNT_CNT_Msk /*!< Counter register */
/****************** Bit definition for LPTIM_OR register *******************/
#define LPTIM_OR_IN1_Pos (0U)
#define LPTIM_OR_IN1_Msk (0xDUL << LPTIM_OR_IN1_Pos) /*!< 0x0000000D */
#define LPTIM_OR_IN1 LPTIM_OR_IN1_Msk /*!< IN1[2:0] bits (Remap selection) */
#define LPTIM_OR_IN1_0 (0x1UL << LPTIM_OR_IN1_Pos) /*!< 0x00000001 */
#define LPTIM_OR_IN1_1 (0x4UL << LPTIM_OR_IN1_Pos) /*!< 0x00000004 */
#define LPTIM_OR_IN1_2 (0x8UL << LPTIM_OR_IN1_Pos) /*!< 0x00000008 */
#define LPTIM_OR_IN2_Pos (1U)
#define LPTIM_OR_IN2_Msk (0x19UL << LPTIM_OR_IN2_Pos) /*!< 0x00000032 */
#define LPTIM_OR_IN2 LPTIM_OR_IN2_Msk /*!< IN2[2:0] bits (Remap selection) */
#define LPTIM_OR_IN2_0 (0x1UL << LPTIM_OR_IN2_Pos) /*!< 0x00000002 */
#define LPTIM_OR_IN2_1 (0x8UL << LPTIM_OR_IN2_Pos) /*!< 0x00000010 */
#define LPTIM_OR_IN2_2 (0x10UL << LPTIM_OR_IN2_Pos) /*!< 0x00000020 */
/******************************************************************************/
/* */
/* Universal Synchronous Asynchronous Receiver Transmitter (USART) */
/* */
/******************************************************************************/
/****************** Bit definition for USART_CR1 register *******************/
#define USART_CR1_UE_Pos (0U)
#define USART_CR1_UE_Msk (0x1UL << USART_CR1_UE_Pos) /*!< 0x00000001 */
#define USART_CR1_UE USART_CR1_UE_Msk /*!< USART Enable */
#define USART_CR1_UESM_Pos (1U)
#define USART_CR1_UESM_Msk (0x1UL << USART_CR1_UESM_Pos) /*!< 0x00000002 */
#define USART_CR1_UESM USART_CR1_UESM_Msk /*!< USART Enable in STOP Mode */
#define USART_CR1_RE_Pos (2U)
#define USART_CR1_RE_Msk (0x1UL << USART_CR1_RE_Pos) /*!< 0x00000004 */
#define USART_CR1_RE USART_CR1_RE_Msk /*!< Receiver Enable */
#define USART_CR1_TE_Pos (3U)
#define USART_CR1_TE_Msk (0x1UL << USART_CR1_TE_Pos) /*!< 0x00000008 */
#define USART_CR1_TE USART_CR1_TE_Msk /*!< Transmitter Enable */
#define USART_CR1_IDLEIE_Pos (4U)
#define USART_CR1_IDLEIE_Msk (0x1UL << USART_CR1_IDLEIE_Pos) /*!< 0x00000010 */
#define USART_CR1_IDLEIE USART_CR1_IDLEIE_Msk /*!< IDLE Interrupt Enable */
#define USART_CR1_RXNEIE_Pos (5U)
#define USART_CR1_RXNEIE_Msk (0x1UL << USART_CR1_RXNEIE_Pos) /*!< 0x00000020 */
#define USART_CR1_RXNEIE USART_CR1_RXNEIE_Msk /*!< RXNE Interrupt Enable */
#define USART_CR1_RXNEIE_RXFNEIE_Pos USART_CR1_RXNEIE_Pos
#define USART_CR1_RXNEIE_RXFNEIE_Msk USART_CR1_RXNEIE_Msk /*!< 0x00000020 */
#define USART_CR1_RXNEIE_RXFNEIE USART_CR1_RXNEIE_Msk /*!< RXNE and RX FIFO Not Empty Interrupt Enable */
#define USART_CR1_TCIE_Pos (6U)
#define USART_CR1_TCIE_Msk (0x1UL << USART_CR1_TCIE_Pos) /*!< 0x00000040 */
#define USART_CR1_TCIE USART_CR1_TCIE_Msk /*!< Transmission Complete Interrupt Enable */
#define USART_CR1_TXEIE_Pos (7U)
#define USART_CR1_TXEIE_Msk (0x1UL << USART_CR1_TXEIE_Pos) /*!< 0x00000080 */
#define USART_CR1_TXEIE USART_CR1_TXEIE_Msk /*!< TXE Interrupt Enable */
#define USART_CR1_TXEIE_TXFNFIE_Pos USART_CR1_TXEIE_Pos
#define USART_CR1_TXEIE_TXFNFIE_Msk USART_CR1_TXEIE_Msk /*!< 0x00000080 */
#define USART_CR1_TXEIE_TXFNFIE USART_CR1_TXEIE_Msk /*!< TXE and TX FIFO Not Full Interrupt Enable */
#define USART_CR1_PEIE_Pos (8U)
#define USART_CR1_PEIE_Msk (0x1UL << USART_CR1_PEIE_Pos) /*!< 0x00000100 */
#define USART_CR1_PEIE USART_CR1_PEIE_Msk /*!< PE Interrupt Enable */
#define USART_CR1_PS_Pos (9U)
#define USART_CR1_PS_Msk (0x1UL << USART_CR1_PS_Pos) /*!< 0x00000200 */
#define USART_CR1_PS USART_CR1_PS_Msk /*!< Parity Selection */
#define USART_CR1_PCE_Pos (10U)
#define USART_CR1_PCE_Msk (0x1UL << USART_CR1_PCE_Pos) /*!< 0x00000400 */
#define USART_CR1_PCE USART_CR1_PCE_Msk /*!< Parity Control Enable */
#define USART_CR1_WAKE_Pos (11U)
#define USART_CR1_WAKE_Msk (0x1UL << USART_CR1_WAKE_Pos) /*!< 0x00000800 */
#define USART_CR1_WAKE USART_CR1_WAKE_Msk /*!< Receiver Wakeup method */
#define USART_CR1_M_Pos (12U)
#define USART_CR1_M_Msk (0x10001UL << USART_CR1_M_Pos) /*!< 0x10001000 */
#define USART_CR1_M USART_CR1_M_Msk /*!< Word length */
#define USART_CR1_M0_Pos (12U)
#define USART_CR1_M0_Msk (0x1UL << USART_CR1_M0_Pos) /*!< 0x00001000 */
#define USART_CR1_M0 USART_CR1_M0_Msk /*!< Word length - Bit 0 */
#define USART_CR1_MME_Pos (13U)
#define USART_CR1_MME_Msk (0x1UL << USART_CR1_MME_Pos) /*!< 0x00002000 */
#define USART_CR1_MME USART_CR1_MME_Msk /*!< Mute Mode Enable */
#define USART_CR1_CMIE_Pos (14U)
#define USART_CR1_CMIE_Msk (0x1UL << USART_CR1_CMIE_Pos) /*!< 0x00004000 */
#define USART_CR1_CMIE USART_CR1_CMIE_Msk /*!< Character match interrupt enable */
#define USART_CR1_OVER8_Pos (15U)
#define USART_CR1_OVER8_Msk (0x1UL << USART_CR1_OVER8_Pos) /*!< 0x00008000 */
#define USART_CR1_OVER8 USART_CR1_OVER8_Msk /*!< Oversampling by 8-bit or 16-bit mode */
#define USART_CR1_DEDT_Pos (16U)
#define USART_CR1_DEDT_Msk (0x1FUL << USART_CR1_DEDT_Pos) /*!< 0x001F0000 */
#define USART_CR1_DEDT USART_CR1_DEDT_Msk /*!< DEDT[4:0] bits (Driver Enable Deassertion Time) */
#define USART_CR1_DEDT_0 (0x01UL << USART_CR1_DEDT_Pos) /*!< 0x00010000 */
#define USART_CR1_DEDT_1 (0x02UL << USART_CR1_DEDT_Pos) /*!< 0x00020000 */
#define USART_CR1_DEDT_2 (0x04UL << USART_CR1_DEDT_Pos) /*!< 0x00040000 */
#define USART_CR1_DEDT_3 (0x08UL << USART_CR1_DEDT_Pos) /*!< 0x00080000 */
#define USART_CR1_DEDT_4 (0x10UL << USART_CR1_DEDT_Pos) /*!< 0x00100000 */
#define USART_CR1_DEAT_Pos (21U)
#define USART_CR1_DEAT_Msk (0x1FUL << USART_CR1_DEAT_Pos) /*!< 0x03E00000 */
#define USART_CR1_DEAT USART_CR1_DEAT_Msk /*!< DEAT[4:0] bits (Driver Enable Assertion Time) */
#define USART_CR1_DEAT_0 (0x01UL << USART_CR1_DEAT_Pos) /*!< 0x00200000 */
#define USART_CR1_DEAT_1 (0x02UL << USART_CR1_DEAT_Pos) /*!< 0x00400000 */
#define USART_CR1_DEAT_2 (0x04UL << USART_CR1_DEAT_Pos) /*!< 0x00800000 */
#define USART_CR1_DEAT_3 (0x08UL << USART_CR1_DEAT_Pos) /*!< 0x01000000 */
#define USART_CR1_DEAT_4 (0x10UL << USART_CR1_DEAT_Pos) /*!< 0x02000000 */
#define USART_CR1_RTOIE_Pos (26U)
#define USART_CR1_RTOIE_Msk (0x1UL << USART_CR1_RTOIE_Pos) /*!< 0x04000000 */
#define USART_CR1_RTOIE USART_CR1_RTOIE_Msk /*!< Receive Time Out interrupt enable */
#define USART_CR1_EOBIE_Pos (27U)
#define USART_CR1_EOBIE_Msk (0x1UL << USART_CR1_EOBIE_Pos) /*!< 0x08000000 */
#define USART_CR1_EOBIE USART_CR1_EOBIE_Msk /*!< End of Block interrupt enable */
#define USART_CR1_M1_Pos (28U)
#define USART_CR1_M1_Msk (0x1UL << USART_CR1_M1_Pos) /*!< 0x10000000 */
#define USART_CR1_M1 USART_CR1_M1_Msk /*!< Word length - Bit 1 */
#define USART_CR1_FIFOEN_Pos (29U)
#define USART_CR1_FIFOEN_Msk (0x1UL << USART_CR1_FIFOEN_Pos) /*!< 0x20000000 */
#define USART_CR1_FIFOEN USART_CR1_FIFOEN_Msk /*!< FIFO mode enable */
#define USART_CR1_TXFEIE_Pos (30U)
#define USART_CR1_TXFEIE_Msk (0x1UL << USART_CR1_TXFEIE_Pos) /*!< 0x40000000 */
#define USART_CR1_TXFEIE USART_CR1_TXFEIE_Msk /*!< TXFIFO empty interrupt enable */
#define USART_CR1_RXFFIE_Pos (31U)
#define USART_CR1_RXFFIE_Msk (0x1UL << USART_CR1_RXFFIE_Pos) /*!< 0x80000000 */
#define USART_CR1_RXFFIE USART_CR1_RXFFIE_Msk /*!< RXFIFO Full interrupt enable */
/****************** Bit definition for USART_CR2 register *******************/
#define USART_CR2_SLVEN_Pos (0U)
#define USART_CR2_SLVEN_Msk (0x1UL << USART_CR2_SLVEN_Pos) /*!< 0x00000001 */
#define USART_CR2_SLVEN USART_CR2_SLVEN_Msk /*!< Synchronous Slave mode enable */
#define USART_CR2_DIS_NSS_Pos (3U)
#define USART_CR2_DIS_NSS_Msk (0x1UL << USART_CR2_DIS_NSS_Pos) /*!< 0x00000008 */
#define USART_CR2_DIS_NSS USART_CR2_DIS_NSS_Msk /*!< Slave Select (NSS) pin management */
#define USART_CR2_ADDM7_Pos (4U)
#define USART_CR2_ADDM7_Msk (0x1UL << USART_CR2_ADDM7_Pos) /*!< 0x00000010 */
#define USART_CR2_ADDM7 USART_CR2_ADDM7_Msk /*!< 7-bit or 4-bit Address Detection */
#define USART_CR2_LBDL_Pos (5U)
#define USART_CR2_LBDL_Msk (0x1UL << USART_CR2_LBDL_Pos) /*!< 0x00000020 */
#define USART_CR2_LBDL USART_CR2_LBDL_Msk /*!< LIN Break Detection Length */
#define USART_CR2_LBDIE_Pos (6U)
#define USART_CR2_LBDIE_Msk (0x1UL << USART_CR2_LBDIE_Pos) /*!< 0x00000040 */
#define USART_CR2_LBDIE USART_CR2_LBDIE_Msk /*!< LIN Break Detection Interrupt Enable */
#define USART_CR2_LBCL_Pos (8U)
#define USART_CR2_LBCL_Msk (0x1UL << USART_CR2_LBCL_Pos) /*!< 0x00000100 */
#define USART_CR2_LBCL USART_CR2_LBCL_Msk /*!< Last Bit Clock pulse */
#define USART_CR2_CPHA_Pos (9U)
#define USART_CR2_CPHA_Msk (0x1UL << USART_CR2_CPHA_Pos) /*!< 0x00000200 */
#define USART_CR2_CPHA USART_CR2_CPHA_Msk /*!< Clock Phase */
#define USART_CR2_CPOL_Pos (10U)
#define USART_CR2_CPOL_Msk (0x1UL << USART_CR2_CPOL_Pos) /*!< 0x00000400 */
#define USART_CR2_CPOL USART_CR2_CPOL_Msk /*!< Clock Polarity */
#define USART_CR2_CLKEN_Pos (11U)
#define USART_CR2_CLKEN_Msk (0x1UL << USART_CR2_CLKEN_Pos) /*!< 0x00000800 */
#define USART_CR2_CLKEN USART_CR2_CLKEN_Msk /*!< Clock Enable */
#define USART_CR2_STOP_Pos (12U)
#define USART_CR2_STOP_Msk (0x3UL << USART_CR2_STOP_Pos) /*!< 0x00003000 */
#define USART_CR2_STOP USART_CR2_STOP_Msk /*!< STOP[1:0] bits (STOP bits) */
#define USART_CR2_STOP_0 (0x1UL << USART_CR2_STOP_Pos) /*!< 0x00001000 */
#define USART_CR2_STOP_1 (0x2UL << USART_CR2_STOP_Pos) /*!< 0x00002000 */
#define USART_CR2_LINEN_Pos (14U)
#define USART_CR2_LINEN_Msk (0x1UL << USART_CR2_LINEN_Pos) /*!< 0x00004000 */
#define USART_CR2_LINEN USART_CR2_LINEN_Msk /*!< LIN mode enable */
#define USART_CR2_SWAP_Pos (15U)
#define USART_CR2_SWAP_Msk (0x1UL << USART_CR2_SWAP_Pos) /*!< 0x00008000 */
#define USART_CR2_SWAP USART_CR2_SWAP_Msk /*!< SWAP TX/RX pins */
#define USART_CR2_RXINV_Pos (16U)
#define USART_CR2_RXINV_Msk (0x1UL << USART_CR2_RXINV_Pos) /*!< 0x00010000 */
#define USART_CR2_RXINV USART_CR2_RXINV_Msk /*!< RX pin active level inversion */
#define USART_CR2_TXINV_Pos (17U)
#define USART_CR2_TXINV_Msk (0x1UL << USART_CR2_TXINV_Pos) /*!< 0x00020000 */
#define USART_CR2_TXINV USART_CR2_TXINV_Msk /*!< TX pin active level inversion */
#define USART_CR2_DATAINV_Pos (18U)
#define USART_CR2_DATAINV_Msk (0x1UL << USART_CR2_DATAINV_Pos) /*!< 0x00040000 */
#define USART_CR2_DATAINV USART_CR2_DATAINV_Msk /*!< Binary data inversion */
#define USART_CR2_MSBFIRST_Pos (19U)
#define USART_CR2_MSBFIRST_Msk (0x1UL << USART_CR2_MSBFIRST_Pos) /*!< 0x00080000 */
#define USART_CR2_MSBFIRST USART_CR2_MSBFIRST_Msk /*!< Most Significant Bit First */
#define USART_CR2_ABREN_Pos (20U)
#define USART_CR2_ABREN_Msk (0x1UL << USART_CR2_ABREN_Pos) /*!< 0x00100000 */
#define USART_CR2_ABREN USART_CR2_ABREN_Msk /*!< Auto Baud-Rate Enable*/
#define USART_CR2_ABRMODE_Pos (21U)
#define USART_CR2_ABRMODE_Msk (0x3UL << USART_CR2_ABRMODE_Pos) /*!< 0x00600000 */
#define USART_CR2_ABRMODE USART_CR2_ABRMODE_Msk /*!< ABRMOD[1:0] bits (Auto Baud-Rate Mode) */
#define USART_CR2_ABRMODE_0 (0x1UL << USART_CR2_ABRMODE_Pos) /*!< 0x00200000 */
#define USART_CR2_ABRMODE_1 (0x2UL << USART_CR2_ABRMODE_Pos) /*!< 0x00400000 */
#define USART_CR2_RTOEN_Pos (23U)
#define USART_CR2_RTOEN_Msk (0x1UL << USART_CR2_RTOEN_Pos) /*!< 0x00800000 */
#define USART_CR2_RTOEN USART_CR2_RTOEN_Msk /*!< Receiver Time-Out enable */
#define USART_CR2_ADD_Pos (24U)
#define USART_CR2_ADD_Msk (0xFFUL << USART_CR2_ADD_Pos) /*!< 0xFF000000 */
#define USART_CR2_ADD USART_CR2_ADD_Msk /*!< Address of the USART node */
/****************** Bit definition for USART_CR3 register *******************/
#define USART_CR3_EIE_Pos (0U)
#define USART_CR3_EIE_Msk (0x1UL << USART_CR3_EIE_Pos) /*!< 0x00000001 */
#define USART_CR3_EIE USART_CR3_EIE_Msk /*!< Error Interrupt Enable */
#define USART_CR3_IREN_Pos (1U)
#define USART_CR3_IREN_Msk (0x1UL << USART_CR3_IREN_Pos) /*!< 0x00000002 */
#define USART_CR3_IREN USART_CR3_IREN_Msk /*!< IrDA mode Enable */
#define USART_CR3_IRLP_Pos (2U)
#define USART_CR3_IRLP_Msk (0x1UL << USART_CR3_IRLP_Pos) /*!< 0x00000004 */
#define USART_CR3_IRLP USART_CR3_IRLP_Msk /*!< IrDA Low-Power */
#define USART_CR3_HDSEL_Pos (3U)
#define USART_CR3_HDSEL_Msk (0x1UL << USART_CR3_HDSEL_Pos) /*!< 0x00000008 */
#define USART_CR3_HDSEL USART_CR3_HDSEL_Msk /*!< Half-Duplex Selection */
#define USART_CR3_NACK_Pos (4U)
#define USART_CR3_NACK_Msk (0x1UL << USART_CR3_NACK_Pos) /*!< 0x00000010 */
#define USART_CR3_NACK USART_CR3_NACK_Msk /*!< SmartCard NACK enable */
#define USART_CR3_SCEN_Pos (5U)
#define USART_CR3_SCEN_Msk (0x1UL << USART_CR3_SCEN_Pos) /*!< 0x00000020 */
#define USART_CR3_SCEN USART_CR3_SCEN_Msk /*!< SmartCard mode enable */
#define USART_CR3_DMAR_Pos (6U)
#define USART_CR3_DMAR_Msk (0x1UL << USART_CR3_DMAR_Pos) /*!< 0x00000040 */
#define USART_CR3_DMAR USART_CR3_DMAR_Msk /*!< DMA Enable Receiver */
#define USART_CR3_DMAT_Pos (7U)
#define USART_CR3_DMAT_Msk (0x1UL << USART_CR3_DMAT_Pos) /*!< 0x00000080 */
#define USART_CR3_DMAT USART_CR3_DMAT_Msk /*!< DMA Enable Transmitter */
#define USART_CR3_RTSE_Pos (8U)
#define USART_CR3_RTSE_Msk (0x1UL << USART_CR3_RTSE_Pos) /*!< 0x00000100 */
#define USART_CR3_RTSE USART_CR3_RTSE_Msk /*!< RTS Enable */
#define USART_CR3_CTSE_Pos (9U)
#define USART_CR3_CTSE_Msk (0x1UL << USART_CR3_CTSE_Pos) /*!< 0x00000200 */
#define USART_CR3_CTSE USART_CR3_CTSE_Msk /*!< CTS Enable */
#define USART_CR3_CTSIE_Pos (10U)
#define USART_CR3_CTSIE_Msk (0x1UL << USART_CR3_CTSIE_Pos) /*!< 0x00000400 */
#define USART_CR3_CTSIE USART_CR3_CTSIE_Msk /*!< CTS Interrupt Enable */
#define USART_CR3_ONEBIT_Pos (11U)
#define USART_CR3_ONEBIT_Msk (0x1UL << USART_CR3_ONEBIT_Pos) /*!< 0x00000800 */
#define USART_CR3_ONEBIT USART_CR3_ONEBIT_Msk /*!< One sample bit method enable */
#define USART_CR3_OVRDIS_Pos (12U)
#define USART_CR3_OVRDIS_Msk (0x1UL << USART_CR3_OVRDIS_Pos) /*!< 0x00001000 */
#define USART_CR3_OVRDIS USART_CR3_OVRDIS_Msk /*!< Overrun Disable */
#define USART_CR3_DDRE_Pos (13U)
#define USART_CR3_DDRE_Msk (0x1UL << USART_CR3_DDRE_Pos) /*!< 0x00002000 */
#define USART_CR3_DDRE USART_CR3_DDRE_Msk /*!< DMA Disable on Reception Error */
#define USART_CR3_DEM_Pos (14U)
#define USART_CR3_DEM_Msk (0x1UL << USART_CR3_DEM_Pos) /*!< 0x00004000 */
#define USART_CR3_DEM USART_CR3_DEM_Msk /*!< Driver Enable Mode */
#define USART_CR3_DEP_Pos (15U)
#define USART_CR3_DEP_Msk (0x1UL << USART_CR3_DEP_Pos) /*!< 0x00008000 */
#define USART_CR3_DEP USART_CR3_DEP_Msk /*!< Driver Enable Polarity Selection */
#define USART_CR3_SCARCNT_Pos (17U)
#define USART_CR3_SCARCNT_Msk (0x7UL << USART_CR3_SCARCNT_Pos) /*!< 0x000E0000 */
#define USART_CR3_SCARCNT USART_CR3_SCARCNT_Msk /*!< SCARCNT[2:0] bits (SmartCard Auto-Retry Count) */
#define USART_CR3_SCARCNT_0 (0x1UL << USART_CR3_SCARCNT_Pos) /*!< 0x00020000 */
#define USART_CR3_SCARCNT_1 (0x2UL << USART_CR3_SCARCNT_Pos) /*!< 0x00040000 */
#define USART_CR3_SCARCNT_2 (0x4UL << USART_CR3_SCARCNT_Pos) /*!< 0x00080000 */
#define USART_CR3_WUS_Pos (20U)
#define USART_CR3_WUS_Msk (0x3UL << USART_CR3_WUS_Pos) /*!< 0x00300000 */
#define USART_CR3_WUS USART_CR3_WUS_Msk /*!< WUS[1:0] bits (Wake UP Interrupt Flag Selection) */
#define USART_CR3_WUS_0 (0x1UL << USART_CR3_WUS_Pos) /*!< 0x00100000 */
#define USART_CR3_WUS_1 (0x2UL << USART_CR3_WUS_Pos) /*!< 0x00200000 */
#define USART_CR3_WUFIE_Pos (22U)
#define USART_CR3_WUFIE_Msk (0x1UL << USART_CR3_WUFIE_Pos) /*!< 0x00400000 */
#define USART_CR3_WUFIE USART_CR3_WUFIE_Msk /*!< Wake Up Interrupt Enable */
#define USART_CR3_TXFTIE_Pos (23U)
#define USART_CR3_TXFTIE_Msk (0x1UL << USART_CR3_TXFTIE_Pos) /*!< 0x00800000 */
#define USART_CR3_TXFTIE USART_CR3_TXFTIE_Msk /*!< TXFIFO threshold interrupt enable */
#define USART_CR3_TCBGTIE_Pos (24U)
#define USART_CR3_TCBGTIE_Msk (0x1UL << USART_CR3_TCBGTIE_Pos) /*!< 0x01000000 */
#define USART_CR3_TCBGTIE USART_CR3_TCBGTIE_Msk /*!< Transmission Complete Before Guard Time Interrupt Enable */
#define USART_CR3_RXFTCFG_Pos (25U)
#define USART_CR3_RXFTCFG_Msk (0x7UL << USART_CR3_RXFTCFG_Pos) /*!< 0x0E000000 */
#define USART_CR3_RXFTCFG USART_CR3_RXFTCFG_Msk /*!< RXFIFO FIFO threshold configuration */
#define USART_CR3_RXFTCFG_0 (0x1UL << USART_CR3_RXFTCFG_Pos) /*!< 0x02000000 */
#define USART_CR3_RXFTCFG_1 (0x2UL << USART_CR3_RXFTCFG_Pos) /*!< 0x04000000 */
#define USART_CR3_RXFTCFG_2 (0x4UL << USART_CR3_RXFTCFG_Pos) /*!< 0x08000000 */
#define USART_CR3_RXFTIE_Pos (28U)
#define USART_CR3_RXFTIE_Msk (0x1UL << USART_CR3_RXFTIE_Pos) /*!< 0x10000000 */
#define USART_CR3_RXFTIE USART_CR3_RXFTIE_Msk /*!< RXFIFO threshold interrupt enable */
#define USART_CR3_TXFTCFG_Pos (29U)
#define USART_CR3_TXFTCFG_Msk (0x7UL << USART_CR3_TXFTCFG_Pos) /*!< 0xE0000000 */
#define USART_CR3_TXFTCFG USART_CR3_TXFTCFG_Msk /*!< TXFIFO threshold configuration */
#define USART_CR3_TXFTCFG_0 (0x1UL << USART_CR3_TXFTCFG_Pos) /*!< 0x20000000 */
#define USART_CR3_TXFTCFG_1 (0x2UL << USART_CR3_TXFTCFG_Pos) /*!< 0x40000000 */
#define USART_CR3_TXFTCFG_2 (0x4UL << USART_CR3_TXFTCFG_Pos) /*!< 0x80000000 */
/****************** Bit definition for USART_BRR register *******************/
#define USART_BRR_LPUART_Pos (0U)
#define USART_BRR_LPUART_Msk (0xFFFFFUL << USART_BRR_LPUART_Pos) /*!< 0x000FFFFF */
#define USART_BRR_LPUART USART_BRR_LPUART_Msk /*!< LPUART Baud rate register [19:0] */
#define USART_BRR_BRR_Pos (0U)
#define USART_BRR_BRR_Msk (0xFFFFUL << USART_BRR_BRR_Pos) /*!< 0x0000FFFF */
#define USART_BRR_BRR USART_BRR_BRR_Msk /*!< USART Baud rate register [15:0] */
/****************** Bit definition for USART_GTPR register ******************/
#define USART_GTPR_PSC_Pos (0U)
#define USART_GTPR_PSC_Msk (0xFFUL << USART_GTPR_PSC_Pos) /*!< 0x000000FF */
#define USART_GTPR_PSC USART_GTPR_PSC_Msk /*!< PSC[7:0] bits (Prescaler value) */
#define USART_GTPR_GT_Pos (8U)
#define USART_GTPR_GT_Msk (0xFFUL << USART_GTPR_GT_Pos) /*!< 0x0000FF00 */
#define USART_GTPR_GT USART_GTPR_GT_Msk /*!< GT[7:0] bits (Guard time value) */
/******************* Bit definition for USART_RTOR register *****************/
#define USART_RTOR_RTO_Pos (0U)
#define USART_RTOR_RTO_Msk (0xFFFFFFUL << USART_RTOR_RTO_Pos) /*!< 0x00FFFFFF */
#define USART_RTOR_RTO USART_RTOR_RTO_Msk /*!< Receiver Time Out Value */
#define USART_RTOR_BLEN_Pos (24U)
#define USART_RTOR_BLEN_Msk (0xFFUL << USART_RTOR_BLEN_Pos) /*!< 0xFF000000 */
#define USART_RTOR_BLEN USART_RTOR_BLEN_Msk /*!< Block Length */
/******************* Bit definition for USART_RQR register ******************/
#define USART_RQR_ABRRQ_Pos (0U)
#define USART_RQR_ABRRQ_Msk (0x1UL << USART_RQR_ABRRQ_Pos) /*!< 0x00000001 */
#define USART_RQR_ABRRQ USART_RQR_ABRRQ_Msk /*!< Auto-Baud Rate Request */
#define USART_RQR_SBKRQ_Pos (1U)
#define USART_RQR_SBKRQ_Msk (0x1UL << USART_RQR_SBKRQ_Pos) /*!< 0x00000002 */
#define USART_RQR_SBKRQ USART_RQR_SBKRQ_Msk /*!< Send Break Request */
#define USART_RQR_MMRQ_Pos (2U)
#define USART_RQR_MMRQ_Msk (0x1UL << USART_RQR_MMRQ_Pos) /*!< 0x00000004 */
#define USART_RQR_MMRQ USART_RQR_MMRQ_Msk /*!< Mute Mode Request */
#define USART_RQR_RXFRQ_Pos (3U)
#define USART_RQR_RXFRQ_Msk (0x1UL << USART_RQR_RXFRQ_Pos) /*!< 0x00000008 */
#define USART_RQR_RXFRQ USART_RQR_RXFRQ_Msk /*!< Receive Data flush Request */
#define USART_RQR_TXFRQ_Pos (4U)
#define USART_RQR_TXFRQ_Msk (0x1UL << USART_RQR_TXFRQ_Pos) /*!< 0x00000010 */
#define USART_RQR_TXFRQ USART_RQR_TXFRQ_Msk /*!< Transmit data flush Request */
/******************* Bit definition for USART_ISR register ******************/
#define USART_ISR_PE_Pos (0U)
#define USART_ISR_PE_Msk (0x1UL << USART_ISR_PE_Pos) /*!< 0x00000001 */
#define USART_ISR_PE USART_ISR_PE_Msk /*!< Parity Error */
#define USART_ISR_FE_Pos (1U)
#define USART_ISR_FE_Msk (0x1UL << USART_ISR_FE_Pos) /*!< 0x00000002 */
#define USART_ISR_FE USART_ISR_FE_Msk /*!< Framing Error */
#define USART_ISR_NE_Pos (2U)
#define USART_ISR_NE_Msk (0x1UL << USART_ISR_NE_Pos) /*!< 0x00000004 */
#define USART_ISR_NE USART_ISR_NE_Msk /*!< Noise detected Flag */
#define USART_ISR_ORE_Pos (3U)
#define USART_ISR_ORE_Msk (0x1UL << USART_ISR_ORE_Pos) /*!< 0x00000008 */
#define USART_ISR_ORE USART_ISR_ORE_Msk /*!< OverRun Error */
#define USART_ISR_IDLE_Pos (4U)
#define USART_ISR_IDLE_Msk (0x1UL << USART_ISR_IDLE_Pos) /*!< 0x00000010 */
#define USART_ISR_IDLE USART_ISR_IDLE_Msk /*!< IDLE line detected */
#define USART_ISR_RXNE_Pos (5U)
#define USART_ISR_RXNE_Msk (0x1UL << USART_ISR_RXNE_Pos) /*!< 0x00000020 */
#define USART_ISR_RXNE USART_ISR_RXNE_Msk /*!< Read Data Register Not Empty */
#define USART_ISR_RXNE_RXFNE_Pos USART_ISR_RXNE_Pos
#define USART_ISR_RXNE_RXFNE_Msk USART_ISR_RXNE_Msk /*!< 0x00000020 */
#define USART_ISR_RXNE_RXFNE USART_ISR_RXNE_Msk /*!< Read Data Register or RX FIFO Not Empty */
#define USART_ISR_TC_Pos (6U)
#define USART_ISR_TC_Msk (0x1UL << USART_ISR_TC_Pos) /*!< 0x00000040 */
#define USART_ISR_TC USART_ISR_TC_Msk /*!< Transmission Complete */
#define USART_ISR_TXE_Pos (7U)
#define USART_ISR_TXE_Msk (0x1UL << USART_ISR_TXE_Pos) /*!< 0x00000080 */
#define USART_ISR_TXE USART_ISR_TXE_Msk /*!< Transmit Data Register Empty */
#define USART_ISR_TXE_TXFNF_Pos USART_ISR_TXE_Pos
#define USART_ISR_TXE_TXFNF_Msk USART_ISR_TXE_Msk /*!< 0x00000080 */
#define USART_ISR_TXE_TXFNF USART_ISR_TXE_Msk /*!< Transmit Data Register Empty or TX FIFO Not Full Flag */
#define USART_ISR_LBDF_Pos (8U)
#define USART_ISR_LBDF_Msk (0x1UL << USART_ISR_LBDF_Pos) /*!< 0x00000100 */
#define USART_ISR_LBDF USART_ISR_LBDF_Msk /*!< LIN Break Detection Flag */
#define USART_ISR_CTSIF_Pos (9U)
#define USART_ISR_CTSIF_Msk (0x1UL << USART_ISR_CTSIF_Pos) /*!< 0x00000200 */
#define USART_ISR_CTSIF USART_ISR_CTSIF_Msk /*!< CTS interrupt flag */
#define USART_ISR_CTS_Pos (10U)
#define USART_ISR_CTS_Msk (0x1UL << USART_ISR_CTS_Pos) /*!< 0x00000400 */
#define USART_ISR_CTS USART_ISR_CTS_Msk /*!< CTS flag */
#define USART_ISR_RTOF_Pos (11U)
#define USART_ISR_RTOF_Msk (0x1UL << USART_ISR_RTOF_Pos) /*!< 0x00000800 */
#define USART_ISR_RTOF USART_ISR_RTOF_Msk /*!< Receiver Time Out */
#define USART_ISR_EOBF_Pos (12U)
#define USART_ISR_EOBF_Msk (0x1UL << USART_ISR_EOBF_Pos) /*!< 0x00001000 */
#define USART_ISR_EOBF USART_ISR_EOBF_Msk /*!< End Of Block Flag */
#define USART_ISR_UDR_Pos (13U)
#define USART_ISR_UDR_Msk (0x1UL << USART_ISR_UDR_Pos) /*!< 0x00002000 */
#define USART_ISR_UDR USART_ISR_UDR_Msk /*!< SPI slave underrun error flag */
#define USART_ISR_ABRE_Pos (14U)
#define USART_ISR_ABRE_Msk (0x1UL << USART_ISR_ABRE_Pos) /*!< 0x00004000 */
#define USART_ISR_ABRE USART_ISR_ABRE_Msk /*!< Auto-Baud Rate Error */
#define USART_ISR_ABRF_Pos (15U)
#define USART_ISR_ABRF_Msk (0x1UL << USART_ISR_ABRF_Pos) /*!< 0x00008000 */
#define USART_ISR_ABRF USART_ISR_ABRF_Msk /*!< Auto-Baud Rate Flag */
#define USART_ISR_BUSY_Pos (16U)
#define USART_ISR_BUSY_Msk (0x1UL << USART_ISR_BUSY_Pos) /*!< 0x00010000 */
#define USART_ISR_BUSY USART_ISR_BUSY_Msk /*!< Busy Flag */
#define USART_ISR_CMF_Pos (17U)
#define USART_ISR_CMF_Msk (0x1UL << USART_ISR_CMF_Pos) /*!< 0x00020000 */
#define USART_ISR_CMF USART_ISR_CMF_Msk /*!< Character Match Flag */
#define USART_ISR_SBKF_Pos (18U)
#define USART_ISR_SBKF_Msk (0x1UL << USART_ISR_SBKF_Pos) /*!< 0x00040000 */
#define USART_ISR_SBKF USART_ISR_SBKF_Msk /*!< Send Break Flag */
#define USART_ISR_RWU_Pos (19U)
#define USART_ISR_RWU_Msk (0x1UL << USART_ISR_RWU_Pos) /*!< 0x00080000 */
#define USART_ISR_RWU USART_ISR_RWU_Msk /*!< Receive Wake Up from mute mode Flag */
#define USART_ISR_WUF_Pos (20U)
#define USART_ISR_WUF_Msk (0x1UL << USART_ISR_WUF_Pos) /*!< 0x00100000 */
#define USART_ISR_WUF USART_ISR_WUF_Msk /*!< Wake Up from stop mode Flag */
#define USART_ISR_TEACK_Pos (21U)
#define USART_ISR_TEACK_Msk (0x1UL << USART_ISR_TEACK_Pos) /*!< 0x00200000 */
#define USART_ISR_TEACK USART_ISR_TEACK_Msk /*!< Transmit Enable Acknowledge Flag */
#define USART_ISR_REACK_Pos (22U)
#define USART_ISR_REACK_Msk (0x1UL << USART_ISR_REACK_Pos) /*!< 0x00400000 */
#define USART_ISR_REACK USART_ISR_REACK_Msk /*!< Receive Enable Acknowledge Flag */
#define USART_ISR_TXFE_Pos (23U)
#define USART_ISR_TXFE_Msk (0x1UL << USART_ISR_TXFE_Pos) /*!< 0x00800000 */
#define USART_ISR_TXFE USART_ISR_TXFE_Msk /*!< TXFIFO Empty */
#define USART_ISR_RXFF_Pos (24U)
#define USART_ISR_RXFF_Msk (0x1UL << USART_ISR_RXFF_Pos) /*!< 0x01000000 */
#define USART_ISR_RXFF USART_ISR_RXFF_Msk /*!< RXFIFO Full */
#define USART_ISR_TCBGT_Pos (25U)
#define USART_ISR_TCBGT_Msk (0x1UL << USART_ISR_TCBGT_Pos) /*!< 0x02000000 */
#define USART_ISR_TCBGT USART_ISR_TCBGT_Msk /*!< Transmission Complete Before Guard Time completion */
#define USART_ISR_RXFT_Pos (26U)
#define USART_ISR_RXFT_Msk (0x1UL << USART_ISR_RXFT_Pos) /*!< 0x04000000 */
#define USART_ISR_RXFT USART_ISR_RXFT_Msk /*!< RXFIFO threshold flag */
#define USART_ISR_TXFT_Pos (27U)
#define USART_ISR_TXFT_Msk (0x1UL << USART_ISR_TXFT_Pos) /*!< 0x08000000 */
#define USART_ISR_TXFT USART_ISR_TXFT_Msk /*!< TXFIFO threshold flag */
/******************* Bit definition for USART_ICR register ******************/
#define USART_ICR_PECF_Pos (0U)
#define USART_ICR_PECF_Msk (0x1UL << USART_ICR_PECF_Pos) /*!< 0x00000001 */
#define USART_ICR_PECF USART_ICR_PECF_Msk /*!< Parity Error Clear Flag */
#define USART_ICR_FECF_Pos (1U)
#define USART_ICR_FECF_Msk (0x1UL << USART_ICR_FECF_Pos) /*!< 0x00000002 */
#define USART_ICR_FECF USART_ICR_FECF_Msk /*!< Framing Error Clear Flag */
#define USART_ICR_NECF_Pos (2U)
#define USART_ICR_NECF_Msk (0x1UL << USART_ICR_NECF_Pos) /*!< 0x00000004 */
#define USART_ICR_NECF USART_ICR_NECF_Msk /*!< Noise detected Clear Flag */
#define USART_ICR_ORECF_Pos (3U)
#define USART_ICR_ORECF_Msk (0x1UL << USART_ICR_ORECF_Pos) /*!< 0x00000008 */
#define USART_ICR_ORECF USART_ICR_ORECF_Msk /*!< OverRun Error Clear Flag */
#define USART_ICR_IDLECF_Pos (4U)
#define USART_ICR_IDLECF_Msk (0x1UL << USART_ICR_IDLECF_Pos) /*!< 0x00000010 */
#define USART_ICR_IDLECF USART_ICR_IDLECF_Msk /*!< IDLE line detected Clear Flag */
#define USART_ICR_TXFECF_Pos (5U)
#define USART_ICR_TXFECF_Msk (0x1UL << USART_ICR_TXFECF_Pos) /*!< 0x00000020 */
#define USART_ICR_TXFECF USART_ICR_TXFECF_Msk /*!< TXFIFO empty Clear flag */
#define USART_ICR_TCCF_Pos (6U)
#define USART_ICR_TCCF_Msk (0x1UL << USART_ICR_TCCF_Pos) /*!< 0x00000040 */
#define USART_ICR_TCCF USART_ICR_TCCF_Msk /*!< Transmission Complete Clear Flag */
#define USART_ICR_TCBGTCF_Pos (7U)
#define USART_ICR_TCBGTCF_Msk (0x1UL << USART_ICR_TCBGTCF_Pos) /*!< 0x00000080 */
#define USART_ICR_TCBGTCF USART_ICR_TCBGTCF_Msk /*!< Transmission Complete Before Guard Time Clear Flag */
#define USART_ICR_LBDCF_Pos (8U)
#define USART_ICR_LBDCF_Msk (0x1UL << USART_ICR_LBDCF_Pos) /*!< 0x00000100 */
#define USART_ICR_LBDCF USART_ICR_LBDCF_Msk /*!< LIN Break Detection Clear Flag */
#define USART_ICR_CTSCF_Pos (9U)
#define USART_ICR_CTSCF_Msk (0x1UL << USART_ICR_CTSCF_Pos) /*!< 0x00000200 */
#define USART_ICR_CTSCF USART_ICR_CTSCF_Msk /*!< CTS Interrupt Clear Flag */
#define USART_ICR_RTOCF_Pos (11U)
#define USART_ICR_RTOCF_Msk (0x1UL << USART_ICR_RTOCF_Pos) /*!< 0x00000800 */
#define USART_ICR_RTOCF USART_ICR_RTOCF_Msk /*!< Receiver Time Out Clear Flag */
#define USART_ICR_EOBCF_Pos (12U)
#define USART_ICR_EOBCF_Msk (0x1UL << USART_ICR_EOBCF_Pos) /*!< 0x00001000 */
#define USART_ICR_EOBCF USART_ICR_EOBCF_Msk /*!< End Of Block Clear Flag */
#define USART_ICR_UDRCF_Pos (13U)
#define USART_ICR_UDRCF_Msk (0x1UL << USART_ICR_UDRCF_Pos) /*!< 0x00002000 */
#define USART_ICR_UDRCF USART_ICR_UDRCF_Msk /*!< SPI Slave Underrun Clear Flag */
#define USART_ICR_CMCF_Pos (17U)
#define USART_ICR_CMCF_Msk (0x1UL << USART_ICR_CMCF_Pos) /*!< 0x00020000 */
#define USART_ICR_CMCF USART_ICR_CMCF_Msk /*!< Character Match Clear Flag */
#define USART_ICR_WUCF_Pos (20U)
#define USART_ICR_WUCF_Msk (0x1UL << USART_ICR_WUCF_Pos) /*!< 0x00100000 */
#define USART_ICR_WUCF USART_ICR_WUCF_Msk /*!< Wake Up from stop mode Clear Flag */
/******************* Bit definition for USART_RDR register ******************/
#define USART_RDR_RDR_Pos (0U)
#define USART_RDR_RDR_Msk (0x1FFUL << USART_RDR_RDR_Pos) /*!< 0x000001FF */
#define USART_RDR_RDR USART_RDR_RDR_Msk /*!< RDR[8:0] bits (Receive Data value) */
/******************* Bit definition for USART_TDR register ******************/
#define USART_TDR_TDR_Pos (0U)
#define USART_TDR_TDR_Msk (0x1FFUL << USART_TDR_TDR_Pos) /*!< 0x000001FF */
#define USART_TDR_TDR USART_TDR_TDR_Msk /*!< TDR[8:0] bits (Transmit Data value) */
/******************* Bit definition for USART_PRESC register ****************/
#define USART_PRESC_PRESCALER_Pos (0U)
#define USART_PRESC_PRESCALER_Msk (0xFUL << USART_PRESC_PRESCALER_Pos) /*!< 0x0000000F */
#define USART_PRESC_PRESCALER USART_PRESC_PRESCALER_Msk /*!< PRESCALER[3:0] bits (Clock prescaler) */
#define USART_PRESC_PRESCALER_0 (0x1UL << USART_PRESC_PRESCALER_Pos) /*!< 0x00000001 */
#define USART_PRESC_PRESCALER_1 (0x2UL << USART_PRESC_PRESCALER_Pos) /*!< 0x00000002 */
#define USART_PRESC_PRESCALER_2 (0x4UL << USART_PRESC_PRESCALER_Pos) /*!< 0x00000004 */
#define USART_PRESC_PRESCALER_3 (0x8UL << USART_PRESC_PRESCALER_Pos) /*!< 0x00000008 */
/******************************************************************************/
/* */
/* VREFBUF */
/* */
/******************************************************************************/
/******************* Bit definition for VREFBUF_CSR register ****************/
#define VREFBUF_CSR_ENVR_Pos (0U)
#define VREFBUF_CSR_ENVR_Msk (0x1UL << VREFBUF_CSR_ENVR_Pos) /*!< 0x00000001 */
#define VREFBUF_CSR_ENVR VREFBUF_CSR_ENVR_Msk /*!<Voltage reference buffer enable */
#define VREFBUF_CSR_HIZ_Pos (1U)
#define VREFBUF_CSR_HIZ_Msk (0x1UL << VREFBUF_CSR_HIZ_Pos) /*!< 0x00000002 */
#define VREFBUF_CSR_HIZ VREFBUF_CSR_HIZ_Msk /*!<High impedance mode */
#define VREFBUF_CSR_VRR_Pos (3U)
#define VREFBUF_CSR_VRR_Msk (0x1UL << VREFBUF_CSR_VRR_Pos) /*!< 0x00000008 */
#define VREFBUF_CSR_VRR VREFBUF_CSR_VRR_Msk /*!<Voltage reference buffer ready */
#define VREFBUF_CSR_VRS_Pos (4U)
#define VREFBUF_CSR_VRS_Msk (0x3UL << VREFBUF_CSR_VRS_Pos) /*!< 0x00000030 */
#define VREFBUF_CSR_VRS VREFBUF_CSR_VRS_Msk /*!<VRS[5:0] bits (Voltage reference scale) */
#define VREFBUF_CSR_VRS_0 (0x1UL << VREFBUF_CSR_VRS_Pos) /*!< 0x00000010 */
#define VREFBUF_CSR_VRS_1 (0x2UL << VREFBUF_CSR_VRS_Pos) /*!< 0x00000020 */
/******************* Bit definition for VREFBUF_CCR register ******************/
#define VREFBUF_CCR_TRIM_Pos (0U)
#define VREFBUF_CCR_TRIM_Msk (0x3FUL << VREFBUF_CCR_TRIM_Pos) /*!< 0x0000003F */
#define VREFBUF_CCR_TRIM VREFBUF_CCR_TRIM_Msk /*!<TRIM[5:0] bits (Trimming code) */
/******************************************************************************/
/* */
/* USB Device FS Endpoint registers */
/* */
/******************************************************************************/
#define USB_EP0R USB_BASE /*!< endpoint 0 register address */
#define USB_EP1R (USB_BASE + 0x0x00000004) /*!< endpoint 1 register address */
#define USB_EP2R (USB_BASE + 0x0x00000008) /*!< endpoint 2 register address */
#define USB_EP3R (USB_BASE + 0x0x0000000C) /*!< endpoint 3 register address */
#define USB_EP4R (USB_BASE + 0x0x00000010) /*!< endpoint 4 register address */
#define USB_EP5R (USB_BASE + 0x0x00000014) /*!< endpoint 5 register address */
#define USB_EP6R (USB_BASE + 0x0x00000018) /*!< endpoint 6 register address */
#define USB_EP7R (USB_BASE + 0x0x0000001C) /*!< endpoint 7 register address */
/* bit positions */
#define USB_EP_CTR_RX ((uint16_t)0x8000U) /*!< EndPoint Correct TRansfer RX */
#define USB_EP_DTOG_RX ((uint16_t)0x4000U) /*!< EndPoint Data TOGGLE RX */
#define USB_EPRX_STAT ((uint16_t)0x3000U) /*!< EndPoint RX STATus bit field */
#define USB_EP_SETUP ((uint16_t)0x0800U) /*!< EndPoint SETUP */
#define USB_EP_T_FIELD ((uint16_t)0x0600U) /*!< EndPoint TYPE */
#define USB_EP_KIND ((uint16_t)0x0100U) /*!< EndPoint KIND */
#define USB_EP_CTR_TX ((uint16_t)0x0080U) /*!< EndPoint Correct TRansfer TX */
#define USB_EP_DTOG_TX ((uint16_t)0x0040U) /*!< EndPoint Data TOGGLE TX */
#define USB_EPTX_STAT ((uint16_t)0x0030U) /*!< EndPoint TX STATus bit field */
#define USB_EPADDR_FIELD ((uint16_t)0x000FU) /*!< EndPoint ADDRess FIELD */
/* EndPoint REGister MASK (no toggle fields) */
#define USB_EPREG_MASK (USB_EP_CTR_RX|USB_EP_SETUP|USB_EP_T_FIELD|USB_EP_KIND|USB_EP_CTR_TX|USB_EPADDR_FIELD)
/*!< EP_TYPE[1:0] EndPoint TYPE */
#define USB_EP_TYPE_MASK ((uint16_t)0x0600U) /*!< EndPoint TYPE Mask */
#define USB_EP_BULK ((uint16_t)0x0000U) /*!< EndPoint BULK */
#define USB_EP_CONTROL ((uint16_t)0x0200U) /*!< EndPoint CONTROL */
#define USB_EP_ISOCHRONOUS ((uint16_t)0x0400U) /*!< EndPoint ISOCHRONOUS */
#define USB_EP_INTERRUPT ((uint16_t)0x0600U) /*!< EndPoint INTERRUPT */
#define USB_EP_T_MASK ((uint16_t) ~USB_EP_T_FIELD & USB_EPREG_MASK)
#define USB_EPKIND_MASK ((uint16_t)~USB_EP_KIND & USB_EPREG_MASK) /*!< EP_KIND EndPoint KIND */
/*!< STAT_TX[1:0] STATus for TX transfer */
#define USB_EP_TX_DIS ((uint16_t)0x0000U) /*!< EndPoint TX DISabled */
#define USB_EP_TX_STALL ((uint16_t)0x0010U) /*!< EndPoint TX STALLed */
#define USB_EP_TX_NAK ((uint16_t)0x0020U) /*!< EndPoint TX NAKed */
#define USB_EP_TX_VALID ((uint16_t)0x0030U) /*!< EndPoint TX VALID */
#define USB_EPTX_DTOG1 ((uint16_t)0x0010U) /*!< EndPoint TX Data TOGgle bit1 */
#define USB_EPTX_DTOG2 ((uint16_t)0x0020U) /*!< EndPoint TX Data TOGgle bit2 */
#define USB_EPTX_DTOGMASK (USB_EPTX_STAT|USB_EPREG_MASK)
/*!< STAT_RX[1:0] STATus for RX transfer */
#define USB_EP_RX_DIS ((uint16_t)0x0000U) /*!< EndPoint RX DISabled */
#define USB_EP_RX_STALL ((uint16_t)0x1000U) /*!< EndPoint RX STALLed */
#define USB_EP_RX_NAK ((uint16_t)0x2000U) /*!< EndPoint RX NAKed */
#define USB_EP_RX_VALID ((uint16_t)0x3000U) /*!< EndPoint RX VALID */
#define USB_EPRX_DTOG1 ((uint16_t)0x1000U) /*!< EndPoint RX Data TOGgle bit1 */
#define USB_EPRX_DTOG2 ((uint16_t)0x2000U) /*!< EndPoint RX Data TOGgle bit1 */
#define USB_EPRX_DTOGMASK (USB_EPRX_STAT|USB_EPREG_MASK)
/******************************************************************************/
/* */
/* USB Device FS General registers */
/* */
/******************************************************************************/
#define USB_CNTR (USB_BASE + 0x00000040U) /*!< Control register */
#define USB_ISTR (USB_BASE + 0x00000044U) /*!< Interrupt status register */
#define USB_FNR (USB_BASE + 0x00000048U) /*!< Frame number register */
#define USB_DADDR (USB_BASE + 0x0000004CU) /*!< Device address register */
#define USB_BTABLE (USB_BASE + 0x00000050U) /*!< Buffer Table address register */
#define USB_LPMCSR (USB_BASE + 0x00000054U) /*!< LPM Control and Status register */
#define USB_BCDR (USB_BASE + 0x00000058U) /*!< Battery Charging detector register*/
/****************** Bits definition for USB_CNTR register *******************/
#define USB_CNTR_CTRM ((uint16_t)0x8000U) /*!< Correct TRansfer Mask */
#define USB_CNTR_PMAOVRM ((uint16_t)0x4000U) /*!< DMA OVeR/underrun Mask */
#define USB_CNTR_ERRM ((uint16_t)0x2000U) /*!< ERRor Mask */
#define USB_CNTR_WKUPM ((uint16_t)0x1000U) /*!< WaKe UP Mask */
#define USB_CNTR_SUSPM ((uint16_t)0x0800U) /*!< SUSPend Mask */
#define USB_CNTR_RESETM ((uint16_t)0x0400U) /*!< RESET Mask */
#define USB_CNTR_SOFM ((uint16_t)0x0200U) /*!< Start Of Frame Mask */
#define USB_CNTR_ESOFM ((uint16_t)0x0100U) /*!< Expected Start Of Frame Mask */
#define USB_CNTR_L1REQM ((uint16_t)0x0080U) /*!< LPM L1 state request interrupt mask */
#define USB_CNTR_L1RESUME ((uint16_t)0x0020U) /*!< LPM L1 Resume request */
#define USB_CNTR_RESUME ((uint16_t)0x0010U) /*!< RESUME request */
#define USB_CNTR_FSUSP ((uint16_t)0x0008U) /*!< Force SUSPend */
#define USB_CNTR_LPMODE ((uint16_t)0x0004U) /*!< Low-power MODE */
#define USB_CNTR_PDWN ((uint16_t)0x0002U) /*!< Power DoWN */
#define USB_CNTR_FRES ((uint16_t)0x0001U) /*!< Force USB RESet */
/****************** Bits definition for USB_ISTR register *******************/
#define USB_ISTR_EP_ID ((uint16_t)0x000FU) /*!< EndPoint IDentifier (read-only bit) */
#define USB_ISTR_DIR ((uint16_t)0x0010U) /*!< DIRection of transaction (read-only bit) */
#define USB_ISTR_L1REQ ((uint16_t)0x0080U) /*!< LPM L1 state request */
#define USB_ISTR_ESOF ((uint16_t)0x0100U) /*!< Expected Start Of Frame (clear-only bit) */
#define USB_ISTR_SOF ((uint16_t)0x0200U) /*!< Start Of Frame (clear-only bit) */
#define USB_ISTR_RESET ((uint16_t)0x0400U) /*!< RESET (clear-only bit) */
#define USB_ISTR_SUSP ((uint16_t)0x0800U) /*!< SUSPend (clear-only bit) */
#define USB_ISTR_WKUP ((uint16_t)0x1000U) /*!< WaKe UP (clear-only bit) */
#define USB_ISTR_ERR ((uint16_t)0x2000U) /*!< ERRor (clear-only bit) */
#define USB_ISTR_PMAOVR ((uint16_t)0x4000U) /*!< DMA OVeR/underrun (clear-only bit) */
#define USB_ISTR_CTR ((uint16_t)0x8000U) /*!< Correct TRansfer (clear-only bit) */
#define USB_CLR_L1REQ (~USB_ISTR_L1REQ) /*!< clear LPM L1 bit */
#define USB_CLR_ESOF (~USB_ISTR_ESOF) /*!< clear Expected Start Of Frame bit */
#define USB_CLR_SOF (~USB_ISTR_SOF) /*!< clear Start Of Frame bit */
#define USB_CLR_RESET (~USB_ISTR_RESET) /*!< clear RESET bit */
#define USB_CLR_SUSP (~USB_ISTR_SUSP) /*!< clear SUSPend bit */
#define USB_CLR_WKUP (~USB_ISTR_WKUP) /*!< clear WaKe UP bit */
#define USB_CLR_ERR (~USB_ISTR_ERR) /*!< clear ERRor bit */
#define USB_CLR_PMAOVR (~USB_ISTR_PMAOVR) /*!< clear DMA OVeR/underrun bit*/
#define USB_CLR_CTR (~USB_ISTR_CTR) /*!< clear Correct TRansfer bit */
/****************** Bits definition for USB_FNR register ********************/
#define USB_FNR_FN ((uint16_t)0x07FFU) /*!< Frame Number */
#define USB_FNR_LSOF ((uint16_t)0x1800U) /*!< Lost SOF */
#define USB_FNR_LCK ((uint16_t)0x2000U) /*!< LoCKed */
#define USB_FNR_RXDM ((uint16_t)0x4000U) /*!< status of D- data line */
#define USB_FNR_RXDP ((uint16_t)0x8000U) /*!< status of D+ data line */
/****************** Bits definition for USB_DADDR register ****************/
#define USB_DADDR_ADD ((uint8_t)0x7FU) /*!< ADD[6:0] bits (Device Address) */
#define USB_DADDR_ADD0 ((uint8_t)0x01U) /*!< Bit 0 */
#define USB_DADDR_ADD1 ((uint8_t)0x02U) /*!< Bit 1 */
#define USB_DADDR_ADD2 ((uint8_t)0x04U) /*!< Bit 2 */
#define USB_DADDR_ADD3 ((uint8_t)0x08U) /*!< Bit 3 */
#define USB_DADDR_ADD4 ((uint8_t)0x10U) /*!< Bit 4 */
#define USB_DADDR_ADD5 ((uint8_t)0x20U) /*!< Bit 5 */
#define USB_DADDR_ADD6 ((uint8_t)0x40U) /*!< Bit 6 */
#define USB_DADDR_EF ((uint8_t)0x80U) /*!< Enable Function */
/****************** Bit definition for USB_BTABLE register ******************/
#define USB_BTABLE_BTABLE ((uint16_t)0xFFF8U) /*!< Buffer Table */
/****************** Bits definition for USB_BCDR register *******************/
#define USB_BCDR_BCDEN ((uint16_t)0x0001U) /*!< Battery charging detector (BCD) enable */
#define USB_BCDR_DCDEN ((uint16_t)0x0002U) /*!< Data contact detection (DCD) mode enable */
#define USB_BCDR_PDEN ((uint16_t)0x0004U) /*!< Primary detection (PD) mode enable */
#define USB_BCDR_SDEN ((uint16_t)0x0008U) /*!< Secondary detection (SD) mode enable */
#define USB_BCDR_DCDET ((uint16_t)0x0010U) /*!< Data contact detection (DCD) status */
#define USB_BCDR_PDET ((uint16_t)0x0020U) /*!< Primary detection (PD) status */
#define USB_BCDR_SDET ((uint16_t)0x0040U) /*!< Secondary detection (SD) status */
#define USB_BCDR_PS2DET ((uint16_t)0x0080U) /*!< PS2 port or proprietary charger detected */
#define USB_BCDR_DPPU ((uint16_t)0x8000U) /*!< DP Pull-up Enable */
/******************* Bit definition for LPMCSR register *********************/
#define USB_LPMCSR_LMPEN ((uint16_t)0x0001U) /*!< LPM support enable */
#define USB_LPMCSR_LPMACK ((uint16_t)0x0002U) /*!< LPM Token acknowledge enable*/
#define USB_LPMCSR_REMWAKE ((uint16_t)0x0008U) /*!< bRemoteWake value received with last ACKed LPM Token */
#define USB_LPMCSR_BESL ((uint16_t)0x00F0U) /*!< BESL value received with last ACKed LPM Token */
/*!< Buffer descriptor table */
/***************** Bit definition for USB_ADDR0_TX register *****************/
#define USB_ADDR0_TX_ADDR0_TX_Pos (1U)
#define USB_ADDR0_TX_ADDR0_TX_Msk (0x7FFFUL << USB_ADDR0_TX_ADDR0_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR0_TX_ADDR0_TX USB_ADDR0_TX_ADDR0_TX_Msk /*!< Transmission Buffer Address 0 */
/***************** Bit definition for USB_ADDR1_TX register *****************/
#define USB_ADDR1_TX_ADDR1_TX_Pos (1U)
#define USB_ADDR1_TX_ADDR1_TX_Msk (0x7FFFUL << USB_ADDR1_TX_ADDR1_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR1_TX_ADDR1_TX USB_ADDR1_TX_ADDR1_TX_Msk /*!< Transmission Buffer Address 1 */
/***************** Bit definition for USB_ADDR2_TX register *****************/
#define USB_ADDR2_TX_ADDR2_TX_Pos (1U)
#define USB_ADDR2_TX_ADDR2_TX_Msk (0x7FFFUL << USB_ADDR2_TX_ADDR2_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR2_TX_ADDR2_TX USB_ADDR2_TX_ADDR2_TX_Msk /*!< Transmission Buffer Address 2 */
/***************** Bit definition for USB_ADDR3_TX register *****************/
#define USB_ADDR3_TX_ADDR3_TX_Pos (1U)
#define USB_ADDR3_TX_ADDR3_TX_Msk (0x7FFFUL << USB_ADDR3_TX_ADDR3_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR3_TX_ADDR3_TX USB_ADDR3_TX_ADDR3_TX_Msk /*!< Transmission Buffer Address 3 */
/***************** Bit definition for USB_ADDR4_TX register *****************/
#define USB_ADDR4_TX_ADDR4_TX_Pos (1U)
#define USB_ADDR4_TX_ADDR4_TX_Msk (0x7FFFUL << USB_ADDR4_TX_ADDR4_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR4_TX_ADDR4_TX USB_ADDR4_TX_ADDR4_TX_Msk /*!< Transmission Buffer Address 4 */
/***************** Bit definition for USB_ADDR5_TX register *****************/
#define USB_ADDR5_TX_ADDR5_TX_Pos (1U)
#define USB_ADDR5_TX_ADDR5_TX_Msk (0x7FFFUL << USB_ADDR5_TX_ADDR5_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR5_TX_ADDR5_TX USB_ADDR5_TX_ADDR5_TX_Msk /*!< Transmission Buffer Address 5 */
/***************** Bit definition for USB_ADDR6_TX register *****************/
#define USB_ADDR6_TX_ADDR6_TX_Pos (1U)
#define USB_ADDR6_TX_ADDR6_TX_Msk (0x7FFFUL << USB_ADDR6_TX_ADDR6_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR6_TX_ADDR6_TX USB_ADDR6_TX_ADDR6_TX_Msk /*!< Transmission Buffer Address 6 */
/***************** Bit definition for USB_ADDR7_TX register *****************/
#define USB_ADDR7_TX_ADDR7_TX_Pos (1U)
#define USB_ADDR7_TX_ADDR7_TX_Msk (0x7FFFUL << USB_ADDR7_TX_ADDR7_TX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR7_TX_ADDR7_TX USB_ADDR7_TX_ADDR7_TX_Msk /*!< Transmission Buffer Address 7 */
/*----------------------------------------------------------------------------*/
/***************** Bit definition for USB_COUNT0_TX register ****************/
#define USB_COUNT0_TX_COUNT0_TX_Pos (0U)
#define USB_COUNT0_TX_COUNT0_TX_Msk (0x3FFUL << USB_COUNT0_TX_COUNT0_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT0_TX_COUNT0_TX USB_COUNT0_TX_COUNT0_TX_Msk /*!< Transmission Byte Count 0 */
/***************** Bit definition for USB_COUNT1_TX register ****************/
#define USB_COUNT1_TX_COUNT1_TX_Pos (0U)
#define USB_COUNT1_TX_COUNT1_TX_Msk (0x3FFUL << USB_COUNT1_TX_COUNT1_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT1_TX_COUNT1_TX USB_COUNT1_TX_COUNT1_TX_Msk /*!< Transmission Byte Count 1 */
/***************** Bit definition for USB_COUNT2_TX register ****************/
#define USB_COUNT2_TX_COUNT2_TX_Pos (0U)
#define USB_COUNT2_TX_COUNT2_TX_Msk (0x3FFUL << USB_COUNT2_TX_COUNT2_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT2_TX_COUNT2_TX USB_COUNT2_TX_COUNT2_TX_Msk /*!< Transmission Byte Count 2 */
/***************** Bit definition for USB_COUNT3_TX register ****************/
#define USB_COUNT3_TX_COUNT3_TX_Pos (0U)
#define USB_COUNT3_TX_COUNT3_TX_Msk (0x3FFUL << USB_COUNT3_TX_COUNT3_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT3_TX_COUNT3_TX USB_COUNT3_TX_COUNT3_TX_Msk /*!< Transmission Byte Count 3 */
/***************** Bit definition for USB_COUNT4_TX register ****************/
#define USB_COUNT4_TX_COUNT4_TX_Pos (0U)
#define USB_COUNT4_TX_COUNT4_TX_Msk (0x3FFUL << USB_COUNT4_TX_COUNT4_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT4_TX_COUNT4_TX USB_COUNT4_TX_COUNT4_TX_Msk /*!< Transmission Byte Count 4 */
/***************** Bit definition for USB_COUNT5_TX register ****************/
#define USB_COUNT5_TX_COUNT5_TX_Pos (0U)
#define USB_COUNT5_TX_COUNT5_TX_Msk (0x3FFUL << USB_COUNT5_TX_COUNT5_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT5_TX_COUNT5_TX USB_COUNT5_TX_COUNT5_TX_Msk /*!< Transmission Byte Count 5 */
/***************** Bit definition for USB_COUNT6_TX register ****************/
#define USB_COUNT6_TX_COUNT6_TX_Pos (0U)
#define USB_COUNT6_TX_COUNT6_TX_Msk (0x3FFUL << USB_COUNT6_TX_COUNT6_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT6_TX_COUNT6_TX USB_COUNT6_TX_COUNT6_TX_Msk /*!< Transmission Byte Count 6 */
/***************** Bit definition for USB_COUNT7_TX register ****************/
#define USB_COUNT7_TX_COUNT7_TX_Pos (0U)
#define USB_COUNT7_TX_COUNT7_TX_Msk (0x3FFUL << USB_COUNT7_TX_COUNT7_TX_Pos)/*!< 0x000003FF */
#define USB_COUNT7_TX_COUNT7_TX USB_COUNT7_TX_COUNT7_TX_Msk /*!< Transmission Byte Count 7 */
/*----------------------------------------------------------------------------*/
/**************** Bit definition for USB_COUNT0_TX_0 register ***************/
#define USB_COUNT0_TX_0_COUNT0_TX_0 (0x000003FFU) /*!< Transmission Byte Count 0 (low) */
/**************** Bit definition for USB_COUNT0_TX_1 register ***************/
#define USB_COUNT0_TX_1_COUNT0_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 0 (high) */
/**************** Bit definition for USB_COUNT1_TX_0 register ***************/
#define USB_COUNT1_TX_0_COUNT1_TX_0 (0x000003FFU) /*!< Transmission Byte Count 1 (low) */
/**************** Bit definition for USB_COUNT1_TX_1 register ***************/
#define USB_COUNT1_TX_1_COUNT1_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 1 (high) */
/**************** Bit definition for USB_COUNT2_TX_0 register ***************/
#define USB_COUNT2_TX_0_COUNT2_TX_0 (0x000003FFU) /*!< Transmission Byte Count 2 (low) */
/**************** Bit definition for USB_COUNT2_TX_1 register ***************/
#define USB_COUNT2_TX_1_COUNT2_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 2 (high) */
/**************** Bit definition for USB_COUNT3_TX_0 register ***************/
#define USB_COUNT3_TX_0_COUNT3_TX_0 (0x000003FFU) /*!< Transmission Byte Count 3 (low) */
/**************** Bit definition for USB_COUNT3_TX_1 register ***************/
#define USB_COUNT3_TX_1_COUNT3_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 3 (high) */
/**************** Bit definition for USB_COUNT4_TX_0 register ***************/
#define USB_COUNT4_TX_0_COUNT4_TX_0 (0x000003FFU) /*!< Transmission Byte Count 4 (low) */
/**************** Bit definition for USB_COUNT4_TX_1 register ***************/
#define USB_COUNT4_TX_1_COUNT4_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 4 (high) */
/**************** Bit definition for USB_COUNT5_TX_0 register ***************/
#define USB_COUNT5_TX_0_COUNT5_TX_0 (0x000003FFU) /*!< Transmission Byte Count 5 (low) */
/**************** Bit definition for USB_COUNT5_TX_1 register ***************/
#define USB_COUNT5_TX_1_COUNT5_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 5 (high) */
/**************** Bit definition for USB_COUNT6_TX_0 register ***************/
#define USB_COUNT6_TX_0_COUNT6_TX_0 (0x000003FFU) /*!< Transmission Byte Count 6 (low) */
/**************** Bit definition for USB_COUNT6_TX_1 register ***************/
#define USB_COUNT6_TX_1_COUNT6_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 6 (high) */
/**************** Bit definition for USB_COUNT7_TX_0 register ***************/
#define USB_COUNT7_TX_0_COUNT7_TX_0 (0x000003FFU) /*!< Transmission Byte Count 7 (low) */
/**************** Bit definition for USB_COUNT7_TX_1 register ***************/
#define USB_COUNT7_TX_1_COUNT7_TX_1 (0x03FF0000U) /*!< Transmission Byte Count 7 (high) */
/*----------------------------------------------------------------------------*/
/***************** Bit definition for USB_ADDR0_RX register *****************/
#define USB_ADDR0_RX_ADDR0_RX_Pos (1U)
#define USB_ADDR0_RX_ADDR0_RX_Msk (0x7FFFUL << USB_ADDR0_RX_ADDR0_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR0_RX_ADDR0_RX USB_ADDR0_RX_ADDR0_RX_Msk /*!< Reception Buffer Address 0 */
/***************** Bit definition for USB_ADDR1_RX register *****************/
#define USB_ADDR1_RX_ADDR1_RX_Pos (1U)
#define USB_ADDR1_RX_ADDR1_RX_Msk (0x7FFFUL << USB_ADDR1_RX_ADDR1_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR1_RX_ADDR1_RX USB_ADDR1_RX_ADDR1_RX_Msk /*!< Reception Buffer Address 1 */
/***************** Bit definition for USB_ADDR2_RX register *****************/
#define USB_ADDR2_RX_ADDR2_RX_Pos (1U)
#define USB_ADDR2_RX_ADDR2_RX_Msk (0x7FFFUL << USB_ADDR2_RX_ADDR2_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR2_RX_ADDR2_RX USB_ADDR2_RX_ADDR2_RX_Msk /*!< Reception Buffer Address 2 */
/***************** Bit definition for USB_ADDR3_RX register *****************/
#define USB_ADDR3_RX_ADDR3_RX_Pos (1U)
#define USB_ADDR3_RX_ADDR3_RX_Msk (0x7FFFUL << USB_ADDR3_RX_ADDR3_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR3_RX_ADDR3_RX USB_ADDR3_RX_ADDR3_RX_Msk /*!< Reception Buffer Address 3 */
/***************** Bit definition for USB_ADDR4_RX register *****************/
#define USB_ADDR4_RX_ADDR4_RX_Pos (1U)
#define USB_ADDR4_RX_ADDR4_RX_Msk (0x7FFFUL << USB_ADDR4_RX_ADDR4_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR4_RX_ADDR4_RX USB_ADDR4_RX_ADDR4_RX_Msk /*!< Reception Buffer Address 4 */
/***************** Bit definition for USB_ADDR5_RX register *****************/
#define USB_ADDR5_RX_ADDR5_RX_Pos (1U)
#define USB_ADDR5_RX_ADDR5_RX_Msk (0x7FFFUL << USB_ADDR5_RX_ADDR5_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR5_RX_ADDR5_RX USB_ADDR5_RX_ADDR5_RX_Msk /*!< Reception Buffer Address 5 */
/***************** Bit definition for USB_ADDR6_RX register *****************/
#define USB_ADDR6_RX_ADDR6_RX_Pos (1U)
#define USB_ADDR6_RX_ADDR6_RX_Msk (0x7FFFUL << USB_ADDR6_RX_ADDR6_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR6_RX_ADDR6_RX USB_ADDR6_RX_ADDR6_RX_Msk /*!< Reception Buffer Address 6 */
/***************** Bit definition for USB_ADDR7_RX register *****************/
#define USB_ADDR7_RX_ADDR7_RX_Pos (1U)
#define USB_ADDR7_RX_ADDR7_RX_Msk (0x7FFFUL << USB_ADDR7_RX_ADDR7_RX_Pos)/*!< 0x0000FFFE */
#define USB_ADDR7_RX_ADDR7_RX USB_ADDR7_RX_ADDR7_RX_Msk /*!< Reception Buffer Address 7 */
/*----------------------------------------------------------------------------*/
/***************** Bit definition for USB_COUNT0_RX register ****************/
#define USB_COUNT0_RX_COUNT0_RX_Pos (0U)
#define USB_COUNT0_RX_COUNT0_RX_Msk (0x3FFUL << USB_COUNT0_RX_COUNT0_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT0_RX_COUNT0_RX USB_COUNT0_RX_COUNT0_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT0_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT0_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT0_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT0_RX_NUM_BLOCK USB_COUNT0_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT0_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT0_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT0_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT0_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT0_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT0_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT0_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT0_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT0_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT0_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT0_RX_BLSIZE_Pos (15U)
#define USB_COUNT0_RX_BLSIZE_Msk (0x1UL << USB_COUNT0_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT0_RX_BLSIZE USB_COUNT0_RX_BLSIZE_Msk /*!< BLock SIZE */
/***************** Bit definition for USB_COUNT1_RX register ****************/
#define USB_COUNT1_RX_COUNT1_RX_Pos (0U)
#define USB_COUNT1_RX_COUNT1_RX_Msk (0x3FFUL << USB_COUNT1_RX_COUNT1_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT1_RX_COUNT1_RX USB_COUNT1_RX_COUNT1_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT1_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT1_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT1_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT1_RX_NUM_BLOCK USB_COUNT1_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT1_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT1_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT1_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT1_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT1_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT1_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT1_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT1_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT1_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT1_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT1_RX_BLSIZE_Pos (15U)
#define USB_COUNT1_RX_BLSIZE_Msk (0x1UL << USB_COUNT1_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT1_RX_BLSIZE USB_COUNT1_RX_BLSIZE_Msk /*!< BLock SIZE */
/***************** Bit definition for USB_COUNT2_RX register ****************/
#define USB_COUNT2_RX_COUNT2_RX_Pos (0U)
#define USB_COUNT2_RX_COUNT2_RX_Msk (0x3FFUL << USB_COUNT2_RX_COUNT2_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT2_RX_COUNT2_RX USB_COUNT2_RX_COUNT2_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT2_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT2_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT2_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT2_RX_NUM_BLOCK USB_COUNT2_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT2_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT2_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT2_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT2_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT2_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT2_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT2_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT2_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT2_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT2_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT2_RX_BLSIZE_Pos (15U)
#define USB_COUNT2_RX_BLSIZE_Msk (0x1UL << USB_COUNT2_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT2_RX_BLSIZE USB_COUNT2_RX_BLSIZE_Msk /*!< BLock SIZE */
/***************** Bit definition for USB_COUNT3_RX register ****************/
#define USB_COUNT3_RX_COUNT3_RX_Pos (0U)
#define USB_COUNT3_RX_COUNT3_RX_Msk (0x3FFUL << USB_COUNT3_RX_COUNT3_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT3_RX_COUNT3_RX USB_COUNT3_RX_COUNT3_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT3_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT3_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT3_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT3_RX_NUM_BLOCK USB_COUNT3_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT3_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT3_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT3_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT3_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT3_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT3_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT3_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT3_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT3_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT3_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT3_RX_BLSIZE_Pos (15U)
#define USB_COUNT3_RX_BLSIZE_Msk (0x1UL << USB_COUNT3_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT3_RX_BLSIZE USB_COUNT3_RX_BLSIZE_Msk /*!< BLock SIZE */
/***************** Bit definition for USB_COUNT4_RX register ****************/
#define USB_COUNT4_RX_COUNT4_RX_Pos (0U)
#define USB_COUNT4_RX_COUNT4_RX_Msk (0x3FFUL << USB_COUNT4_RX_COUNT4_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT4_RX_COUNT4_RX USB_COUNT4_RX_COUNT4_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT4_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT4_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT4_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT4_RX_NUM_BLOCK USB_COUNT4_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT4_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT4_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT4_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT4_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT4_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT4_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT4_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT4_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT4_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT4_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT4_RX_BLSIZE_Pos (15U)
#define USB_COUNT4_RX_BLSIZE_Msk (0x1UL << USB_COUNT4_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT4_RX_BLSIZE USB_COUNT4_RX_BLSIZE_Msk /*!< BLock SIZE */
/***************** Bit definition for USB_COUNT5_RX register ****************/
#define USB_COUNT5_RX_COUNT5_RX_Pos (0U)
#define USB_COUNT5_RX_COUNT5_RX_Msk (0x3FFUL << USB_COUNT5_RX_COUNT5_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT5_RX_COUNT5_RX USB_COUNT5_RX_COUNT5_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT5_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT5_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT5_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT5_RX_NUM_BLOCK USB_COUNT5_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT5_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT5_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT5_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT5_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT5_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT5_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT5_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT5_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT5_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT5_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT5_RX_BLSIZE_Pos (15U)
#define USB_COUNT5_RX_BLSIZE_Msk (0x1UL << USB_COUNT5_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT5_RX_BLSIZE USB_COUNT5_RX_BLSIZE_Msk /*!< BLock SIZE */
/***************** Bit definition for USB_COUNT6_RX register ****************/
#define USB_COUNT6_RX_COUNT6_RX_Pos (0U)
#define USB_COUNT6_RX_COUNT6_RX_Msk (0x3FFUL << USB_COUNT6_RX_COUNT6_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT6_RX_COUNT6_RX USB_COUNT6_RX_COUNT6_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT6_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT6_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT6_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT6_RX_NUM_BLOCK USB_COUNT6_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT6_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT6_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT6_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT6_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT6_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT6_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT6_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT6_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT6_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT6_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT6_RX_BLSIZE_Pos (15U)
#define USB_COUNT6_RX_BLSIZE_Msk (0x1UL << USB_COUNT6_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT6_RX_BLSIZE USB_COUNT6_RX_BLSIZE_Msk /*!< BLock SIZE */
/***************** Bit definition for USB_COUNT7_RX register ****************/
#define USB_COUNT7_RX_COUNT7_RX_Pos (0U)
#define USB_COUNT7_RX_COUNT7_RX_Msk (0x3FFUL << USB_COUNT7_RX_COUNT7_RX_Pos)/*!< 0x000003FF */
#define USB_COUNT7_RX_COUNT7_RX USB_COUNT7_RX_COUNT7_RX_Msk /*!< Reception Byte Count */
#define USB_COUNT7_RX_NUM_BLOCK_Pos (10U)
#define USB_COUNT7_RX_NUM_BLOCK_Msk (0x1FUL << USB_COUNT7_RX_NUM_BLOCK_Pos)/*!< 0x00007C00 */
#define USB_COUNT7_RX_NUM_BLOCK USB_COUNT7_RX_NUM_BLOCK_Msk /*!< NUM_BLOCK[4:0] bits (Number of blocks) */
#define USB_COUNT7_RX_NUM_BLOCK_0 (0x01UL << USB_COUNT7_RX_NUM_BLOCK_Pos)/*!< 0x00000400 */
#define USB_COUNT7_RX_NUM_BLOCK_1 (0x02UL << USB_COUNT7_RX_NUM_BLOCK_Pos)/*!< 0x00000800 */
#define USB_COUNT7_RX_NUM_BLOCK_2 (0x04UL << USB_COUNT7_RX_NUM_BLOCK_Pos)/*!< 0x00001000 */
#define USB_COUNT7_RX_NUM_BLOCK_3 (0x08UL << USB_COUNT7_RX_NUM_BLOCK_Pos)/*!< 0x00002000 */
#define USB_COUNT7_RX_NUM_BLOCK_4 (0x10UL << USB_COUNT7_RX_NUM_BLOCK_Pos)/*!< 0x00004000 */
#define USB_COUNT7_RX_BLSIZE_Pos (15U)
#define USB_COUNT7_RX_BLSIZE_Msk (0x1UL << USB_COUNT7_RX_BLSIZE_Pos)/*!< 0x00008000 */
#define USB_COUNT7_RX_BLSIZE USB_COUNT7_RX_BLSIZE_Msk /*!< BLock SIZE */
/*----------------------------------------------------------------------------*/
/**************** Bit definition for USB_COUNT0_RX_0 register ***************/
#define USB_COUNT0_RX_0_COUNT0_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT0_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT0_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT0_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT0_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT0_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT0_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT0_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/**************** Bit definition for USB_COUNT0_RX_1 register ***************/
#define USB_COUNT0_RX_1_COUNT0_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT0_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT0_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 1 */
#define USB_COUNT0_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT0_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT0_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT0_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT0_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/**************** Bit definition for USB_COUNT1_RX_0 register ***************/
#define USB_COUNT1_RX_0_COUNT1_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT1_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT1_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT1_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT1_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT1_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT1_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT1_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/**************** Bit definition for USB_COUNT1_RX_1 register ***************/
#define USB_COUNT1_RX_1_COUNT1_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT1_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT1_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 0 */
#define USB_COUNT1_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT1_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT1_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT1_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT1_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/**************** Bit definition for USB_COUNT2_RX_0 register ***************/
#define USB_COUNT2_RX_0_COUNT2_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT2_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT2_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT2_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT2_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT2_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT2_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT2_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/**************** Bit definition for USB_COUNT2_RX_1 register ***************/
#define USB_COUNT2_RX_1_COUNT2_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT2_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT2_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 0 */
#define USB_COUNT2_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT2_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT2_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT2_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT2_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/**************** Bit definition for USB_COUNT3_RX_0 register ***************/
#define USB_COUNT3_RX_0_COUNT3_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT3_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT3_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT3_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT3_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT3_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT3_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT3_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/**************** Bit definition for USB_COUNT3_RX_1 register ***************/
#define USB_COUNT3_RX_1_COUNT3_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT3_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT3_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 0 */
#define USB_COUNT3_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT3_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT3_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT3_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT3_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/**************** Bit definition for USB_COUNT4_RX_0 register ***************/
#define USB_COUNT4_RX_0_COUNT4_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT4_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT4_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT4_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT4_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT4_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT4_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT4_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/**************** Bit definition for USB_COUNT4_RX_1 register ***************/
#define USB_COUNT4_RX_1_COUNT4_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT4_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT4_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 0 */
#define USB_COUNT4_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT4_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT4_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT4_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT4_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/**************** Bit definition for USB_COUNT5_RX_0 register ***************/
#define USB_COUNT5_RX_0_COUNT5_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT5_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT5_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT5_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT5_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT5_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT5_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT5_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/**************** Bit definition for USB_COUNT5_RX_1 register ***************/
#define USB_COUNT5_RX_1_COUNT5_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT5_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT5_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 0 */
#define USB_COUNT5_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT5_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT5_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT5_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT5_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/*************** Bit definition for USB_COUNT6_RX_0 register ***************/
#define USB_COUNT6_RX_0_COUNT6_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT6_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT6_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT6_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT6_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT6_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT6_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT6_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/**************** Bit definition for USB_COUNT6_RX_1 register ***************/
#define USB_COUNT6_RX_1_COUNT6_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT6_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT6_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 0 */
#define USB_COUNT6_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT6_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT6_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT6_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT6_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/*************** Bit definition for USB_COUNT7_RX_0 register ****************/
#define USB_COUNT7_RX_0_COUNT7_RX_0 (0x000003FFU) /*!< Reception Byte Count (low) */
#define USB_COUNT7_RX_0_NUM_BLOCK_0 (0x00007C00U) /*!< NUM_BLOCK_0[4:0] bits (Number of blocks) (low) */
#define USB_COUNT7_RX_0_NUM_BLOCK_0_0 (0x00000400U) /*!< Bit 0 */
#define USB_COUNT7_RX_0_NUM_BLOCK_0_1 (0x00000800U) /*!< Bit 1 */
#define USB_COUNT7_RX_0_NUM_BLOCK_0_2 (0x00001000U) /*!< Bit 2 */
#define USB_COUNT7_RX_0_NUM_BLOCK_0_3 (0x00002000U) /*!< Bit 3 */
#define USB_COUNT7_RX_0_NUM_BLOCK_0_4 (0x00004000U) /*!< Bit 4 */
#define USB_COUNT7_RX_0_BLSIZE_0 (0x00008000U) /*!< BLock SIZE (low) */
/*************** Bit definition for USB_COUNT7_RX_1 register ****************/
#define USB_COUNT7_RX_1_COUNT7_RX_1 (0x03FF0000U) /*!< Reception Byte Count (high) */
#define USB_COUNT7_RX_1_NUM_BLOCK_1 (0x7C000000U) /*!< NUM_BLOCK_1[4:0] bits (Number of blocks) (high) */
#define USB_COUNT7_RX_1_NUM_BLOCK_1_0 (0x04000000U) /*!< Bit 0 */
#define USB_COUNT7_RX_1_NUM_BLOCK_1_1 (0x08000000U) /*!< Bit 1 */
#define USB_COUNT7_RX_1_NUM_BLOCK_1_2 (0x10000000U) /*!< Bit 2 */
#define USB_COUNT7_RX_1_NUM_BLOCK_1_3 (0x20000000U) /*!< Bit 3 */
#define USB_COUNT7_RX_1_NUM_BLOCK_1_4 (0x40000000U) /*!< Bit 4 */
#define USB_COUNT7_RX_1_BLSIZE_1 (0x80000000U) /*!< BLock SIZE (high) */
/******************************************************************************/
/* */
/* UCPD */
/* */
/******************************************************************************/
/******************** Bits definition for UCPD_CFG1 register *******************/
#define UCPD_CFG1_HBITCLKDIV_Pos (0U)
#define UCPD_CFG1_HBITCLKDIV_Msk (0x3FUL << UCPD_CFG1_HBITCLKDIV_Pos) /*!< 0x0000003F */
#define UCPD_CFG1_HBITCLKDIV UCPD_CFG1_HBITCLKDIV_Msk /*!< Number of cycles (minus 1) for a half bit clock */
#define UCPD_CFG1_HBITCLKDIV_0 (0x01UL << UCPD_CFG1_HBITCLKDIV_Pos) /*!< 0x00000001 */
#define UCPD_CFG1_HBITCLKDIV_1 (0x02UL << UCPD_CFG1_HBITCLKDIV_Pos) /*!< 0x00000002 */
#define UCPD_CFG1_HBITCLKDIV_2 (0x04UL << UCPD_CFG1_HBITCLKDIV_Pos) /*!< 0x00000004 */
#define UCPD_CFG1_HBITCLKDIV_3 (0x08UL << UCPD_CFG1_HBITCLKDIV_Pos) /*!< 0x00000008 */
#define UCPD_CFG1_HBITCLKDIV_4 (0x10UL << UCPD_CFG1_HBITCLKDIV_Pos) /*!< 0x00000010 */
#define UCPD_CFG1_HBITCLKDIV_5 (0x20UL << UCPD_CFG1_HBITCLKDIV_Pos) /*!< 0x00000020 */
#define UCPD_CFG1_IFRGAP_Pos (6U)
#define UCPD_CFG1_IFRGAP_Msk (0x1FUL << UCPD_CFG1_IFRGAP_Pos) /*!< 0x000007C0 */
#define UCPD_CFG1_IFRGAP UCPD_CFG1_IFRGAP_Msk /*!< Clock divider value to generates Interframe gap */
#define UCPD_CFG1_IFRGAP_0 (0x01UL << UCPD_CFG1_IFRGAP_Pos) /*!< 0x00000040 */
#define UCPD_CFG1_IFRGAP_1 (0x02UL << UCPD_CFG1_IFRGAP_Pos) /*!< 0x00000080 */
#define UCPD_CFG1_IFRGAP_2 (0x04UL << UCPD_CFG1_IFRGAP_Pos) /*!< 0x00000100 */
#define UCPD_CFG1_IFRGAP_3 (0x08UL << UCPD_CFG1_IFRGAP_Pos) /*!< 0x00000200 */
#define UCPD_CFG1_IFRGAP_4 (0x10UL << UCPD_CFG1_IFRGAP_Pos) /*!< 0x00000400 */
#define UCPD_CFG1_TRANSWIN_Pos (11U)
#define UCPD_CFG1_TRANSWIN_Msk (0x1FUL << UCPD_CFG1_TRANSWIN_Pos) /*!< 0x0000F800 */
#define UCPD_CFG1_TRANSWIN UCPD_CFG1_TRANSWIN_Msk /*!< Number of cycles (minus 1) of the half bit clock */
#define UCPD_CFG1_TRANSWIN_0 (0x01UL << UCPD_CFG1_TRANSWIN_Pos) /*!< 0x00000800 */
#define UCPD_CFG1_TRANSWIN_1 (0x02UL << UCPD_CFG1_TRANSWIN_Pos) /*!< 0x00001000 */
#define UCPD_CFG1_TRANSWIN_2 (0x04UL << UCPD_CFG1_TRANSWIN_Pos) /*!< 0x00002000 */
#define UCPD_CFG1_TRANSWIN_3 (0x08UL << UCPD_CFG1_TRANSWIN_Pos) /*!< 0x00004000 */
#define UCPD_CFG1_TRANSWIN_4 (0x10UL << UCPD_CFG1_TRANSWIN_Pos) /*!< 0x00008000 */
#define UCPD_CFG1_PSC_UCPDCLK_Pos (17U)
#define UCPD_CFG1_PSC_UCPDCLK_Msk (0x7UL << UCPD_CFG1_PSC_UCPDCLK_Pos) /*!< 0x000E0000 */
#define UCPD_CFG1_PSC_UCPDCLK UCPD_CFG1_PSC_UCPDCLK_Msk /*!< Prescaler for UCPDCLK */
#define UCPD_CFG1_PSC_UCPDCLK_0 (0x1UL << UCPD_CFG1_PSC_UCPDCLK_Pos) /*!< 0x00020000 */
#define UCPD_CFG1_PSC_UCPDCLK_1 (0x2UL << UCPD_CFG1_PSC_UCPDCLK_Pos) /*!< 0x00040000 */
#define UCPD_CFG1_PSC_UCPDCLK_2 (0x4UL << UCPD_CFG1_PSC_UCPDCLK_Pos) /*!< 0x00080000 */
#define UCPD_CFG1_RXORDSETEN_Pos (20U)
#define UCPD_CFG1_RXORDSETEN_Msk (0x1FFUL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x1FF00000 */
#define UCPD_CFG1_RXORDSETEN UCPD_CFG1_RXORDSETEN_Msk /*!< Receiver ordered set detection enable */
#define UCPD_CFG1_RXORDSETEN_0 (0x001UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x00100000 */
#define UCPD_CFG1_RXORDSETEN_1 (0x002UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x00200000 */
#define UCPD_CFG1_RXORDSETEN_2 (0x004UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x00400000 */
#define UCPD_CFG1_RXORDSETEN_3 (0x008UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x00800000 */
#define UCPD_CFG1_RXORDSETEN_4 (0x010UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x01000000 */
#define UCPD_CFG1_RXORDSETEN_5 (0x020UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x02000000 */
#define UCPD_CFG1_RXORDSETEN_6 (0x040UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x04000000 */
#define UCPD_CFG1_RXORDSETEN_7 (0x080UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x08000000 */
#define UCPD_CFG1_RXORDSETEN_8 (0x100UL << UCPD_CFG1_RXORDSETEN_Pos)/*!< 0x10000000 */
#define UCPD_CFG1_TXDMAEN_Pos (29U)
#define UCPD_CFG1_TXDMAEN_Msk (0x1UL << UCPD_CFG1_TXDMAEN_Pos) /*!< 0x20000000 */
#define UCPD_CFG1_TXDMAEN UCPD_CFG1_TXDMAEN_Msk /*!< DMA transmission requests enable */
#define UCPD_CFG1_RXDMAEN_Pos (30U)
#define UCPD_CFG1_RXDMAEN_Msk (0x1UL << UCPD_CFG1_RXDMAEN_Pos) /*!< 0x40000000 */
#define UCPD_CFG1_RXDMAEN UCPD_CFG1_RXDMAEN_Msk /*!< DMA reception requests enable */
#define UCPD_CFG1_UCPDEN_Pos (31U)
#define UCPD_CFG1_UCPDEN_Msk (0x1UL << UCPD_CFG1_UCPDEN_Pos) /*!< 0x80000000 */
#define UCPD_CFG1_UCPDEN UCPD_CFG1_UCPDEN_Msk /*!< USB Power Delivery Block Enable */
/******************** Bits definition for UCPD_CFG2 register *******************/
#define UCPD_CFG2_RXFILTDIS_Pos (0U)
#define UCPD_CFG2_RXFILTDIS_Msk (0x1UL << UCPD_CFG2_RXFILTDIS_Pos) /*!< 0x00000001 */
#define UCPD_CFG2_RXFILTDIS UCPD_CFG2_RXFILTDIS_Msk /*!< Enables an Rx pre-filter for the BMC decoder */
#define UCPD_CFG2_RXFILT2N3_Pos (1U)
#define UCPD_CFG2_RXFILT2N3_Msk (0x1UL << UCPD_CFG2_RXFILT2N3_Pos) /*!< 0x00000002 */
#define UCPD_CFG2_RXFILT2N3 UCPD_CFG2_RXFILT2N3_Msk /*!< Controls the sampling method for an Rx pre-filter for the BMC decode */
#define UCPD_CFG2_FORCECLK_Pos (2U)
#define UCPD_CFG2_FORCECLK_Msk (0x1UL << UCPD_CFG2_FORCECLK_Pos) /*!< 0x00000004 */
#define UCPD_CFG2_FORCECLK UCPD_CFG2_FORCECLK_Msk /*!< Controls forcing of the clock request UCPDCLK_REQ */
#define UCPD_CFG2_WUPEN_Pos (3U)
#define UCPD_CFG2_WUPEN_Msk (0x1UL << UCPD_CFG2_WUPEN_Pos) /*!< 0x00000008 */
#define UCPD_CFG2_WUPEN UCPD_CFG2_WUPEN_Msk /*!< Wakeup from STOP enable */
/******************** Bits definition for UCPD_CR register ********************/
#define UCPD_CR_TXMODE_Pos (0U)
#define UCPD_CR_TXMODE_Msk (0x3UL << UCPD_CR_TXMODE_Pos) /*!< 0x00000003 */
#define UCPD_CR_TXMODE UCPD_CR_TXMODE_Msk /*!< Type of Tx packet */
#define UCPD_CR_TXMODE_0 (0x1UL << UCPD_CR_TXMODE_Pos) /*!< 0x00000001 */
#define UCPD_CR_TXMODE_1 (0x2UL << UCPD_CR_TXMODE_Pos) /*!< 0x00000002 */
#define UCPD_CR_TXSEND_Pos (2U)
#define UCPD_CR_TXSEND_Msk (0x1UL << UCPD_CR_TXSEND_Pos) /*!< 0x00000004 */
#define UCPD_CR_TXSEND UCPD_CR_TXSEND_Msk /*!< Type of Tx packet */
#define UCPD_CR_TXHRST_Pos (3U)
#define UCPD_CR_TXHRST_Msk (0x1UL << UCPD_CR_TXHRST_Pos) /*!< 0x00000008 */
#define UCPD_CR_TXHRST UCPD_CR_TXHRST_Msk /*!< Command to send a Tx Hard Reset */
#define UCPD_CR_RXMODE_Pos (4U)
#define UCPD_CR_RXMODE_Msk (0x1UL << UCPD_CR_RXMODE_Pos) /*!< 0x00000010 */
#define UCPD_CR_RXMODE UCPD_CR_RXMODE_Msk /*!< Receiver mode */
#define UCPD_CR_PHYRXEN_Pos (5U)
#define UCPD_CR_PHYRXEN_Msk (0x1UL << UCPD_CR_PHYRXEN_Pos) /*!< 0x00000020 */
#define UCPD_CR_PHYRXEN UCPD_CR_PHYRXEN_Msk /*!< Controls enable of USB Power Delivery receiver */
#define UCPD_CR_PHYCCSEL_Pos (6U)
#define UCPD_CR_PHYCCSEL_Msk (0x1UL << UCPD_CR_PHYCCSEL_Pos) /*!< 0x00000040 */
#define UCPD_CR_PHYCCSEL UCPD_CR_PHYCCSEL_Msk /*!< */
#define UCPD_CR_ANASUBMODE_Pos (7U)
#define UCPD_CR_ANASUBMODE_Msk (0x3UL << UCPD_CR_ANASUBMODE_Pos) /*!< 0x00000180 */
#define UCPD_CR_ANASUBMODE UCPD_CR_ANASUBMODE_Msk /*!< Analog PHY sub-mode */
#define UCPD_CR_ANASUBMODE_0 (0x1UL << UCPD_CR_ANASUBMODE_Pos) /*!< 0x00000080 */
#define UCPD_CR_ANASUBMODE_1 (0x2UL << UCPD_CR_ANASUBMODE_Pos) /*!< 0x00000100 */
#define UCPD_CR_ANAMODE_Pos (9U)
#define UCPD_CR_ANAMODE_Msk (0x1UL << UCPD_CR_ANAMODE_Pos) /*!< 0x00000200 */
#define UCPD_CR_ANAMODE UCPD_CR_ANAMODE_Msk /*!< Analog PHY working mode */
#define UCPD_CR_CCENABLE_Pos (10U)
#define UCPD_CR_CCENABLE_Msk (0x3UL << UCPD_CR_CCENABLE_Pos) /*!< 0x00000C00 */
#define UCPD_CR_CCENABLE UCPD_CR_CCENABLE_Msk /*!< */
#define UCPD_CR_CCENABLE_0 (0x1UL << UCPD_CR_CCENABLE_Pos) /*!< 0x00000400 */
#define UCPD_CR_CCENABLE_1 (0x2UL << UCPD_CR_CCENABLE_Pos) /*!< 0x00000800 */
#define UCPD_CR_FRSRXEN_Pos (16U)
#define UCPD_CR_FRSRXEN_Msk (0x1UL << UCPD_CR_FRSRXEN_Pos) /*!< 0x00010000 */
#define UCPD_CR_FRSRXEN UCPD_CR_FRSRXEN_Msk /*!< Enable FRS request detection function */
#define UCPD_CR_FRSTX_Pos (17U)
#define UCPD_CR_FRSTX_Msk (0x1UL << UCPD_CR_FRSTX_Pos) /*!< 0x00020000 */
#define UCPD_CR_FRSTX UCPD_CR_FRSTX_Msk /*!< Signal Fast Role Swap request */
#define UCPD_CR_RDCH_Pos (18U)
#define UCPD_CR_RDCH_Msk (0x1UL << UCPD_CR_RDCH_Pos) /*!< 0x00040000 */
#define UCPD_CR_RDCH UCPD_CR_RDCH_Msk /*!< */
#define UCPD_CR_CC1TCDIS_Pos (20U)
#define UCPD_CR_CC1TCDIS_Msk (0x1UL << UCPD_CR_CC1TCDIS_Pos) /*!< 0x00100000 */
#define UCPD_CR_CC1TCDIS UCPD_CR_CC1TCDIS_Msk /*!< The bit allows the Type-C detector for CC0 to be disabled. */
#define UCPD_CR_CC2TCDIS_Pos (21U)
#define UCPD_CR_CC2TCDIS_Msk (0x1UL << UCPD_CR_CC2TCDIS_Pos) /*!< 0x00200000 */
#define UCPD_CR_CC2TCDIS UCPD_CR_CC2TCDIS_Msk /*!< The bit allows the Type-C detector for CC2 to be disabled. */
/******************** Bits definition for UCPD_IMR register *******************/
#define UCPD_IMR_TXISIE_Pos (0U)
#define UCPD_IMR_TXISIE_Msk (0x1UL << UCPD_IMR_TXISIE_Pos) /*!< 0x00000001 */
#define UCPD_IMR_TXISIE UCPD_IMR_TXISIE_Msk /*!< Enable TXIS interrupt */
#define UCPD_IMR_TXMSGDISCIE_Pos (1U)
#define UCPD_IMR_TXMSGDISCIE_Msk (0x1UL << UCPD_IMR_TXMSGDISCIE_Pos) /*!< 0x00000002 */
#define UCPD_IMR_TXMSGDISCIE UCPD_IMR_TXMSGDISCIE_Msk /*!< Enable TXMSGDISC interrupt */
#define UCPD_IMR_TXMSGSENTIE_Pos (2U)
#define UCPD_IMR_TXMSGSENTIE_Msk (0x1UL << UCPD_IMR_TXMSGSENTIE_Pos) /*!< 0x00000004 */
#define UCPD_IMR_TXMSGSENTIE UCPD_IMR_TXMSGSENTIE_Msk /*!< Enable TXMSGSENT interrupt */
#define UCPD_IMR_TXMSGABTIE_Pos (3U)
#define UCPD_IMR_TXMSGABTIE_Msk (0x1UL << UCPD_IMR_TXMSGABTIE_Pos) /*!< 0x00000008 */
#define UCPD_IMR_TXMSGABTIE UCPD_IMR_TXMSGABTIE_Msk /*!< Enable TXMSGABT interrupt */
#define UCPD_IMR_HRSTDISCIE_Pos (4U)
#define UCPD_IMR_HRSTDISCIE_Msk (0x1UL << UCPD_IMR_HRSTDISCIE_Pos) /*!< 0x00000010 */
#define UCPD_IMR_HRSTDISCIE UCPD_IMR_HRSTDISCIE_Msk /*!< Enable HRSTDISC interrupt */
#define UCPD_IMR_HRSTSENTIE_Pos (5U)
#define UCPD_IMR_HRSTSENTIE_Msk (0x1UL << UCPD_IMR_HRSTSENTIE_Pos) /*!< 0x00000020 */
#define UCPD_IMR_HRSTSENTIE UCPD_IMR_HRSTSENTIE_Msk /*!< Enable HRSTSENT interrupt */
#define UCPD_IMR_TXUNDIE_Pos (6U)
#define UCPD_IMR_TXUNDIE_Msk (0x1UL << UCPD_IMR_TXUNDIE_Pos) /*!< 0x00000040 */
#define UCPD_IMR_TXUNDIE UCPD_IMR_TXUNDIE_Msk /*!< Enable TXUND interrupt */
#define UCPD_IMR_RXNEIE_Pos (8U)
#define UCPD_IMR_RXNEIE_Msk (0x1UL << UCPD_IMR_RXNEIE_Pos) /*!< 0x00000100 */
#define UCPD_IMR_RXNEIE UCPD_IMR_RXNEIE_Msk /*!< Enable RXNE interrupt */
#define UCPD_IMR_RXORDDETIE_Pos (9U)
#define UCPD_IMR_RXORDDETIE_Msk (0x1UL << UCPD_IMR_RXORDDETIE_Pos) /*!< 0x00000200 */
#define UCPD_IMR_RXORDDETIE UCPD_IMR_RXORDDETIE_Msk /*!< Enable RXORDDET interrupt */
#define UCPD_IMR_RXHRSTDETIE_Pos (10U)
#define UCPD_IMR_RXHRSTDETIE_Msk (0x1UL << UCPD_IMR_RXHRSTDETIE_Pos) /*!< 0x00000400 */
#define UCPD_IMR_RXHRSTDETIE UCPD_IMR_RXHRSTDETIE_Msk /*!< Enable RXHRSTDET interrupt */
#define UCPD_IMR_RXOVRIE_Pos (11U)
#define UCPD_IMR_RXOVRIE_Msk (0x1UL << UCPD_IMR_RXOVRIE_Pos) /*!< 0x00000800 */
#define UCPD_IMR_RXOVRIE UCPD_IMR_RXOVRIE_Msk /*!< Enable RXOVR interrupt */
#define UCPD_IMR_RXMSGENDIE_Pos (12U)
#define UCPD_IMR_RXMSGENDIE_Msk (0x1UL << UCPD_IMR_RXMSGENDIE_Pos) /*!< 0x00001000 */
#define UCPD_IMR_RXMSGENDIE UCPD_IMR_RXMSGENDIE_Msk /*!< Enable RXMSGEND interrupt */
#define UCPD_IMR_TYPECEVT1IE_Pos (14U)
#define UCPD_IMR_TYPECEVT1IE_Msk (0x1UL << UCPD_IMR_TYPECEVT1IE_Pos) /*!< 0x00004000 */
#define UCPD_IMR_TYPECEVT1IE UCPD_IMR_TYPECEVT1IE_Msk /*!< Enable TYPECEVT1IE interrupt */
#define UCPD_IMR_TYPECEVT2IE_Pos (15U)
#define UCPD_IMR_TYPECEVT2IE_Msk (0x1UL << UCPD_IMR_TYPECEVT2IE_Pos) /*!< 0x00008000 */
#define UCPD_IMR_TYPECEVT2IE UCPD_IMR_TYPECEVT2IE_Msk /*!< Enable TYPECEVT2IE interrupt */
#define UCPD_IMR_FRSEVTIE_Pos (20U)
#define UCPD_IMR_FRSEVTIE_Msk (0x1UL << UCPD_IMR_FRSEVTIE_Pos) /*!< 0x00100000 */
#define UCPD_IMR_FRSEVTIE UCPD_IMR_FRSEVTIE_Msk /*!< Fast Role Swap interrupt */
/******************** Bits definition for UCPD_SR register ********************/
#define UCPD_SR_TXIS_Pos (0U)
#define UCPD_SR_TXIS_Msk (0x1UL << UCPD_SR_TXIS_Pos) /*!< 0x00000001 */
#define UCPD_SR_TXIS UCPD_SR_TXIS_Msk /*!< Transmit interrupt status */
#define UCPD_SR_TXMSGDISC_Pos (1U)
#define UCPD_SR_TXMSGDISC_Msk (0x1UL << UCPD_SR_TXMSGDISC_Pos) /*!< 0x00000002 */
#define UCPD_SR_TXMSGDISC UCPD_SR_TXMSGDISC_Msk /*!< Transmit message discarded interrupt */
#define UCPD_SR_TXMSGSENT_Pos (2U)
#define UCPD_SR_TXMSGSENT_Msk (0x1UL << UCPD_SR_TXMSGSENT_Pos) /*!< 0x00000004 */
#define UCPD_SR_TXMSGSENT UCPD_SR_TXMSGSENT_Msk /*!< Transmit message sent interrupt */
#define UCPD_SR_TXMSGABT_Pos (3U)
#define UCPD_SR_TXMSGABT_Msk (0x1UL << UCPD_SR_TXMSGABT_Pos) /*!< 0x00000008 */
#define UCPD_SR_TXMSGABT UCPD_SR_TXMSGABT_Msk /*!< Transmit message abort interrupt */
#define UCPD_SR_HRSTDISC_Pos (4U)
#define UCPD_SR_HRSTDISC_Msk (0x1UL << UCPD_SR_HRSTDISC_Pos) /*!< 0x00000010 */
#define UCPD_SR_HRSTDISC UCPD_SR_HRSTDISC_Msk /*!< HRST discarded interrupt */
#define UCPD_SR_HRSTSENT_Pos (5U)
#define UCPD_SR_HRSTSENT_Msk (0x1UL << UCPD_SR_HRSTSENT_Pos) /*!< 0x00000020 */
#define UCPD_SR_HRSTSENT UCPD_SR_HRSTSENT_Msk /*!< HRST sent interrupt */
#define UCPD_SR_TXUND_Pos (6U)
#define UCPD_SR_TXUND_Msk (0x1UL << UCPD_SR_TXUND_Pos) /*!< 0x00000040 */
#define UCPD_SR_TXUND UCPD_SR_TXUND_Msk /*!< Tx data underrun condition interrupt */
#define UCPD_SR_RXNE_Pos (8U)
#define UCPD_SR_RXNE_Msk (0x1UL << UCPD_SR_RXNE_Pos) /*!< 0x00000100 */
#define UCPD_SR_RXNE UCPD_SR_RXNE_Msk /*!< Receive data register not empty interrupt */
#define UCPD_SR_RXORDDET_Pos (9U)
#define UCPD_SR_RXORDDET_Msk (0x1UL << UCPD_SR_RXORDDET_Pos) /*!< 0x00000200 */
#define UCPD_SR_RXORDDET UCPD_SR_RXORDDET_Msk /*!< Rx ordered set (4 K-codes) detected interrupt */
#define UCPD_SR_RXHRSTDET_Pos (10U)
#define UCPD_SR_RXHRSTDET_Msk (0x1UL << UCPD_SR_RXHRSTDET_Pos) /*!< 0x00000400 */
#define UCPD_SR_RXHRSTDET UCPD_SR_RXHRSTDET_Msk /*!< Rx Hard Reset detect interrupt */
#define UCPD_SR_RXOVR_Pos (11U)
#define UCPD_SR_RXOVR_Msk (0x1UL << UCPD_SR_RXOVR_Pos) /*!< 0x00000800 */
#define UCPD_SR_RXOVR UCPD_SR_RXOVR_Msk /*!< Rx data overflow interrupt */
#define UCPD_SR_RXMSGEND_Pos (12U)
#define UCPD_SR_RXMSGEND_Msk (0x1UL << UCPD_SR_RXMSGEND_Pos) /*!< 0x00001000 */
#define UCPD_SR_RXMSGEND UCPD_SR_RXMSGEND_Msk /*!< Rx message received */
#define UCPD_SR_RXERR_Pos (13U)
#define UCPD_SR_RXERR_Msk (0x1UL << UCPD_SR_RXERR_Pos) /*!< 0x00002000 */
#define UCPD_SR_RXERR UCPD_SR_RXERR_Msk /*!< RX Error */
#define UCPD_SR_TYPECEVT1_Pos (14U)
#define UCPD_SR_TYPECEVT1_Msk (0x1UL << UCPD_SR_TYPECEVT1_Pos) /*!< 0x00004000 */
#define UCPD_SR_TYPECEVT1 UCPD_SR_TYPECEVT1_Msk /*!< Type C voltage level event on CC1 */
#define UCPD_SR_TYPECEVT2_Pos (15U)
#define UCPD_SR_TYPECEVT2_Msk (0x1UL << UCPD_SR_TYPECEVT2_Pos) /*!< 0x00008000 */
#define UCPD_SR_TYPECEVT2 UCPD_SR_TYPECEVT2_Msk /*!< Type C voltage level event on CC2 */
#define UCPD_SR_TYPEC_VSTATE_CC1_Pos (16U)
#define UCPD_SR_TYPEC_VSTATE_CC1_Msk (0x3UL << UCPD_SR_TYPEC_VSTATE_CC1_Pos)/*!< 0x00030000 */
#define UCPD_SR_TYPEC_VSTATE_CC1 UCPD_SR_TYPEC_VSTATE_CC1_Msk /*!< Status of DC level on CC1 pin */
#define UCPD_SR_TYPEC_VSTATE_CC1_0 (0x1UL << UCPD_SR_TYPEC_VSTATE_CC1_Pos)/*!< 0x00010000 */
#define UCPD_SR_TYPEC_VSTATE_CC1_1 (0x2UL << UCPD_SR_TYPEC_VSTATE_CC1_Pos)/*!< 0x00020000 */
#define UCPD_SR_TYPEC_VSTATE_CC2_Pos (18U)
#define UCPD_SR_TYPEC_VSTATE_CC2_Msk (0x3UL << UCPD_SR_TYPEC_VSTATE_CC2_Pos)/*!< 0x000C0000 */
#define UCPD_SR_TYPEC_VSTATE_CC2 UCPD_SR_TYPEC_VSTATE_CC2_Msk /*!<Status of DC level on CC2 pin */
#define UCPD_SR_TYPEC_VSTATE_CC2_0 (0x1UL << UCPD_SR_TYPEC_VSTATE_CC2_Pos)/*!< 0x00040000 */
#define UCPD_SR_TYPEC_VSTATE_CC2_1 (0x2UL << UCPD_SR_TYPEC_VSTATE_CC2_Pos)/*!< 0x00080000 */
#define UCPD_SR_FRSEVT_Pos (20U)
#define UCPD_SR_FRSEVT_Msk (0x1UL << UCPD_SR_FRSEVT_Pos) /*!< 0x00100000 */
#define UCPD_SR_FRSEVT UCPD_SR_FRSEVT_Msk /*!< Fast Role Swap detection event */
/******************** Bits definition for UCPD_ICR register *******************/
#define UCPD_ICR_TXMSGDISCCF_Pos (1U)
#define UCPD_ICR_TXMSGDISCCF_Msk (0x1UL << UCPD_ICR_TXMSGDISCCF_Pos) /*!< 0x00000002 */
#define UCPD_ICR_TXMSGDISCCF UCPD_ICR_TXMSGDISCCF_Msk /*!< Tx message discarded flag (TXMSGDISC) clear */
#define UCPD_ICR_TXMSGSENTCF_Pos (2U)
#define UCPD_ICR_TXMSGSENTCF_Msk (0x1UL << UCPD_ICR_TXMSGSENTCF_Pos) /*!< 0x00000004 */
#define UCPD_ICR_TXMSGSENTCF UCPD_ICR_TXMSGSENTCF_Msk /*!< Tx message sent flag (TXMSGSENT) clear */
#define UCPD_ICR_TXMSGABTCF_Pos (3U)
#define UCPD_ICR_TXMSGABTCF_Msk (0x1UL << UCPD_ICR_TXMSGABTCF_Pos) /*!< 0x00000008 */
#define UCPD_ICR_TXMSGABTCF UCPD_ICR_TXMSGABTCF_Msk /*!< Tx message abort flag (TXMSGABT) clear */
#define UCPD_ICR_HRSTDISCCF_Pos (4U)
#define UCPD_ICR_HRSTDISCCF_Msk (0x1UL << UCPD_ICR_HRSTDISCCF_Pos) /*!< 0x00000010 */
#define UCPD_ICR_HRSTDISCCF UCPD_ICR_HRSTDISCCF_Msk /*!< Hard reset discarded flag (HRSTDISC) clear */
#define UCPD_ICR_HRSTSENTCF_Pos (5U)
#define UCPD_ICR_HRSTSENTCF_Msk (0x1UL << UCPD_ICR_HRSTSENTCF_Pos) /*!< 0x00000020 */
#define UCPD_ICR_HRSTSENTCF UCPD_ICR_HRSTSENTCF_Msk /*!< Hard reset sent flag (HRSTSENT) clear */
#define UCPD_ICR_TXUNDCF_Pos (6U)
#define UCPD_ICR_TXUNDCF_Msk (0x1UL << UCPD_ICR_TXUNDCF_Pos) /*!< 0x00000040 */
#define UCPD_ICR_TXUNDCF UCPD_ICR_TXUNDCF_Msk /*!< Tx underflow flag (TXUND) clear */
#define UCPD_ICR_RXORDDETCF_Pos (9U)
#define UCPD_ICR_RXORDDETCF_Msk (0x1UL << UCPD_ICR_RXORDDETCF_Pos) /*!< 0x00000200 */
#define UCPD_ICR_RXORDDETCF UCPD_ICR_RXORDDETCF_Msk /*!< Rx ordered set detect flag (RXORDDET) clear */
#define UCPD_ICR_RXHRSTDETCF_Pos (10U)
#define UCPD_ICR_RXHRSTDETCF_Msk (0x1UL << UCPD_ICR_RXHRSTDETCF_Pos) /*!< 0x00000400 */
#define UCPD_ICR_RXHRSTDETCF UCPD_ICR_RXHRSTDETCF_Msk /*!< Rx Hard Reset detected flag (RXHRSTDET) clear */
#define UCPD_ICR_RXOVRCF_Pos (11U)
#define UCPD_ICR_RXOVRCF_Msk (0x1UL << UCPD_ICR_RXOVRCF_Pos) /*!< 0x00000800 */
#define UCPD_ICR_RXOVRCF UCPD_ICR_RXOVRCF_Msk /*!< Rx overflow flag (RXOVR) clear */
#define UCPD_ICR_RXMSGENDCF_Pos (12U)
#define UCPD_ICR_RXMSGENDCF_Msk (0x1UL << UCPD_ICR_RXMSGENDCF_Pos) /*!< 0x00001000 */
#define UCPD_ICR_RXMSGENDCF UCPD_ICR_RXMSGENDCF_Msk /*!< Rx message received flag (RXMSGEND) clear */
#define UCPD_ICR_TYPECEVT1CF_Pos (14U)
#define UCPD_ICR_TYPECEVT1CF_Msk (0x1UL << UCPD_ICR_TYPECEVT1CF_Pos) /*!< 0x00004000 */
#define UCPD_ICR_TYPECEVT1CF UCPD_ICR_TYPECEVT1CF_Msk /*!< TypeC event (CC1) flag (TYPECEVT1) clear */
#define UCPD_ICR_TYPECEVT2CF_Pos (15U)
#define UCPD_ICR_TYPECEVT2CF_Msk (0x1UL << UCPD_ICR_TYPECEVT2CF_Pos) /*!< 0x00008000 */
#define UCPD_ICR_TYPECEVT2CF UCPD_ICR_TYPECEVT2CF_Msk /*!< TypeC event (CC2) flag (TYPECEVT2) clear */
#define UCPD_ICR_FRSEVTCF_Pos (20U)
#define UCPD_ICR_FRSEVTCF_Msk (0x1UL << UCPD_ICR_FRSEVTCF_Pos) /*!< 0x00100000 */
#define UCPD_ICR_FRSEVTCF UCPD_ICR_FRSEVTCF_Msk /*!< Fast Role Swap event flag clear */
/******************** Bits definition for UCPD_TXORDSET register **************/
#define UCPD_TX_ORDSET_TXORDSET_Pos (0U)
#define UCPD_TX_ORDSET_TXORDSET_Msk (0xFFFFFUL << UCPD_TX_ORDSET_TXORDSET_Pos)/*!< 0x000FFFFF */
#define UCPD_TX_ORDSET_TXORDSET UCPD_TX_ORDSET_TXORDSET_Msk /*!< Tx Ordered Set */
/******************** Bits definition for UCPD_TXPAYSZ register ****************/
#define UCPD_TX_PAYSZ_TXPAYSZ_Pos (0U)
#define UCPD_TX_PAYSZ_TXPAYSZ_Msk (0x3FFUL << UCPD_TX_PAYSZ_TXPAYSZ_Pos)/*!< 0x000003FF */
#define UCPD_TX_PAYSZ_TXPAYSZ UCPD_TX_PAYSZ_TXPAYSZ_Msk /*!< Tx payload size in bytes */
/******************** Bits definition for UCPD_TXDR register *******************/
#define UCPD_TXDR_TXDATA_Pos (0U)
#define UCPD_TXDR_TXDATA_Msk (0xFFUL << UCPD_TXDR_TXDATA_Pos) /*!< 0x000000FF */
#define UCPD_TXDR_TXDATA UCPD_TXDR_TXDATA_Msk /*!< Tx Data Register */
/******************** Bits definition for UCPD_RXORDSET register **************/
#define UCPD_RX_ORDSET_RXORDSET_Pos (0U)
#define UCPD_RX_ORDSET_RXORDSET_Msk (0x7UL << UCPD_RX_ORDSET_RXORDSET_Pos) /*!< 0x00000007 */
#define UCPD_RX_ORDSET_RXORDSET UCPD_RX_ORDSET_RXORDSET_Msk /*!< Rx Ordered Set Code detected */
#define UCPD_RX_ORDSET_RXORDSET_0 (0x1UL << UCPD_RX_ORDSET_RXORDSET_Pos) /*!< 0x00000001 */
#define UCPD_RX_ORDSET_RXORDSET_1 (0x2UL << UCPD_RX_ORDSET_RXORDSET_Pos) /*!< 0x00000002 */
#define UCPD_RX_ORDSET_RXORDSET_2 (0x4UL << UCPD_RX_ORDSET_RXORDSET_Pos) /*!< 0x00000004 */
#define UCPD_RX_ORDSET_RXSOP3OF4_Pos (3U)
#define UCPD_RX_ORDSET_RXSOP3OF4_Msk (0x1UL << UCPD_RX_ORDSET_RXSOP3OF4_Pos)/*!< 0x00000008 */
#define UCPD_RX_ORDSET_RXSOP3OF4 UCPD_RX_ORDSET_RXSOP3OF4_Msk /*!< Rx Ordered Set Debug indication */
#define UCPD_RX_ORDSET_RXSOPKINVALID_Pos (4U)
#define UCPD_RX_ORDSET_RXSOPKINVALID_Msk (0x7UL << UCPD_RX_ORDSET_RXSOPKINVALID_Pos)/*!< 0x00000070 */
#define UCPD_RX_ORDSET_RXSOPKINVALID UCPD_RX_ORDSET_RXSOPKINVALID_Msk /*!< Rx Ordered Set corrupted K-Codes (Debug) */
/******************** Bits definition for UCPD_RXPAYSZ register ****************/
#define UCPD_RX_PAYSZ_RXPAYSZ_Pos (0U)
#define UCPD_RX_PAYSZ_RXPAYSZ_Msk (0x3FFUL << UCPD_RX_PAYSZ_RXPAYSZ_Pos)/*!< 0x000003FF */
#define UCPD_RX_PAYSZ_RXPAYSZ UCPD_RX_PAYSZ_RXPAYSZ_Msk /*!< Rx payload size in bytes */
/******************** Bits definition for UCPD_RXDR register *******************/
#define UCPD_RXDR_RXDATA_Pos (0U)
#define UCPD_RXDR_RXDATA_Msk (0xFFUL << UCPD_RXDR_RXDATA_Pos) /*!< 0x000000FF */
#define UCPD_RXDR_RXDATA UCPD_RXDR_RXDATA_Msk /*!< 8-bit receive data */
/******************** Bits definition for UCPD_RXORDEXT1 register **************/
#define UCPD_RX_ORDEXT1_RXSOPX1_Pos (0U)
#define UCPD_RX_ORDEXT1_RXSOPX1_Msk (0xFFFFFUL << UCPD_RX_ORDEXT1_RXSOPX1_Pos)/*!< 0x000FFFFF */
#define UCPD_RX_ORDEXT1_RXSOPX1 UCPD_RX_ORDEXT1_RXSOPX1_Msk /*!< RX Ordered Set Extension Register 1 */
/******************** Bits definition for UCPD_RXORDEXT2 register **************/
#define UCPD_RX_ORDEXT2_RXSOPX2_Pos (0U)
#define UCPD_RX_ORDEXT2_RXSOPX2_Msk (0xFFFFFUL << UCPD_RX_ORDEXT2_RXSOPX2_Pos)/*!< 0x000FFFFF */
#define UCPD_RX_ORDEXT2_RXSOPX2 UCPD_RX_ORDEXT2_RXSOPX2_Msk /*!< RX Ordered Set Extension Register 1 */
/******************************************************************************/
/* */
/* Window WATCHDOG */
/* */
/******************************************************************************/
/******************* Bit definition for WWDG_CR register ********************/
#define WWDG_CR_T_Pos (0U)
#define WWDG_CR_T_Msk (0x7FUL << WWDG_CR_T_Pos) /*!< 0x0000007F */
#define WWDG_CR_T WWDG_CR_T_Msk /*!<T[6:0] bits (7-Bit counter (MSB to LSB)) */
#define WWDG_CR_T_0 (0x01UL << WWDG_CR_T_Pos) /*!< 0x00000001 */
#define WWDG_CR_T_1 (0x02UL << WWDG_CR_T_Pos) /*!< 0x00000002 */
#define WWDG_CR_T_2 (0x04UL << WWDG_CR_T_Pos) /*!< 0x00000004 */
#define WWDG_CR_T_3 (0x08UL << WWDG_CR_T_Pos) /*!< 0x00000008 */
#define WWDG_CR_T_4 (0x10UL << WWDG_CR_T_Pos) /*!< 0x00000010 */
#define WWDG_CR_T_5 (0x20UL << WWDG_CR_T_Pos) /*!< 0x00000020 */
#define WWDG_CR_T_6 (0x40UL << WWDG_CR_T_Pos) /*!< 0x00000040 */
#define WWDG_CR_WDGA_Pos (7U)
#define WWDG_CR_WDGA_Msk (0x1UL << WWDG_CR_WDGA_Pos) /*!< 0x00000080 */
#define WWDG_CR_WDGA WWDG_CR_WDGA_Msk /*!<Activation bit */
/******************* Bit definition for WWDG_CFR register *******************/
#define WWDG_CFR_W_Pos (0U)
#define WWDG_CFR_W_Msk (0x7FUL << WWDG_CFR_W_Pos) /*!< 0x0000007F */
#define WWDG_CFR_W WWDG_CFR_W_Msk /*!<W[6:0] bits (7-bit window value) */
#define WWDG_CFR_W_0 (0x01UL << WWDG_CFR_W_Pos) /*!< 0x00000001 */
#define WWDG_CFR_W_1 (0x02UL << WWDG_CFR_W_Pos) /*!< 0x00000002 */
#define WWDG_CFR_W_2 (0x04UL << WWDG_CFR_W_Pos) /*!< 0x00000004 */
#define WWDG_CFR_W_3 (0x08UL << WWDG_CFR_W_Pos) /*!< 0x00000008 */
#define WWDG_CFR_W_4 (0x10UL << WWDG_CFR_W_Pos) /*!< 0x00000010 */
#define WWDG_CFR_W_5 (0x20UL << WWDG_CFR_W_Pos) /*!< 0x00000020 */
#define WWDG_CFR_W_6 (0x40UL << WWDG_CFR_W_Pos) /*!< 0x00000040 */
#define WWDG_CFR_WDGTB_Pos (11U)
#define WWDG_CFR_WDGTB_Msk (0x7UL << WWDG_CFR_WDGTB_Pos) /*!< 0x00003800 */
#define WWDG_CFR_WDGTB WWDG_CFR_WDGTB_Msk /*!<WDGTB[2:0] bits (Timer Base) */
#define WWDG_CFR_WDGTB_0 (0x1UL << WWDG_CFR_WDGTB_Pos) /*!< 0x00000800 */
#define WWDG_CFR_WDGTB_1 (0x2UL << WWDG_CFR_WDGTB_Pos) /*!< 0x00001000 */
#define WWDG_CFR_WDGTB_2 (0x4UL << WWDG_CFR_WDGTB_Pos) /*!< 0x00002000 */
#define WWDG_CFR_EWI_Pos (9U)
#define WWDG_CFR_EWI_Msk (0x1UL << WWDG_CFR_EWI_Pos) /*!< 0x00000200 */
#define WWDG_CFR_EWI WWDG_CFR_EWI_Msk /*!<Early Wakeup Interrupt */
/******************* Bit definition for WWDG_SR register ********************/
#define WWDG_SR_EWIF_Pos (0U)
#define WWDG_SR_EWIF_Msk (0x1UL << WWDG_SR_EWIF_Pos) /*!< 0x00000001 */
#define WWDG_SR_EWIF WWDG_SR_EWIF_Msk /*!<Early Wakeup Interrupt Flag */
/**
* @}
*/
/**
* @}
*/
/** @addtogroup Exported_macros
* @{
*/
/******************************* ADC Instances ********************************/
#define IS_ADC_ALL_INSTANCE(INSTANCE) (((INSTANCE) == ADC1) || \
((INSTANCE) == ADC2))
#define IS_ADC_MULTIMODE_MASTER_INSTANCE(INSTANCE) ((INSTANCE) == ADC1)
#define IS_ADC_COMMON_INSTANCE(INSTANCE) ((INSTANCE) == ADC12_COMMON)
/******************************** FDCAN Instances ******************************/
#define IS_FDCAN_ALL_INSTANCE(INSTANCE) ((INSTANCE) == FDCAN1)
#define IS_FDCAN_CONFIG_INSTANCE(INSTANCE) ((INSTANCE) == FDCAN_CONFIG)
/******************************** COMP Instances ******************************/
#define IS_COMP_ALL_INSTANCE(INSTANCE) (((INSTANCE) == COMP1) || \
((INSTANCE) == COMP2) || \
((INSTANCE) == COMP3) || \
((INSTANCE) == COMP4))
/******************************* CORDIC Instances *****************************/
#define IS_CORDIC_ALL_INSTANCE(INSTANCE) ((INSTANCE) == CORDIC)
/******************************* CRC Instances ********************************/
#define IS_CRC_ALL_INSTANCE(INSTANCE) ((INSTANCE) == CRC)
/******************************* DAC Instances ********************************/
#define IS_DAC_ALL_INSTANCE(INSTANCE) (((INSTANCE) == DAC1) || \
((INSTANCE) == DAC3))
/******************************** DMA Instances *******************************/
#define IS_DMA_ALL_INSTANCE(INSTANCE) (((INSTANCE) == DMA1_Channel1) || \
((INSTANCE) == DMA1_Channel2) || \
((INSTANCE) == DMA1_Channel3) || \
((INSTANCE) == DMA1_Channel4) || \
((INSTANCE) == DMA1_Channel5) || \
((INSTANCE) == DMA1_Channel6) || \
((INSTANCE) == DMA2_Channel1) || \
((INSTANCE) == DMA2_Channel2) || \
((INSTANCE) == DMA2_Channel3) || \
((INSTANCE) == DMA2_Channel4) || \
((INSTANCE) == DMA2_Channel5) || \
((INSTANCE) == DMA2_Channel6))
#define IS_DMA_REQUEST_GEN_ALL_INSTANCE(INSTANCE) (((INSTANCE) == DMAMUX1_RequestGenerator0) || \
((INSTANCE) == DMAMUX1_RequestGenerator1) || \
((INSTANCE) == DMAMUX1_RequestGenerator2) || \
((INSTANCE) == DMAMUX1_RequestGenerator3))
/******************************* FMAC Instances *******************************/
#define IS_FMAC_ALL_INSTANCE(INSTANCE) ((INSTANCE) == FMAC)
/******************************* GPIO Instances *******************************/
#define IS_GPIO_ALL_INSTANCE(INSTANCE) (((INSTANCE) == GPIOA) || \
((INSTANCE) == GPIOB) || \
((INSTANCE) == GPIOC) || \
((INSTANCE) == GPIOD) || \
((INSTANCE) == GPIOE) || \
((INSTANCE) == GPIOF) || \
((INSTANCE) == GPIOG))
/******************************* GPIO AF Instances ****************************/
#define IS_GPIO_AF_INSTANCE(INSTANCE) IS_GPIO_ALL_INSTANCE(INSTANCE)
/**************************** GPIO Lock Instances *****************************/
#define IS_GPIO_LOCK_INSTANCE(INSTANCE) IS_GPIO_ALL_INSTANCE(INSTANCE)
/******************************** I2C Instances *******************************/
#define IS_I2C_ALL_INSTANCE(INSTANCE) (((INSTANCE) == I2C1) || \
((INSTANCE) == I2C2) || \
((INSTANCE) == I2C3))
/****************** I2C Instances : wakeup capability from stop modes *********/
#define IS_I2C_WAKEUP_FROMSTOP_INSTANCE(INSTANCE) IS_I2C_ALL_INSTANCE(INSTANCE)
/****************************** OPAMP Instances *******************************/
#define IS_OPAMP_ALL_INSTANCE(INSTANCE) (((INSTANCE) == OPAMP1) || \
((INSTANCE) == OPAMP2) || \
((INSTANCE) == OPAMP3))
/******************************** PCD Instances *******************************/
#define IS_PCD_ALL_INSTANCE(INSTANCE) ((INSTANCE) == USB)
/******************************* RNG Instances ********************************/
#define IS_RNG_ALL_INSTANCE(INSTANCE) ((INSTANCE) == RNG)
/****************************** RTC Instances *********************************/
#define IS_RTC_ALL_INSTANCE(INSTANCE) ((INSTANCE) == RTC)
#define IS_TAMP_ALL_INSTANCE(INSTANCE) ((INSTANCE) == TAMP)
/****************************** SMBUS Instances *******************************/
#define IS_SMBUS_ALL_INSTANCE(INSTANCE) (((INSTANCE) == I2C1) || \
((INSTANCE) == I2C2) || \
((INSTANCE) == I2C3))
/******************************** SAI Instances *******************************/
#define IS_SAI_ALL_INSTANCE(INSTANCE) (((INSTANCE) == SAI1_Block_A) || ((INSTANCE) == SAI1_Block_B))
/******************************** SPI Instances *******************************/
#define IS_SPI_ALL_INSTANCE(INSTANCE) (((INSTANCE) == SPI1) || \
((INSTANCE) == SPI2) || \
((INSTANCE) == SPI3))
/******************************** I2S Instances *******************************/
#define IS_I2S_ALL_INSTANCE(__INSTANCE__) (((__INSTANCE__) == SPI2) || \
((__INSTANCE__) == SPI3))
/****************** LPTIM Instances : All supported instances *****************/
#define IS_LPTIM_INSTANCE(INSTANCE) ((INSTANCE) == LPTIM1)
/****************** LPTIM Instances : supporting encoder interface **************/
#define IS_LPTIM_ENCODER_INTERFACE_INSTANCE(INSTANCE) ((INSTANCE) == LPTIM1)
/****************** LPTIM Instances : All supported instances *****************/
#define IS_LPTIM_ENCODER_INSTANCE(INSTANCE) ((INSTANCE) == LPTIM1)
/****************** TIM Instances : All supported instances *******************/
#define IS_TIM_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM6) || \
((INSTANCE) == TIM7) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : supporting 32 bits counter ****************/
#define IS_TIM_32B_COUNTER_INSTANCE(INSTANCE) ((INSTANCE) == TIM2)
/****************** TIM Instances : supporting the break function *************/
#define IS_TIM_BREAK_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/************** TIM Instances : supporting Break source selection *************/
#define IS_TIM_BREAKSOURCE_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : supporting 2 break inputs *****************/
#define IS_TIM_BKIN2_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8))
/************* TIM Instances : at least 1 capture/compare channel *************/
#define IS_TIM_CC1_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/************ TIM Instances : at least 2 capture/compare channels *************/
#define IS_TIM_CC2_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15))
/************ TIM Instances : at least 3 capture/compare channels *************/
#define IS_TIM_CC3_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/************ TIM Instances : at least 4 capture/compare channels *************/
#define IS_TIM_CC4_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : at least 5 capture/compare channels *******/
#define IS_TIM_CC5_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : at least 6 capture/compare channels *******/
#define IS_TIM_CC6_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8))
/************ TIM Instances : DMA requests generation (TIMx_DIER.COMDE) *******/
#define IS_TIM_CCDMA_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : DMA requests generation (TIMx_DIER.UDE) ***/
#define IS_TIM_DMA_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM6) || \
((INSTANCE) == TIM7) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/************ TIM Instances : DMA requests generation (TIMx_DIER.CCxDE) *******/
#define IS_TIM_DMA_CC_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/******************** TIM Instances : DMA burst feature ***********************/
#define IS_TIM_DMABURST_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/******************* TIM Instances : output(s) available **********************/
#define IS_TIM_CCX_INSTANCE(INSTANCE, CHANNEL) \
((((INSTANCE) == TIM1) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2) || \
((CHANNEL) == TIM_CHANNEL_3) || \
((CHANNEL) == TIM_CHANNEL_4) || \
((CHANNEL) == TIM_CHANNEL_5) || \
((CHANNEL) == TIM_CHANNEL_6))) \
|| \
(((INSTANCE) == TIM2) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2) || \
((CHANNEL) == TIM_CHANNEL_3) || \
((CHANNEL) == TIM_CHANNEL_4))) \
|| \
(((INSTANCE) == TIM3) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2) || \
((CHANNEL) == TIM_CHANNEL_3) || \
((CHANNEL) == TIM_CHANNEL_4))) \
|| \
(((INSTANCE) == TIM4) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2) || \
((CHANNEL) == TIM_CHANNEL_3) || \
((CHANNEL) == TIM_CHANNEL_4))) \
|| \
(((INSTANCE) == TIM8) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2) || \
((CHANNEL) == TIM_CHANNEL_3) || \
((CHANNEL) == TIM_CHANNEL_4) || \
((CHANNEL) == TIM_CHANNEL_5) || \
((CHANNEL) == TIM_CHANNEL_6))) \
|| \
(((INSTANCE) == TIM15) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2))) \
|| \
(((INSTANCE) == TIM16) && \
(((CHANNEL) == TIM_CHANNEL_1))) \
|| \
(((INSTANCE) == TIM17) && \
(((CHANNEL) == TIM_CHANNEL_1))))
/****************** TIM Instances : supporting complementary output(s) ********/
#define IS_TIM_CCXN_INSTANCE(INSTANCE, CHANNEL) \
((((INSTANCE) == TIM1) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2) || \
((CHANNEL) == TIM_CHANNEL_3) || \
((CHANNEL) == TIM_CHANNEL_4))) \
|| \
(((INSTANCE) == TIM8) && \
(((CHANNEL) == TIM_CHANNEL_1) || \
((CHANNEL) == TIM_CHANNEL_2) || \
((CHANNEL) == TIM_CHANNEL_3) || \
((CHANNEL) == TIM_CHANNEL_4))) \
|| \
(((INSTANCE) == TIM15) && \
((CHANNEL) == TIM_CHANNEL_1)) \
|| \
(((INSTANCE) == TIM16) && \
((CHANNEL) == TIM_CHANNEL_1)) \
|| \
(((INSTANCE) == TIM17) && \
((CHANNEL) == TIM_CHANNEL_1)))
/****************** TIM Instances : supporting clock division *****************/
#define IS_TIM_CLOCK_DIVISION_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****** TIM Instances : supporting external clock mode 1 for ETRF input *******/
#define IS_TIM_CLOCKSOURCE_ETRMODE1_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/****** TIM Instances : supporting external clock mode 2 for ETRF input *******/
#define IS_TIM_CLOCKSOURCE_ETRMODE2_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : supporting external clock mode 1 for TIX inputs*/
#define IS_TIM_CLOCKSOURCE_TIX_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15))
/****************** TIM Instances : supporting internal trigger inputs(ITRX) *******/
#define IS_TIM_CLOCKSOURCE_ITRX_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15))
/****************** TIM Instances : supporting combined 3-phase PWM mode ******/
#define IS_TIM_COMBINED3PHASEPWM_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : supporting commutation event generation ***/
#define IS_TIM_COMMUTATION_EVENT_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : supporting counting mode selection ********/
#define IS_TIM_COUNTER_MODE_SELECT_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : supporting encoder interface **************/
#define IS_TIM_ENCODER_INTERFACE_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : supporting Hall sensor interface **********/
#define IS_TIM_HALL_SENSOR_INTERFACE_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15))
/**************** TIM Instances : external trigger input available ************/
#define IS_TIM_ETR_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/************* TIM Instances : supporting ETR source selection ***************/
#define IS_TIM_ETRSEL_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/****** TIM Instances : Master mode available (TIMx_CR2.MMS available )********/
#define IS_TIM_MASTER_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM6) || \
((INSTANCE) == TIM7) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15))
/*********** TIM Instances : Slave mode available (TIMx_SMCR available )*******/
#define IS_TIM_SLAVE_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15))
/****************** TIM Instances : supporting OCxREF clear *******************/
#define IS_TIM_OCXREF_CLEAR_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : supporting bitfield OCCS in SMCR register *******************/
#define IS_TIM_OCCS_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : remapping capability **********************/
#define IS_TIM_REMAP_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : supporting repetition counter *************/
#define IS_TIM_REPETITION_COUNTER_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : supporting ADC triggering through TRGO2 ***/
#define IS_TIM_TRGO2_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8))
/******************* TIM Instances : Timer input XOR function *****************/
#define IS_TIM_XOR_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15))
/******************* TIM Instances : Timer input selection ********************/
#define IS_TIM_TISEL_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM2) || \
((INSTANCE) == TIM3) || \
((INSTANCE) == TIM4) || \
((INSTANCE) == TIM8) || \
((INSTANCE) == TIM15) || \
((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/****************** TIM Instances : Advanced timer instances *******************/
#define IS_TIM_ADVANCED_INSTANCE(INSTANCE) (((INSTANCE) == TIM1) || \
((INSTANCE) == TIM8))
/****************** TIM Instances : supporting HSE/32 request instances *******************/
#define IS_TIM_HSE32_INSTANCE(INSTANCE) (((INSTANCE) == TIM16) || \
((INSTANCE) == TIM17))
/******************** USART Instances : Synchronous mode **********************/
#define IS_USART_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3))
/******************** UART Instances : Asynchronous mode **********************/
#define IS_UART_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4))
/*********************** UART Instances : FIFO mode ***************************/
#define IS_UART_FIFO_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4) || \
((INSTANCE) == LPUART1))
/*********************** UART Instances : SPI Slave mode **********************/
#define IS_UART_SPI_SLAVE_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3))
/****************** UART Instances : Auto Baud Rate detection ****************/
#define IS_USART_AUTOBAUDRATE_DETECTION_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4))
/****************** UART Instances : Driver Enable *****************/
#define IS_UART_DRIVER_ENABLE_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4) || \
((INSTANCE) == LPUART1))
/******************** UART Instances : Half-Duplex mode **********************/
#define IS_UART_HALFDUPLEX_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4) || \
((INSTANCE) == LPUART1))
/****************** UART Instances : Hardware Flow control ********************/
#define IS_UART_HWFLOW_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4) || \
((INSTANCE) == LPUART1))
/******************** UART Instances : LIN mode **********************/
#define IS_UART_LIN_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4))
/******************** UART Instances : Wake-up from Stop mode **********************/
#define IS_UART_WAKEUP_FROMSTOP_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4) || \
((INSTANCE) == LPUART1))
/*********************** UART Instances : IRDA mode ***************************/
#define IS_IRDA_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3) || \
((INSTANCE) == UART4))
/********************* USART Instances : Smard card mode ***********************/
#define IS_SMARTCARD_INSTANCE(INSTANCE) (((INSTANCE) == USART1) || \
((INSTANCE) == USART2) || \
((INSTANCE) == USART3))
/******************** LPUART Instance *****************************************/
#define IS_LPUART_INSTANCE(INSTANCE) ((INSTANCE) == LPUART1)
/****************************** IWDG Instances ********************************/
#define IS_IWDG_ALL_INSTANCE(INSTANCE) ((INSTANCE) == IWDG)
/****************************** WWDG Instances ********************************/
#define IS_WWDG_ALL_INSTANCE(INSTANCE) ((INSTANCE) == WWDG)
/****************************** UCPD Instances ********************************/
#define IS_UCPD_ALL_INSTANCE(INSTANCE) ((INSTANCE) == UCPD1)
/******************************* USB Instances *******************************/
#define IS_USB_ALL_INSTANCE(INSTANCE) ((INSTANCE) == USB)
/**
* @}
*/
/******************************************************************************/
/* For a painless codes migration between the STM32G4xx device product */
/* lines, the aliases defined below are put in place to overcome the */
/* differences in the interrupt handlers and IRQn definitions. */
/* No need to update developed interrupt code when moving across */
/* product lines within the same STM32G4 Family */
/******************************************************************************/
/* Aliases for __IRQn */
#define TIM7_DAC_IRQn TIM7_IRQn
#define COMP4_5_6_IRQn COMP4_IRQn
/* Aliases for __IRQHandler */
#define TIM7_DAC_IRQHandler TIM7_IRQHandler
#define COMP4_5_6_IRQHandler COMP4_IRQHandler
#ifdef __cplusplus
}
#endif /* __cplusplus */
#endif /* __STM32G431xx_H */
/**
* @}
*/
/**
* @}
*/
| 988,858 | C | 74.335898 | 180 | 0.51183 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm7.h | /**************************************************************************//**
* @file core_cm7.h
* @brief CMSIS Cortex-M7 Core Peripheral Access Layer Header File
* @version V5.1.1
* @date 28. March 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM7_H_GENERIC
#define __CORE_CM7_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M7
@{
*/
#include "cmsis_version.h"
/* CMSIS CM7 definitions */
#define __CM7_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM7_CMSIS_VERSION_SUB ( __CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM7_CMSIS_VERSION ((__CM7_CMSIS_VERSION_MAIN << 16U) | \
__CM7_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (7U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
For this, __FPU_PRESENT has to be checked prior to making use of FPU specific registers and functions.
*/
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#warning "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM7_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM7_H_DEPENDANT
#define __CORE_CM7_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM7_REV
#define __CM7_REV 0x0000U
#warning "__CM7_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __ICACHE_PRESENT
#define __ICACHE_PRESENT 0U
#warning "__ICACHE_PRESENT not defined in device header file; using default!"
#endif
#ifndef __DCACHE_PRESENT
#define __DCACHE_PRESENT 0U
#warning "__DCACHE_PRESENT not defined in device header file; using default!"
#endif
#ifndef __DTCM_PRESENT
#define __DTCM_PRESENT 0U
#warning "__DTCM_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M7 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core FPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:16; /*!< bit: 0..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:7; /*!< bit: 20..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
#define APSR_GE_Pos 16U /*!< APSR: GE Position */
#define APSR_GE_Msk (0xFUL << APSR_GE_Pos) /*!< APSR: GE Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:1; /*!< bit: 9 Reserved */
uint32_t ICI_IT_1:6; /*!< bit: 10..15 ICI/IT part 1 */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:4; /*!< bit: 20..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit */
uint32_t ICI_IT_2:2; /*!< bit: 25..26 ICI/IT part 2 */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_ICI_IT_2_Pos 25U /*!< xPSR: ICI/IT part 2 Position */
#define xPSR_ICI_IT_2_Msk (3UL << xPSR_ICI_IT_2_Pos) /*!< xPSR: ICI/IT part 2 Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_GE_Pos 16U /*!< xPSR: GE Position */
#define xPSR_GE_Msk (0xFUL << xPSR_GE_Pos) /*!< xPSR: GE Mask */
#define xPSR_ICI_IT_1_Pos 10U /*!< xPSR: ICI/IT part 1 Position */
#define xPSR_ICI_IT_1_Msk (0x3FUL << xPSR_ICI_IT_1_Pos) /*!< xPSR: ICI/IT part 1 Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t FPCA:1; /*!< bit: 2 FP extension active flag */
uint32_t _reserved0:29; /*!< bit: 3..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_FPCA_Pos 2U /*!< CONTROL: FPCA Position */
#define CONTROL_FPCA_Msk (1UL << CONTROL_FPCA_Pos) /*!< CONTROL: FPCA Mask */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[8U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[24U];
__IOM uint32_t ICER[8U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RESERVED1[24U];
__IOM uint32_t ISPR[8U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[24U];
__IOM uint32_t ICPR[8U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[24U];
__IOM uint32_t IABR[8U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[56U];
__IOM uint8_t IP[240U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED5[644U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHPR[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t ID_PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t ID_DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ID_AFR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t ID_MFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ID_ISAR[5U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
uint32_t RESERVED0[1U];
__IM uint32_t CLIDR; /*!< Offset: 0x078 (R/ ) Cache Level ID register */
__IM uint32_t CTR; /*!< Offset: 0x07C (R/ ) Cache Type register */
__IM uint32_t CCSIDR; /*!< Offset: 0x080 (R/ ) Cache Size ID Register */
__IOM uint32_t CSSELR; /*!< Offset: 0x084 (R/W) Cache Size Selection Register */
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
uint32_t RESERVED3[93U];
__OM uint32_t STIR; /*!< Offset: 0x200 ( /W) Software Triggered Interrupt Register */
uint32_t RESERVED4[15U];
__IM uint32_t MVFR0; /*!< Offset: 0x240 (R/ ) Media and VFP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x244 (R/ ) Media and VFP Feature Register 1 */
__IM uint32_t MVFR2; /*!< Offset: 0x248 (R/ ) Media and VFP Feature Register 2 */
uint32_t RESERVED5[1U];
__OM uint32_t ICIALLU; /*!< Offset: 0x250 ( /W) I-Cache Invalidate All to PoU */
uint32_t RESERVED6[1U];
__OM uint32_t ICIMVAU; /*!< Offset: 0x258 ( /W) I-Cache Invalidate by MVA to PoU */
__OM uint32_t DCIMVAC; /*!< Offset: 0x25C ( /W) D-Cache Invalidate by MVA to PoC */
__OM uint32_t DCISW; /*!< Offset: 0x260 ( /W) D-Cache Invalidate by Set-way */
__OM uint32_t DCCMVAU; /*!< Offset: 0x264 ( /W) D-Cache Clean by MVA to PoU */
__OM uint32_t DCCMVAC; /*!< Offset: 0x268 ( /W) D-Cache Clean by MVA to PoC */
__OM uint32_t DCCSW; /*!< Offset: 0x26C ( /W) D-Cache Clean by Set-way */
__OM uint32_t DCCIMVAC; /*!< Offset: 0x270 ( /W) D-Cache Clean and Invalidate by MVA to PoC */
__OM uint32_t DCCISW; /*!< Offset: 0x274 ( /W) D-Cache Clean and Invalidate by Set-way */
uint32_t RESERVED7[6U];
__IOM uint32_t ITCMCR; /*!< Offset: 0x290 (R/W) Instruction Tightly-Coupled Memory Control Register */
__IOM uint32_t DTCMCR; /*!< Offset: 0x294 (R/W) Data Tightly-Coupled Memory Control Registers */
__IOM uint32_t AHBPCR; /*!< Offset: 0x298 (R/W) AHBP Control Register */
__IOM uint32_t CACR; /*!< Offset: 0x29C (R/W) L1 Cache Control Register */
__IOM uint32_t AHBSCR; /*!< Offset: 0x2A0 (R/W) AHB Slave Control Register */
uint32_t RESERVED8[1U];
__IOM uint32_t ABFSR; /*!< Offset: 0x2A8 (R/W) Auxiliary Bus Fault Status Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
#define SCB_AIRCR_VECTRESET_Pos 0U /*!< SCB AIRCR: VECTRESET Position */
#define SCB_AIRCR_VECTRESET_Msk (1UL /*<< SCB_AIRCR_VECTRESET_Pos*/) /*!< SCB AIRCR: VECTRESET Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_BP_Pos 18U /*!< SCB CCR: Branch prediction enable bit Position */
#define SCB_CCR_BP_Msk (1UL << SCB_CCR_BP_Pos) /*!< SCB CCR: Branch prediction enable bit Mask */
#define SCB_CCR_IC_Pos 17U /*!< SCB CCR: Instruction cache enable bit Position */
#define SCB_CCR_IC_Msk (1UL << SCB_CCR_IC_Pos) /*!< SCB CCR: Instruction cache enable bit Mask */
#define SCB_CCR_DC_Pos 16U /*!< SCB CCR: Cache enable bit Position */
#define SCB_CCR_DC_Msk (1UL << SCB_CCR_DC_Pos) /*!< SCB CCR: Cache enable bit Mask */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
#define SCB_CCR_NONBASETHRDENA_Pos 0U /*!< SCB CCR: NONBASETHRDENA Position */
#define SCB_CCR_NONBASETHRDENA_Msk (1UL /*<< SCB_CCR_NONBASETHRDENA_Pos*/) /*!< SCB CCR: NONBASETHRDENA Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MLSPERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 5U) /*!< SCB CFSR (MMFSR): MLSPERR Position */
#define SCB_CFSR_MLSPERR_Msk (1UL << SCB_CFSR_MLSPERR_Pos) /*!< SCB CFSR (MMFSR): MLSPERR Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_LSPERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 5U) /*!< SCB CFSR (BFSR): LSPERR Position */
#define SCB_CFSR_LSPERR_Msk (1UL << SCB_CFSR_LSPERR_Pos) /*!< SCB CFSR (BFSR): LSPERR Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/* SCB Cache Level ID Register Definitions */
#define SCB_CLIDR_LOUU_Pos 27U /*!< SCB CLIDR: LoUU Position */
#define SCB_CLIDR_LOUU_Msk (7UL << SCB_CLIDR_LOUU_Pos) /*!< SCB CLIDR: LoUU Mask */
#define SCB_CLIDR_LOC_Pos 24U /*!< SCB CLIDR: LoC Position */
#define SCB_CLIDR_LOC_Msk (7UL << SCB_CLIDR_LOC_Pos) /*!< SCB CLIDR: LoC Mask */
/* SCB Cache Type Register Definitions */
#define SCB_CTR_FORMAT_Pos 29U /*!< SCB CTR: Format Position */
#define SCB_CTR_FORMAT_Msk (7UL << SCB_CTR_FORMAT_Pos) /*!< SCB CTR: Format Mask */
#define SCB_CTR_CWG_Pos 24U /*!< SCB CTR: CWG Position */
#define SCB_CTR_CWG_Msk (0xFUL << SCB_CTR_CWG_Pos) /*!< SCB CTR: CWG Mask */
#define SCB_CTR_ERG_Pos 20U /*!< SCB CTR: ERG Position */
#define SCB_CTR_ERG_Msk (0xFUL << SCB_CTR_ERG_Pos) /*!< SCB CTR: ERG Mask */
#define SCB_CTR_DMINLINE_Pos 16U /*!< SCB CTR: DminLine Position */
#define SCB_CTR_DMINLINE_Msk (0xFUL << SCB_CTR_DMINLINE_Pos) /*!< SCB CTR: DminLine Mask */
#define SCB_CTR_IMINLINE_Pos 0U /*!< SCB CTR: ImInLine Position */
#define SCB_CTR_IMINLINE_Msk (0xFUL /*<< SCB_CTR_IMINLINE_Pos*/) /*!< SCB CTR: ImInLine Mask */
/* SCB Cache Size ID Register Definitions */
#define SCB_CCSIDR_WT_Pos 31U /*!< SCB CCSIDR: WT Position */
#define SCB_CCSIDR_WT_Msk (1UL << SCB_CCSIDR_WT_Pos) /*!< SCB CCSIDR: WT Mask */
#define SCB_CCSIDR_WB_Pos 30U /*!< SCB CCSIDR: WB Position */
#define SCB_CCSIDR_WB_Msk (1UL << SCB_CCSIDR_WB_Pos) /*!< SCB CCSIDR: WB Mask */
#define SCB_CCSIDR_RA_Pos 29U /*!< SCB CCSIDR: RA Position */
#define SCB_CCSIDR_RA_Msk (1UL << SCB_CCSIDR_RA_Pos) /*!< SCB CCSIDR: RA Mask */
#define SCB_CCSIDR_WA_Pos 28U /*!< SCB CCSIDR: WA Position */
#define SCB_CCSIDR_WA_Msk (1UL << SCB_CCSIDR_WA_Pos) /*!< SCB CCSIDR: WA Mask */
#define SCB_CCSIDR_NUMSETS_Pos 13U /*!< SCB CCSIDR: NumSets Position */
#define SCB_CCSIDR_NUMSETS_Msk (0x7FFFUL << SCB_CCSIDR_NUMSETS_Pos) /*!< SCB CCSIDR: NumSets Mask */
#define SCB_CCSIDR_ASSOCIATIVITY_Pos 3U /*!< SCB CCSIDR: Associativity Position */
#define SCB_CCSIDR_ASSOCIATIVITY_Msk (0x3FFUL << SCB_CCSIDR_ASSOCIATIVITY_Pos) /*!< SCB CCSIDR: Associativity Mask */
#define SCB_CCSIDR_LINESIZE_Pos 0U /*!< SCB CCSIDR: LineSize Position */
#define SCB_CCSIDR_LINESIZE_Msk (7UL /*<< SCB_CCSIDR_LINESIZE_Pos*/) /*!< SCB CCSIDR: LineSize Mask */
/* SCB Cache Size Selection Register Definitions */
#define SCB_CSSELR_LEVEL_Pos 1U /*!< SCB CSSELR: Level Position */
#define SCB_CSSELR_LEVEL_Msk (7UL << SCB_CSSELR_LEVEL_Pos) /*!< SCB CSSELR: Level Mask */
#define SCB_CSSELR_IND_Pos 0U /*!< SCB CSSELR: InD Position */
#define SCB_CSSELR_IND_Msk (1UL /*<< SCB_CSSELR_IND_Pos*/) /*!< SCB CSSELR: InD Mask */
/* SCB Software Triggered Interrupt Register Definitions */
#define SCB_STIR_INTID_Pos 0U /*!< SCB STIR: INTID Position */
#define SCB_STIR_INTID_Msk (0x1FFUL /*<< SCB_STIR_INTID_Pos*/) /*!< SCB STIR: INTID Mask */
/* SCB D-Cache Invalidate by Set-way Register Definitions */
#define SCB_DCISW_WAY_Pos 30U /*!< SCB DCISW: Way Position */
#define SCB_DCISW_WAY_Msk (3UL << SCB_DCISW_WAY_Pos) /*!< SCB DCISW: Way Mask */
#define SCB_DCISW_SET_Pos 5U /*!< SCB DCISW: Set Position */
#define SCB_DCISW_SET_Msk (0x1FFUL << SCB_DCISW_SET_Pos) /*!< SCB DCISW: Set Mask */
/* SCB D-Cache Clean by Set-way Register Definitions */
#define SCB_DCCSW_WAY_Pos 30U /*!< SCB DCCSW: Way Position */
#define SCB_DCCSW_WAY_Msk (3UL << SCB_DCCSW_WAY_Pos) /*!< SCB DCCSW: Way Mask */
#define SCB_DCCSW_SET_Pos 5U /*!< SCB DCCSW: Set Position */
#define SCB_DCCSW_SET_Msk (0x1FFUL << SCB_DCCSW_SET_Pos) /*!< SCB DCCSW: Set Mask */
/* SCB D-Cache Clean and Invalidate by Set-way Register Definitions */
#define SCB_DCCISW_WAY_Pos 30U /*!< SCB DCCISW: Way Position */
#define SCB_DCCISW_WAY_Msk (3UL << SCB_DCCISW_WAY_Pos) /*!< SCB DCCISW: Way Mask */
#define SCB_DCCISW_SET_Pos 5U /*!< SCB DCCISW: Set Position */
#define SCB_DCCISW_SET_Msk (0x1FFUL << SCB_DCCISW_SET_Pos) /*!< SCB DCCISW: Set Mask */
/* Instruction Tightly-Coupled Memory Control Register Definitions */
#define SCB_ITCMCR_SZ_Pos 3U /*!< SCB ITCMCR: SZ Position */
#define SCB_ITCMCR_SZ_Msk (0xFUL << SCB_ITCMCR_SZ_Pos) /*!< SCB ITCMCR: SZ Mask */
#define SCB_ITCMCR_RETEN_Pos 2U /*!< SCB ITCMCR: RETEN Position */
#define SCB_ITCMCR_RETEN_Msk (1UL << SCB_ITCMCR_RETEN_Pos) /*!< SCB ITCMCR: RETEN Mask */
#define SCB_ITCMCR_RMW_Pos 1U /*!< SCB ITCMCR: RMW Position */
#define SCB_ITCMCR_RMW_Msk (1UL << SCB_ITCMCR_RMW_Pos) /*!< SCB ITCMCR: RMW Mask */
#define SCB_ITCMCR_EN_Pos 0U /*!< SCB ITCMCR: EN Position */
#define SCB_ITCMCR_EN_Msk (1UL /*<< SCB_ITCMCR_EN_Pos*/) /*!< SCB ITCMCR: EN Mask */
/* Data Tightly-Coupled Memory Control Register Definitions */
#define SCB_DTCMCR_SZ_Pos 3U /*!< SCB DTCMCR: SZ Position */
#define SCB_DTCMCR_SZ_Msk (0xFUL << SCB_DTCMCR_SZ_Pos) /*!< SCB DTCMCR: SZ Mask */
#define SCB_DTCMCR_RETEN_Pos 2U /*!< SCB DTCMCR: RETEN Position */
#define SCB_DTCMCR_RETEN_Msk (1UL << SCB_DTCMCR_RETEN_Pos) /*!< SCB DTCMCR: RETEN Mask */
#define SCB_DTCMCR_RMW_Pos 1U /*!< SCB DTCMCR: RMW Position */
#define SCB_DTCMCR_RMW_Msk (1UL << SCB_DTCMCR_RMW_Pos) /*!< SCB DTCMCR: RMW Mask */
#define SCB_DTCMCR_EN_Pos 0U /*!< SCB DTCMCR: EN Position */
#define SCB_DTCMCR_EN_Msk (1UL /*<< SCB_DTCMCR_EN_Pos*/) /*!< SCB DTCMCR: EN Mask */
/* AHBP Control Register Definitions */
#define SCB_AHBPCR_SZ_Pos 1U /*!< SCB AHBPCR: SZ Position */
#define SCB_AHBPCR_SZ_Msk (7UL << SCB_AHBPCR_SZ_Pos) /*!< SCB AHBPCR: SZ Mask */
#define SCB_AHBPCR_EN_Pos 0U /*!< SCB AHBPCR: EN Position */
#define SCB_AHBPCR_EN_Msk (1UL /*<< SCB_AHBPCR_EN_Pos*/) /*!< SCB AHBPCR: EN Mask */
/* L1 Cache Control Register Definitions */
#define SCB_CACR_FORCEWT_Pos 2U /*!< SCB CACR: FORCEWT Position */
#define SCB_CACR_FORCEWT_Msk (1UL << SCB_CACR_FORCEWT_Pos) /*!< SCB CACR: FORCEWT Mask */
#define SCB_CACR_ECCEN_Pos 1U /*!< SCB CACR: ECCEN Position */
#define SCB_CACR_ECCEN_Msk (1UL << SCB_CACR_ECCEN_Pos) /*!< SCB CACR: ECCEN Mask */
#define SCB_CACR_SIWT_Pos 0U /*!< SCB CACR: SIWT Position */
#define SCB_CACR_SIWT_Msk (1UL /*<< SCB_CACR_SIWT_Pos*/) /*!< SCB CACR: SIWT Mask */
/* AHBS Control Register Definitions */
#define SCB_AHBSCR_INITCOUNT_Pos 11U /*!< SCB AHBSCR: INITCOUNT Position */
#define SCB_AHBSCR_INITCOUNT_Msk (0x1FUL << SCB_AHBPCR_INITCOUNT_Pos) /*!< SCB AHBSCR: INITCOUNT Mask */
#define SCB_AHBSCR_TPRI_Pos 2U /*!< SCB AHBSCR: TPRI Position */
#define SCB_AHBSCR_TPRI_Msk (0x1FFUL << SCB_AHBPCR_TPRI_Pos) /*!< SCB AHBSCR: TPRI Mask */
#define SCB_AHBSCR_CTL_Pos 0U /*!< SCB AHBSCR: CTL Position*/
#define SCB_AHBSCR_CTL_Msk (3UL /*<< SCB_AHBPCR_CTL_Pos*/) /*!< SCB AHBSCR: CTL Mask */
/* Auxiliary Bus Fault Status Register Definitions */
#define SCB_ABFSR_AXIMTYPE_Pos 8U /*!< SCB ABFSR: AXIMTYPE Position*/
#define SCB_ABFSR_AXIMTYPE_Msk (3UL << SCB_ABFSR_AXIMTYPE_Pos) /*!< SCB ABFSR: AXIMTYPE Mask */
#define SCB_ABFSR_EPPB_Pos 4U /*!< SCB ABFSR: EPPB Position*/
#define SCB_ABFSR_EPPB_Msk (1UL << SCB_ABFSR_EPPB_Pos) /*!< SCB ABFSR: EPPB Mask */
#define SCB_ABFSR_AXIM_Pos 3U /*!< SCB ABFSR: AXIM Position*/
#define SCB_ABFSR_AXIM_Msk (1UL << SCB_ABFSR_AXIM_Pos) /*!< SCB ABFSR: AXIM Mask */
#define SCB_ABFSR_AHBP_Pos 2U /*!< SCB ABFSR: AHBP Position*/
#define SCB_ABFSR_AHBP_Msk (1UL << SCB_ABFSR_AHBP_Pos) /*!< SCB ABFSR: AHBP Mask */
#define SCB_ABFSR_DTCM_Pos 1U /*!< SCB ABFSR: DTCM Position*/
#define SCB_ABFSR_DTCM_Msk (1UL << SCB_ABFSR_DTCM_Pos) /*!< SCB ABFSR: DTCM Mask */
#define SCB_ABFSR_ITCM_Pos 0U /*!< SCB ABFSR: ITCM Position*/
#define SCB_ABFSR_ITCM_Msk (1UL /*<< SCB_ABFSR_ITCM_Pos*/) /*!< SCB ABFSR: ITCM Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/* Auxiliary Control Register Definitions */
#define SCnSCB_ACTLR_DISDYNADD_Pos 26U /*!< ACTLR: DISDYNADD Position */
#define SCnSCB_ACTLR_DISDYNADD_Msk (1UL << SCnSCB_ACTLR_DISDYNADD_Pos) /*!< ACTLR: DISDYNADD Mask */
#define SCnSCB_ACTLR_DISISSCH1_Pos 21U /*!< ACTLR: DISISSCH1 Position */
#define SCnSCB_ACTLR_DISISSCH1_Msk (0x1FUL << SCnSCB_ACTLR_DISISSCH1_Pos) /*!< ACTLR: DISISSCH1 Mask */
#define SCnSCB_ACTLR_DISDI_Pos 16U /*!< ACTLR: DISDI Position */
#define SCnSCB_ACTLR_DISDI_Msk (0x1FUL << SCnSCB_ACTLR_DISDI_Pos) /*!< ACTLR: DISDI Mask */
#define SCnSCB_ACTLR_DISCRITAXIRUR_Pos 15U /*!< ACTLR: DISCRITAXIRUR Position */
#define SCnSCB_ACTLR_DISCRITAXIRUR_Msk (1UL << SCnSCB_ACTLR_DISCRITAXIRUR_Pos) /*!< ACTLR: DISCRITAXIRUR Mask */
#define SCnSCB_ACTLR_DISBTACALLOC_Pos 14U /*!< ACTLR: DISBTACALLOC Position */
#define SCnSCB_ACTLR_DISBTACALLOC_Msk (1UL << SCnSCB_ACTLR_DISBTACALLOC_Pos) /*!< ACTLR: DISBTACALLOC Mask */
#define SCnSCB_ACTLR_DISBTACREAD_Pos 13U /*!< ACTLR: DISBTACREAD Position */
#define SCnSCB_ACTLR_DISBTACREAD_Msk (1UL << SCnSCB_ACTLR_DISBTACREAD_Pos) /*!< ACTLR: DISBTACREAD Mask */
#define SCnSCB_ACTLR_DISITMATBFLUSH_Pos 12U /*!< ACTLR: DISITMATBFLUSH Position */
#define SCnSCB_ACTLR_DISITMATBFLUSH_Msk (1UL << SCnSCB_ACTLR_DISITMATBFLUSH_Pos) /*!< ACTLR: DISITMATBFLUSH Mask */
#define SCnSCB_ACTLR_DISRAMODE_Pos 11U /*!< ACTLR: DISRAMODE Position */
#define SCnSCB_ACTLR_DISRAMODE_Msk (1UL << SCnSCB_ACTLR_DISRAMODE_Pos) /*!< ACTLR: DISRAMODE Mask */
#define SCnSCB_ACTLR_FPEXCODIS_Pos 10U /*!< ACTLR: FPEXCODIS Position */
#define SCnSCB_ACTLR_FPEXCODIS_Msk (1UL << SCnSCB_ACTLR_FPEXCODIS_Pos) /*!< ACTLR: FPEXCODIS Mask */
#define SCnSCB_ACTLR_DISFOLD_Pos 2U /*!< ACTLR: DISFOLD Position */
#define SCnSCB_ACTLR_DISFOLD_Msk (1UL << SCnSCB_ACTLR_DISFOLD_Pos) /*!< ACTLR: DISFOLD Mask */
#define SCnSCB_ACTLR_DISMCYCINT_Pos 0U /*!< ACTLR: DISMCYCINT Position */
#define SCnSCB_ACTLR_DISMCYCINT_Msk (1UL /*<< SCnSCB_ACTLR_DISMCYCINT_Pos*/) /*!< ACTLR: DISMCYCINT Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[32U];
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[6U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFFFFFFFFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TraceBusID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TraceBusID_Msk (0x7FUL << ITM_TCR_TraceBusID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPrescale_Pos 8U /*!< ITM TCR: TSPrescale Position */
#define ITM_TCR_TSPrescale_Msk (3UL << ITM_TCR_TSPrescale_Pos) /*!< ITM TCR: TSPrescale Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
__IOM uint32_t MASK0; /*!< Offset: 0x024 (R/W) Mask Register 0 */
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED0[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
__IOM uint32_t MASK1; /*!< Offset: 0x034 (R/W) Mask Register 1 */
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED1[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
__IOM uint32_t MASK2; /*!< Offset: 0x044 (R/W) Mask Register 2 */
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
__IOM uint32_t MASK3; /*!< Offset: 0x054 (R/W) Mask Register 3 */
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
uint32_t RESERVED3[981U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( W) Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R ) Lock Status Register */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Mask Register Definitions */
#define DWT_MASK_MASK_Pos 0U /*!< DWT MASK: MASK Position */
#define DWT_MASK_MASK_Msk (0x1FUL /*<< DWT_MASK_MASK_Pos*/) /*!< DWT MASK: MASK Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVADDR1_Pos 16U /*!< DWT FUNCTION: DATAVADDR1 Position */
#define DWT_FUNCTION_DATAVADDR1_Msk (0xFUL << DWT_FUNCTION_DATAVADDR1_Pos) /*!< DWT FUNCTION: DATAVADDR1 Mask */
#define DWT_FUNCTION_DATAVADDR0_Pos 12U /*!< DWT FUNCTION: DATAVADDR0 Position */
#define DWT_FUNCTION_DATAVADDR0_Msk (0xFUL << DWT_FUNCTION_DATAVADDR0_Pos) /*!< DWT FUNCTION: DATAVADDR0 Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_LNK1ENA_Pos 9U /*!< DWT FUNCTION: LNK1ENA Position */
#define DWT_FUNCTION_LNK1ENA_Msk (0x1UL << DWT_FUNCTION_LNK1ENA_Pos) /*!< DWT FUNCTION: LNK1ENA Mask */
#define DWT_FUNCTION_DATAVMATCH_Pos 8U /*!< DWT FUNCTION: DATAVMATCH Position */
#define DWT_FUNCTION_DATAVMATCH_Msk (0x1UL << DWT_FUNCTION_DATAVMATCH_Pos) /*!< DWT FUNCTION: DATAVMATCH Mask */
#define DWT_FUNCTION_CYCMATCH_Pos 7U /*!< DWT FUNCTION: CYCMATCH Position */
#define DWT_FUNCTION_CYCMATCH_Msk (0x1UL << DWT_FUNCTION_CYCMATCH_Pos) /*!< DWT FUNCTION: CYCMATCH Mask */
#define DWT_FUNCTION_EMITRANGE_Pos 5U /*!< DWT FUNCTION: EMITRANGE Position */
#define DWT_FUNCTION_EMITRANGE_Msk (0x1UL << DWT_FUNCTION_EMITRANGE_Pos) /*!< DWT FUNCTION: EMITRANGE Mask */
#define DWT_FUNCTION_FUNCTION_Pos 0U /*!< DWT FUNCTION: FUNCTION Position */
#define DWT_FUNCTION_FUNCTION_Msk (0xFUL /*<< DWT_FUNCTION_FUNCTION_Pos*/) /*!< DWT FUNCTION: FUNCTION Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Size Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Size Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IM uint32_t FSCR; /*!< Offset: 0x308 (R/ ) Formatter Synchronization Counter Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER Register */
__IM uint32_t FIFO0; /*!< Offset: 0xEEC (R/ ) Integration ETM Data */
__IM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/ ) ITATBCTR2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) ITATBCTR0 */
__IM uint32_t FIFO1; /*!< Offset: 0xEFC (R/ ) Integration ITM Data */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) TPIU_DEVID */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) TPIU_DEVTYPE */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration ETM Data Register Definitions (FIFO0) */
#define TPI_FIFO0_ITM_ATVALID_Pos 29U /*!< TPI FIFO0: ITM_ATVALID Position */
#define TPI_FIFO0_ITM_ATVALID_Msk (0x1UL << TPI_FIFO0_ITM_ATVALID_Pos) /*!< TPI FIFO0: ITM_ATVALID Mask */
#define TPI_FIFO0_ITM_bytecount_Pos 27U /*!< TPI FIFO0: ITM_bytecount Position */
#define TPI_FIFO0_ITM_bytecount_Msk (0x3UL << TPI_FIFO0_ITM_bytecount_Pos) /*!< TPI FIFO0: ITM_bytecount Mask */
#define TPI_FIFO0_ETM_ATVALID_Pos 26U /*!< TPI FIFO0: ETM_ATVALID Position */
#define TPI_FIFO0_ETM_ATVALID_Msk (0x1UL << TPI_FIFO0_ETM_ATVALID_Pos) /*!< TPI FIFO0: ETM_ATVALID Mask */
#define TPI_FIFO0_ETM_bytecount_Pos 24U /*!< TPI FIFO0: ETM_bytecount Position */
#define TPI_FIFO0_ETM_bytecount_Msk (0x3UL << TPI_FIFO0_ETM_bytecount_Pos) /*!< TPI FIFO0: ETM_bytecount Mask */
#define TPI_FIFO0_ETM2_Pos 16U /*!< TPI FIFO0: ETM2 Position */
#define TPI_FIFO0_ETM2_Msk (0xFFUL << TPI_FIFO0_ETM2_Pos) /*!< TPI FIFO0: ETM2 Mask */
#define TPI_FIFO0_ETM1_Pos 8U /*!< TPI FIFO0: ETM1 Position */
#define TPI_FIFO0_ETM1_Msk (0xFFUL << TPI_FIFO0_ETM1_Pos) /*!< TPI FIFO0: ETM1 Mask */
#define TPI_FIFO0_ETM0_Pos 0U /*!< TPI FIFO0: ETM0 Position */
#define TPI_FIFO0_ETM0_Msk (0xFFUL /*<< TPI_FIFO0_ETM0_Pos*/) /*!< TPI FIFO0: ETM0 Mask */
/* TPI ITATBCTR2 Register Definitions */
#define TPI_ITATBCTR2_ATREADY2_Pos 0U /*!< TPI ITATBCTR2: ATREADY2 Position */
#define TPI_ITATBCTR2_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY2_Pos*/) /*!< TPI ITATBCTR2: ATREADY2 Mask */
#define TPI_ITATBCTR2_ATREADY1_Pos 0U /*!< TPI ITATBCTR2: ATREADY1 Position */
#define TPI_ITATBCTR2_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY1_Pos*/) /*!< TPI ITATBCTR2: ATREADY1 Mask */
/* TPI Integration ITM Data Register Definitions (FIFO1) */
#define TPI_FIFO1_ITM_ATVALID_Pos 29U /*!< TPI FIFO1: ITM_ATVALID Position */
#define TPI_FIFO1_ITM_ATVALID_Msk (0x1UL << TPI_FIFO1_ITM_ATVALID_Pos) /*!< TPI FIFO1: ITM_ATVALID Mask */
#define TPI_FIFO1_ITM_bytecount_Pos 27U /*!< TPI FIFO1: ITM_bytecount Position */
#define TPI_FIFO1_ITM_bytecount_Msk (0x3UL << TPI_FIFO1_ITM_bytecount_Pos) /*!< TPI FIFO1: ITM_bytecount Mask */
#define TPI_FIFO1_ETM_ATVALID_Pos 26U /*!< TPI FIFO1: ETM_ATVALID Position */
#define TPI_FIFO1_ETM_ATVALID_Msk (0x1UL << TPI_FIFO1_ETM_ATVALID_Pos) /*!< TPI FIFO1: ETM_ATVALID Mask */
#define TPI_FIFO1_ETM_bytecount_Pos 24U /*!< TPI FIFO1: ETM_bytecount Position */
#define TPI_FIFO1_ETM_bytecount_Msk (0x3UL << TPI_FIFO1_ETM_bytecount_Pos) /*!< TPI FIFO1: ETM_bytecount Mask */
#define TPI_FIFO1_ITM2_Pos 16U /*!< TPI FIFO1: ITM2 Position */
#define TPI_FIFO1_ITM2_Msk (0xFFUL << TPI_FIFO1_ITM2_Pos) /*!< TPI FIFO1: ITM2 Mask */
#define TPI_FIFO1_ITM1_Pos 8U /*!< TPI FIFO1: ITM1 Position */
#define TPI_FIFO1_ITM1_Msk (0xFFUL << TPI_FIFO1_ITM1_Pos) /*!< TPI FIFO1: ITM1 Mask */
#define TPI_FIFO1_ITM0_Pos 0U /*!< TPI FIFO1: ITM0 Position */
#define TPI_FIFO1_ITM0_Msk (0xFFUL /*<< TPI_FIFO1_ITM0_Pos*/) /*!< TPI FIFO1: ITM0 Mask */
/* TPI ITATBCTR0 Register Definitions */
#define TPI_ITATBCTR0_ATREADY2_Pos 0U /*!< TPI ITATBCTR0: ATREADY2 Position */
#define TPI_ITATBCTR0_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY2_Pos*/) /*!< TPI ITATBCTR0: ATREADY2 Mask */
#define TPI_ITATBCTR0_ATREADY1_Pos 0U /*!< TPI ITATBCTR0: ATREADY1 Position */
#define TPI_ITATBCTR0_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY1_Pos*/) /*!< TPI ITATBCTR0: ATREADY1 Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x3UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_MinBufSz_Pos 6U /*!< TPI DEVID: MinBufSz Position */
#define TPI_DEVID_MinBufSz_Msk (0x7UL << TPI_DEVID_MinBufSz_Pos) /*!< TPI DEVID: MinBufSz Mask */
#define TPI_DEVID_AsynClkIn_Pos 5U /*!< TPI DEVID: AsynClkIn Position */
#define TPI_DEVID_AsynClkIn_Msk (0x1UL << TPI_DEVID_AsynClkIn_Pos) /*!< TPI DEVID: AsynClkIn Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x1FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region RNRber Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RASR; /*!< Offset: 0x010 (R/W) MPU Region Attribute and Size Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Alias 1 Region Base Address Register */
__IOM uint32_t RASR_A1; /*!< Offset: 0x018 (R/W) MPU Alias 1 Region Attribute and Size Register */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Alias 2 Region Base Address Register */
__IOM uint32_t RASR_A2; /*!< Offset: 0x020 (R/W) MPU Alias 2 Region Attribute and Size Register */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Alias 3 Region Base Address Register */
__IOM uint32_t RASR_A3; /*!< Offset: 0x028 (R/W) MPU Alias 3 Region Attribute and Size Register */
} MPU_Type;
#define MPU_TYPE_RALIASES 4U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_ADDR_Pos 5U /*!< MPU RBAR: ADDR Position */
#define MPU_RBAR_ADDR_Msk (0x7FFFFFFUL << MPU_RBAR_ADDR_Pos) /*!< MPU RBAR: ADDR Mask */
#define MPU_RBAR_VALID_Pos 4U /*!< MPU RBAR: VALID Position */
#define MPU_RBAR_VALID_Msk (1UL << MPU_RBAR_VALID_Pos) /*!< MPU RBAR: VALID Mask */
#define MPU_RBAR_REGION_Pos 0U /*!< MPU RBAR: REGION Position */
#define MPU_RBAR_REGION_Msk (0xFUL /*<< MPU_RBAR_REGION_Pos*/) /*!< MPU RBAR: REGION Mask */
/* MPU Region Attribute and Size Register Definitions */
#define MPU_RASR_ATTRS_Pos 16U /*!< MPU RASR: MPU Region Attribute field Position */
#define MPU_RASR_ATTRS_Msk (0xFFFFUL << MPU_RASR_ATTRS_Pos) /*!< MPU RASR: MPU Region Attribute field Mask */
#define MPU_RASR_XN_Pos 28U /*!< MPU RASR: ATTRS.XN Position */
#define MPU_RASR_XN_Msk (1UL << MPU_RASR_XN_Pos) /*!< MPU RASR: ATTRS.XN Mask */
#define MPU_RASR_AP_Pos 24U /*!< MPU RASR: ATTRS.AP Position */
#define MPU_RASR_AP_Msk (0x7UL << MPU_RASR_AP_Pos) /*!< MPU RASR: ATTRS.AP Mask */
#define MPU_RASR_TEX_Pos 19U /*!< MPU RASR: ATTRS.TEX Position */
#define MPU_RASR_TEX_Msk (0x7UL << MPU_RASR_TEX_Pos) /*!< MPU RASR: ATTRS.TEX Mask */
#define MPU_RASR_S_Pos 18U /*!< MPU RASR: ATTRS.S Position */
#define MPU_RASR_S_Msk (1UL << MPU_RASR_S_Pos) /*!< MPU RASR: ATTRS.S Mask */
#define MPU_RASR_C_Pos 17U /*!< MPU RASR: ATTRS.C Position */
#define MPU_RASR_C_Msk (1UL << MPU_RASR_C_Pos) /*!< MPU RASR: ATTRS.C Mask */
#define MPU_RASR_B_Pos 16U /*!< MPU RASR: ATTRS.B Position */
#define MPU_RASR_B_Msk (1UL << MPU_RASR_B_Pos) /*!< MPU RASR: ATTRS.B Mask */
#define MPU_RASR_SRD_Pos 8U /*!< MPU RASR: Sub-Region Disable Position */
#define MPU_RASR_SRD_Msk (0xFFUL << MPU_RASR_SRD_Pos) /*!< MPU RASR: Sub-Region Disable Mask */
#define MPU_RASR_SIZE_Pos 1U /*!< MPU RASR: Region Size Field Position */
#define MPU_RASR_SIZE_Msk (0x1FUL << MPU_RASR_SIZE_Pos) /*!< MPU RASR: Region Size Field Mask */
#define MPU_RASR_ENABLE_Pos 0U /*!< MPU RASR: Region enable bit Position */
#define MPU_RASR_ENABLE_Msk (1UL /*<< MPU_RASR_ENABLE_Pos*/) /*!< MPU RASR: Region enable bit Disable Mask */
/*@} end of group CMSIS_MPU */
#endif /* defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_FPU Floating Point Unit (FPU)
\brief Type definitions for the Floating Point Unit (FPU)
@{
*/
/**
\brief Structure type to access the Floating Point Unit (FPU).
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IOM uint32_t FPCCR; /*!< Offset: 0x004 (R/W) Floating-Point Context Control Register */
__IOM uint32_t FPCAR; /*!< Offset: 0x008 (R/W) Floating-Point Context Address Register */
__IOM uint32_t FPDSCR; /*!< Offset: 0x00C (R/W) Floating-Point Default Status Control Register */
__IM uint32_t MVFR0; /*!< Offset: 0x010 (R/ ) Media and FP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x014 (R/ ) Media and FP Feature Register 1 */
__IM uint32_t MVFR2; /*!< Offset: 0x018 (R/ ) Media and FP Feature Register 2 */
} FPU_Type;
/* Floating-Point Context Control Register Definitions */
#define FPU_FPCCR_ASPEN_Pos 31U /*!< FPCCR: ASPEN bit Position */
#define FPU_FPCCR_ASPEN_Msk (1UL << FPU_FPCCR_ASPEN_Pos) /*!< FPCCR: ASPEN bit Mask */
#define FPU_FPCCR_LSPEN_Pos 30U /*!< FPCCR: LSPEN Position */
#define FPU_FPCCR_LSPEN_Msk (1UL << FPU_FPCCR_LSPEN_Pos) /*!< FPCCR: LSPEN bit Mask */
#define FPU_FPCCR_MONRDY_Pos 8U /*!< FPCCR: MONRDY Position */
#define FPU_FPCCR_MONRDY_Msk (1UL << FPU_FPCCR_MONRDY_Pos) /*!< FPCCR: MONRDY bit Mask */
#define FPU_FPCCR_BFRDY_Pos 6U /*!< FPCCR: BFRDY Position */
#define FPU_FPCCR_BFRDY_Msk (1UL << FPU_FPCCR_BFRDY_Pos) /*!< FPCCR: BFRDY bit Mask */
#define FPU_FPCCR_MMRDY_Pos 5U /*!< FPCCR: MMRDY Position */
#define FPU_FPCCR_MMRDY_Msk (1UL << FPU_FPCCR_MMRDY_Pos) /*!< FPCCR: MMRDY bit Mask */
#define FPU_FPCCR_HFRDY_Pos 4U /*!< FPCCR: HFRDY Position */
#define FPU_FPCCR_HFRDY_Msk (1UL << FPU_FPCCR_HFRDY_Pos) /*!< FPCCR: HFRDY bit Mask */
#define FPU_FPCCR_THREAD_Pos 3U /*!< FPCCR: processor mode bit Position */
#define FPU_FPCCR_THREAD_Msk (1UL << FPU_FPCCR_THREAD_Pos) /*!< FPCCR: processor mode active bit Mask */
#define FPU_FPCCR_USER_Pos 1U /*!< FPCCR: privilege level bit Position */
#define FPU_FPCCR_USER_Msk (1UL << FPU_FPCCR_USER_Pos) /*!< FPCCR: privilege level bit Mask */
#define FPU_FPCCR_LSPACT_Pos 0U /*!< FPCCR: Lazy state preservation active bit Position */
#define FPU_FPCCR_LSPACT_Msk (1UL /*<< FPU_FPCCR_LSPACT_Pos*/) /*!< FPCCR: Lazy state preservation active bit Mask */
/* Floating-Point Context Address Register Definitions */
#define FPU_FPCAR_ADDRESS_Pos 3U /*!< FPCAR: ADDRESS bit Position */
#define FPU_FPCAR_ADDRESS_Msk (0x1FFFFFFFUL << FPU_FPCAR_ADDRESS_Pos) /*!< FPCAR: ADDRESS bit Mask */
/* Floating-Point Default Status Control Register Definitions */
#define FPU_FPDSCR_AHP_Pos 26U /*!< FPDSCR: AHP bit Position */
#define FPU_FPDSCR_AHP_Msk (1UL << FPU_FPDSCR_AHP_Pos) /*!< FPDSCR: AHP bit Mask */
#define FPU_FPDSCR_DN_Pos 25U /*!< FPDSCR: DN bit Position */
#define FPU_FPDSCR_DN_Msk (1UL << FPU_FPDSCR_DN_Pos) /*!< FPDSCR: DN bit Mask */
#define FPU_FPDSCR_FZ_Pos 24U /*!< FPDSCR: FZ bit Position */
#define FPU_FPDSCR_FZ_Msk (1UL << FPU_FPDSCR_FZ_Pos) /*!< FPDSCR: FZ bit Mask */
#define FPU_FPDSCR_RMode_Pos 22U /*!< FPDSCR: RMode bit Position */
#define FPU_FPDSCR_RMode_Msk (3UL << FPU_FPDSCR_RMode_Pos) /*!< FPDSCR: RMode bit Mask */
/* Media and FP Feature Register 0 Definitions */
#define FPU_MVFR0_FP_rounding_modes_Pos 28U /*!< MVFR0: FP rounding modes bits Position */
#define FPU_MVFR0_FP_rounding_modes_Msk (0xFUL << FPU_MVFR0_FP_rounding_modes_Pos) /*!< MVFR0: FP rounding modes bits Mask */
#define FPU_MVFR0_Short_vectors_Pos 24U /*!< MVFR0: Short vectors bits Position */
#define FPU_MVFR0_Short_vectors_Msk (0xFUL << FPU_MVFR0_Short_vectors_Pos) /*!< MVFR0: Short vectors bits Mask */
#define FPU_MVFR0_Square_root_Pos 20U /*!< MVFR0: Square root bits Position */
#define FPU_MVFR0_Square_root_Msk (0xFUL << FPU_MVFR0_Square_root_Pos) /*!< MVFR0: Square root bits Mask */
#define FPU_MVFR0_Divide_Pos 16U /*!< MVFR0: Divide bits Position */
#define FPU_MVFR0_Divide_Msk (0xFUL << FPU_MVFR0_Divide_Pos) /*!< MVFR0: Divide bits Mask */
#define FPU_MVFR0_FP_excep_trapping_Pos 12U /*!< MVFR0: FP exception trapping bits Position */
#define FPU_MVFR0_FP_excep_trapping_Msk (0xFUL << FPU_MVFR0_FP_excep_trapping_Pos) /*!< MVFR0: FP exception trapping bits Mask */
#define FPU_MVFR0_Double_precision_Pos 8U /*!< MVFR0: Double-precision bits Position */
#define FPU_MVFR0_Double_precision_Msk (0xFUL << FPU_MVFR0_Double_precision_Pos) /*!< MVFR0: Double-precision bits Mask */
#define FPU_MVFR0_Single_precision_Pos 4U /*!< MVFR0: Single-precision bits Position */
#define FPU_MVFR0_Single_precision_Msk (0xFUL << FPU_MVFR0_Single_precision_Pos) /*!< MVFR0: Single-precision bits Mask */
#define FPU_MVFR0_A_SIMD_registers_Pos 0U /*!< MVFR0: A_SIMD registers bits Position */
#define FPU_MVFR0_A_SIMD_registers_Msk (0xFUL /*<< FPU_MVFR0_A_SIMD_registers_Pos*/) /*!< MVFR0: A_SIMD registers bits Mask */
/* Media and FP Feature Register 1 Definitions */
#define FPU_MVFR1_FP_fused_MAC_Pos 28U /*!< MVFR1: FP fused MAC bits Position */
#define FPU_MVFR1_FP_fused_MAC_Msk (0xFUL << FPU_MVFR1_FP_fused_MAC_Pos) /*!< MVFR1: FP fused MAC bits Mask */
#define FPU_MVFR1_FP_HPFP_Pos 24U /*!< MVFR1: FP HPFP bits Position */
#define FPU_MVFR1_FP_HPFP_Msk (0xFUL << FPU_MVFR1_FP_HPFP_Pos) /*!< MVFR1: FP HPFP bits Mask */
#define FPU_MVFR1_D_NaN_mode_Pos 4U /*!< MVFR1: D_NaN mode bits Position */
#define FPU_MVFR1_D_NaN_mode_Msk (0xFUL << FPU_MVFR1_D_NaN_mode_Pos) /*!< MVFR1: D_NaN mode bits Mask */
#define FPU_MVFR1_FtZ_mode_Pos 0U /*!< MVFR1: FtZ mode bits Position */
#define FPU_MVFR1_FtZ_mode_Msk (0xFUL /*<< FPU_MVFR1_FtZ_mode_Pos*/) /*!< MVFR1: FtZ mode bits Mask */
/* Media and FP Feature Register 2 Definitions */
#define FPU_MVFR2_VFP_Misc_Pos 4U /*!< MVFR2: VFP Misc bits Position */
#define FPU_MVFR2_VFP_Misc_Msk (0xFUL << FPU_MVFR2_VFP_Misc_Pos) /*!< MVFR2: VFP Misc bits Mask */
/*@} end of group CMSIS_FPU */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#define FPU_BASE (SCS_BASE + 0x0F30UL) /*!< Floating Point Unit */
#define FPU ((FPU_Type *) FPU_BASE ) /*!< Floating Point Unit */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
#define EXC_RETURN_HANDLER_FPU (0xFFFFFFE1UL) /* return to Handler mode, uses MSP after return, restore floating-point state */
#define EXC_RETURN_THREAD_MSP_FPU (0xFFFFFFE9UL) /* return to Thread mode, uses MSP after return, restore floating-point state */
#define EXC_RETURN_THREAD_PSP_FPU (0xFFFFFFEDUL) /* return to Thread mode, uses PSP after return, restore floating-point state */
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IP[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4)) = vector;
__DSB();
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
return (uint32_t)(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4));
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv7.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
uint32_t mvfr0;
mvfr0 = SCB->MVFR0;
if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x220U)
{
return 2U; /* Double + Single precision FPU */
}
else if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x020U)
{
return 1U; /* Single precision FPU */
}
else
{
return 0U; /* No FPU */
}
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ########################## Cache functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_CacheFunctions Cache Functions
\brief Functions that configure Instruction and Data cache.
@{
*/
/* Cache Size ID Register Macros */
#define CCSIDR_WAYS(x) (((x) & SCB_CCSIDR_ASSOCIATIVITY_Msk) >> SCB_CCSIDR_ASSOCIATIVITY_Pos)
#define CCSIDR_SETS(x) (((x) & SCB_CCSIDR_NUMSETS_Msk ) >> SCB_CCSIDR_NUMSETS_Pos )
#define __SCB_DCACHE_LINE_SIZE 32U /*!< Cortex-M7 cache line size is fixed to 32 bytes (8 words). See also register SCB_CCSIDR */
#define __SCB_ICACHE_LINE_SIZE 32U /*!< Cortex-M7 cache line size is fixed to 32 bytes (8 words). See also register SCB_CCSIDR */
/**
\brief Enable I-Cache
\details Turns on I-Cache
*/
__STATIC_FORCEINLINE void SCB_EnableICache (void)
{
#if defined (__ICACHE_PRESENT) && (__ICACHE_PRESENT == 1U)
if (SCB->CCR & SCB_CCR_IC_Msk) return; /* return if ICache is already enabled */
__DSB();
__ISB();
SCB->ICIALLU = 0UL; /* invalidate I-Cache */
__DSB();
__ISB();
SCB->CCR |= (uint32_t)SCB_CCR_IC_Msk; /* enable I-Cache */
__DSB();
__ISB();
#endif
}
/**
\brief Disable I-Cache
\details Turns off I-Cache
*/
__STATIC_FORCEINLINE void SCB_DisableICache (void)
{
#if defined (__ICACHE_PRESENT) && (__ICACHE_PRESENT == 1U)
__DSB();
__ISB();
SCB->CCR &= ~(uint32_t)SCB_CCR_IC_Msk; /* disable I-Cache */
SCB->ICIALLU = 0UL; /* invalidate I-Cache */
__DSB();
__ISB();
#endif
}
/**
\brief Invalidate I-Cache
\details Invalidates I-Cache
*/
__STATIC_FORCEINLINE void SCB_InvalidateICache (void)
{
#if defined (__ICACHE_PRESENT) && (__ICACHE_PRESENT == 1U)
__DSB();
__ISB();
SCB->ICIALLU = 0UL;
__DSB();
__ISB();
#endif
}
/**
\brief I-Cache Invalidate by address
\details Invalidates I-Cache for the given address.
I-Cache is invalidated starting from a 32 byte aligned address in 32 byte granularity.
I-Cache memory blocks which are part of given address + given size are invalidated.
\param[in] addr address
\param[in] isize size of memory block (in number of bytes)
*/
__STATIC_FORCEINLINE void SCB_InvalidateICache_by_Addr (void *addr, int32_t isize)
{
#if defined (__ICACHE_PRESENT) && (__ICACHE_PRESENT == 1U)
if ( isize > 0 ) {
int32_t op_size = isize + (((uint32_t)addr) & (__SCB_ICACHE_LINE_SIZE - 1U));
uint32_t op_addr = (uint32_t)addr /* & ~(__SCB_ICACHE_LINE_SIZE - 1U) */;
__DSB();
do {
SCB->ICIMVAU = op_addr; /* register accepts only 32byte aligned values, only bits 31..5 are valid */
op_addr += __SCB_ICACHE_LINE_SIZE;
op_size -= __SCB_ICACHE_LINE_SIZE;
} while ( op_size > 0 );
__DSB();
__ISB();
}
#endif
}
/**
\brief Enable D-Cache
\details Turns on D-Cache
*/
__STATIC_FORCEINLINE void SCB_EnableDCache (void)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
uint32_t ccsidr;
uint32_t sets;
uint32_t ways;
if (SCB->CCR & SCB_CCR_DC_Msk) return; /* return if DCache is already enabled */
SCB->CSSELR = 0U; /* select Level 1 data cache */
__DSB();
ccsidr = SCB->CCSIDR;
/* invalidate D-Cache */
sets = (uint32_t)(CCSIDR_SETS(ccsidr));
do {
ways = (uint32_t)(CCSIDR_WAYS(ccsidr));
do {
SCB->DCISW = (((sets << SCB_DCISW_SET_Pos) & SCB_DCISW_SET_Msk) |
((ways << SCB_DCISW_WAY_Pos) & SCB_DCISW_WAY_Msk) );
#if defined ( __CC_ARM )
__schedule_barrier();
#endif
} while (ways-- != 0U);
} while(sets-- != 0U);
__DSB();
SCB->CCR |= (uint32_t)SCB_CCR_DC_Msk; /* enable D-Cache */
__DSB();
__ISB();
#endif
}
/**
\brief Disable D-Cache
\details Turns off D-Cache
*/
__STATIC_FORCEINLINE void SCB_DisableDCache (void)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
uint32_t ccsidr;
uint32_t sets;
uint32_t ways;
SCB->CSSELR = 0U; /* select Level 1 data cache */
__DSB();
SCB->CCR &= ~(uint32_t)SCB_CCR_DC_Msk; /* disable D-Cache */
__DSB();
ccsidr = SCB->CCSIDR;
/* clean & invalidate D-Cache */
sets = (uint32_t)(CCSIDR_SETS(ccsidr));
do {
ways = (uint32_t)(CCSIDR_WAYS(ccsidr));
do {
SCB->DCCISW = (((sets << SCB_DCCISW_SET_Pos) & SCB_DCCISW_SET_Msk) |
((ways << SCB_DCCISW_WAY_Pos) & SCB_DCCISW_WAY_Msk) );
#if defined ( __CC_ARM )
__schedule_barrier();
#endif
} while (ways-- != 0U);
} while(sets-- != 0U);
__DSB();
__ISB();
#endif
}
/**
\brief Invalidate D-Cache
\details Invalidates D-Cache
*/
__STATIC_FORCEINLINE void SCB_InvalidateDCache (void)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
uint32_t ccsidr;
uint32_t sets;
uint32_t ways;
SCB->CSSELR = 0U; /* select Level 1 data cache */
__DSB();
ccsidr = SCB->CCSIDR;
/* invalidate D-Cache */
sets = (uint32_t)(CCSIDR_SETS(ccsidr));
do {
ways = (uint32_t)(CCSIDR_WAYS(ccsidr));
do {
SCB->DCISW = (((sets << SCB_DCISW_SET_Pos) & SCB_DCISW_SET_Msk) |
((ways << SCB_DCISW_WAY_Pos) & SCB_DCISW_WAY_Msk) );
#if defined ( __CC_ARM )
__schedule_barrier();
#endif
} while (ways-- != 0U);
} while(sets-- != 0U);
__DSB();
__ISB();
#endif
}
/**
\brief Clean D-Cache
\details Cleans D-Cache
*/
__STATIC_FORCEINLINE void SCB_CleanDCache (void)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
uint32_t ccsidr;
uint32_t sets;
uint32_t ways;
SCB->CSSELR = 0U; /* select Level 1 data cache */
__DSB();
ccsidr = SCB->CCSIDR;
/* clean D-Cache */
sets = (uint32_t)(CCSIDR_SETS(ccsidr));
do {
ways = (uint32_t)(CCSIDR_WAYS(ccsidr));
do {
SCB->DCCSW = (((sets << SCB_DCCSW_SET_Pos) & SCB_DCCSW_SET_Msk) |
((ways << SCB_DCCSW_WAY_Pos) & SCB_DCCSW_WAY_Msk) );
#if defined ( __CC_ARM )
__schedule_barrier();
#endif
} while (ways-- != 0U);
} while(sets-- != 0U);
__DSB();
__ISB();
#endif
}
/**
\brief Clean & Invalidate D-Cache
\details Cleans and Invalidates D-Cache
*/
__STATIC_FORCEINLINE void SCB_CleanInvalidateDCache (void)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
uint32_t ccsidr;
uint32_t sets;
uint32_t ways;
SCB->CSSELR = 0U; /* select Level 1 data cache */
__DSB();
ccsidr = SCB->CCSIDR;
/* clean & invalidate D-Cache */
sets = (uint32_t)(CCSIDR_SETS(ccsidr));
do {
ways = (uint32_t)(CCSIDR_WAYS(ccsidr));
do {
SCB->DCCISW = (((sets << SCB_DCCISW_SET_Pos) & SCB_DCCISW_SET_Msk) |
((ways << SCB_DCCISW_WAY_Pos) & SCB_DCCISW_WAY_Msk) );
#if defined ( __CC_ARM )
__schedule_barrier();
#endif
} while (ways-- != 0U);
} while(sets-- != 0U);
__DSB();
__ISB();
#endif
}
/**
\brief D-Cache Invalidate by address
\details Invalidates D-Cache for the given address.
D-Cache is invalidated starting from a 32 byte aligned address in 32 byte granularity.
D-Cache memory blocks which are part of given address + given size are invalidated.
\param[in] addr address
\param[in] dsize size of memory block (in number of bytes)
*/
__STATIC_FORCEINLINE void SCB_InvalidateDCache_by_Addr (void *addr, int32_t dsize)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
if ( dsize > 0 ) {
int32_t op_size = dsize + (((uint32_t)addr) & (__SCB_DCACHE_LINE_SIZE - 1U));
uint32_t op_addr = (uint32_t)addr /* & ~(__SCB_DCACHE_LINE_SIZE - 1U) */;
__DSB();
do {
SCB->DCIMVAC = op_addr; /* register accepts only 32byte aligned values, only bits 31..5 are valid */
op_addr += __SCB_DCACHE_LINE_SIZE;
op_size -= __SCB_DCACHE_LINE_SIZE;
} while ( op_size > 0 );
__DSB();
__ISB();
}
#endif
}
/**
\brief D-Cache Clean by address
\details Cleans D-Cache for the given address
D-Cache is cleaned starting from a 32 byte aligned address in 32 byte granularity.
D-Cache memory blocks which are part of given address + given size are cleaned.
\param[in] addr address
\param[in] dsize size of memory block (in number of bytes)
*/
__STATIC_FORCEINLINE void SCB_CleanDCache_by_Addr (uint32_t *addr, int32_t dsize)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
if ( dsize > 0 ) {
int32_t op_size = dsize + (((uint32_t)addr) & (__SCB_DCACHE_LINE_SIZE - 1U));
uint32_t op_addr = (uint32_t)addr /* & ~(__SCB_DCACHE_LINE_SIZE - 1U) */;
__DSB();
do {
SCB->DCCMVAC = op_addr; /* register accepts only 32byte aligned values, only bits 31..5 are valid */
op_addr += __SCB_DCACHE_LINE_SIZE;
op_size -= __SCB_DCACHE_LINE_SIZE;
} while ( op_size > 0 );
__DSB();
__ISB();
}
#endif
}
/**
\brief D-Cache Clean and Invalidate by address
\details Cleans and invalidates D_Cache for the given address
D-Cache is cleaned and invalidated starting from a 32 byte aligned address in 32 byte granularity.
D-Cache memory blocks which are part of given address + given size are cleaned and invalidated.
\param[in] addr address (aligned to 32-byte boundary)
\param[in] dsize size of memory block (in number of bytes)
*/
__STATIC_FORCEINLINE void SCB_CleanInvalidateDCache_by_Addr (uint32_t *addr, int32_t dsize)
{
#if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U)
if ( dsize > 0 ) {
int32_t op_size = dsize + (((uint32_t)addr) & (__SCB_DCACHE_LINE_SIZE - 1U));
uint32_t op_addr = (uint32_t)addr /* & ~(__SCB_DCACHE_LINE_SIZE - 1U) */;
__DSB();
do {
SCB->DCCIMVAC = op_addr; /* register accepts only 32byte aligned values, only bits 31..5 are valid */
op_addr += __SCB_DCACHE_LINE_SIZE;
op_size -= __SCB_DCACHE_LINE_SIZE;
} while ( op_size > 0 );
__DSB();
__ISB();
}
#endif
}
/*@} end of CMSIS_Core_CacheFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM7_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 149,036 | C | 53.672414 | 178 | 0.522934 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_sc300.h | /**************************************************************************//**
* @file core_sc300.h
* @brief CMSIS SC300 Core Peripheral Access Layer Header File
* @version V5.0.8
* @date 31. May 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_SC300_H_GENERIC
#define __CORE_SC300_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup SC3000
@{
*/
#include "cmsis_version.h"
/* CMSIS SC300 definitions */
#define __SC300_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __SC300_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __SC300_CMSIS_VERSION ((__SC300_CMSIS_VERSION_MAIN << 16U) | \
__SC300_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_SC (300U) /*!< Cortex secure core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_SC300_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_SC300_H_DEPENDANT
#define __CORE_SC300_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __SC300_REV
#define __SC300_REV 0x0000U
#warning "__SC300_REV not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group SC300 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:27; /*!< bit: 0..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:1; /*!< bit: 9 Reserved */
uint32_t ICI_IT_1:6; /*!< bit: 10..15 ICI/IT part 1 */
uint32_t _reserved1:8; /*!< bit: 16..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit */
uint32_t ICI_IT_2:2; /*!< bit: 25..26 ICI/IT part 2 */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_ICI_IT_2_Pos 25U /*!< xPSR: ICI/IT part 2 Position */
#define xPSR_ICI_IT_2_Msk (3UL << xPSR_ICI_IT_2_Pos) /*!< xPSR: ICI/IT part 2 Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ICI_IT_1_Pos 10U /*!< xPSR: ICI/IT part 1 Position */
#define xPSR_ICI_IT_1_Msk (0x3FUL << xPSR_ICI_IT_1_Pos) /*!< xPSR: ICI/IT part 1 Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[8U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[24U];
__IOM uint32_t ICER[8U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RESERVED1[24U];
__IOM uint32_t ISPR[8U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[24U];
__IOM uint32_t ICPR[8U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[24U];
__IOM uint32_t IABR[8U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[56U];
__IOM uint8_t IP[240U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED5[644U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHP[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ADR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t MMFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ISAR[5U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
uint32_t RESERVED0[5U];
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
uint32_t RESERVED1[129U];
__IOM uint32_t SFCR; /*!< Offset: 0x290 (R/W) Security Features Control Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLBASE_Pos 29U /*!< SCB VTOR: TBLBASE Position */
#define SCB_VTOR_TBLBASE_Msk (1UL << SCB_VTOR_TBLBASE_Pos) /*!< SCB VTOR: TBLBASE Mask */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x3FFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
#define SCB_AIRCR_VECTRESET_Pos 0U /*!< SCB AIRCR: VECTRESET Position */
#define SCB_AIRCR_VECTRESET_Msk (1UL /*<< SCB_AIRCR_VECTRESET_Pos*/) /*!< SCB AIRCR: VECTRESET Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
#define SCB_CCR_NONBASETHRDENA_Pos 0U /*!< SCB CCR: NONBASETHRDENA Position */
#define SCB_CCR_NONBASETHRDENA_Msk (1UL /*<< SCB_CCR_NONBASETHRDENA_Pos*/) /*!< SCB CCR: NONBASETHRDENA Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/* Auxiliary Control Register Definitions */
#define SCnSCB_ACTLR_DISFOLD_Pos 2U /*!< ACTLR: DISFOLD Position */
#define SCnSCB_ACTLR_DISFOLD_Msk (1UL << SCnSCB_ACTLR_DISFOLD_Pos) /*!< ACTLR: DISFOLD Mask */
#define SCnSCB_ACTLR_DISDEFWBUF_Pos 1U /*!< ACTLR: DISDEFWBUF Position */
#define SCnSCB_ACTLR_DISDEFWBUF_Msk (1UL << SCnSCB_ACTLR_DISDEFWBUF_Pos) /*!< ACTLR: DISDEFWBUF Mask */
#define SCnSCB_ACTLR_DISMCYCINT_Pos 0U /*!< ACTLR: DISMCYCINT Position */
#define SCnSCB_ACTLR_DISMCYCINT_Msk (1UL /*<< SCnSCB_ACTLR_DISMCYCINT_Pos*/) /*!< ACTLR: DISMCYCINT Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[32U];
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[6U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TraceBusID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TraceBusID_Msk (0x7FUL << ITM_TCR_TraceBusID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPrescale_Pos 8U /*!< ITM TCR: TSPrescale Position */
#define ITM_TCR_TSPrescale_Msk (3UL << ITM_TCR_TSPrescale_Pos) /*!< ITM TCR: TSPrescale Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
__IOM uint32_t MASK0; /*!< Offset: 0x024 (R/W) Mask Register 0 */
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED0[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
__IOM uint32_t MASK1; /*!< Offset: 0x034 (R/W) Mask Register 1 */
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED1[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
__IOM uint32_t MASK2; /*!< Offset: 0x044 (R/W) Mask Register 2 */
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
__IOM uint32_t MASK3; /*!< Offset: 0x054 (R/W) Mask Register 3 */
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Mask Register Definitions */
#define DWT_MASK_MASK_Pos 0U /*!< DWT MASK: MASK Position */
#define DWT_MASK_MASK_Msk (0x1FUL /*<< DWT_MASK_MASK_Pos*/) /*!< DWT MASK: MASK Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVADDR1_Pos 16U /*!< DWT FUNCTION: DATAVADDR1 Position */
#define DWT_FUNCTION_DATAVADDR1_Msk (0xFUL << DWT_FUNCTION_DATAVADDR1_Pos) /*!< DWT FUNCTION: DATAVADDR1 Mask */
#define DWT_FUNCTION_DATAVADDR0_Pos 12U /*!< DWT FUNCTION: DATAVADDR0 Position */
#define DWT_FUNCTION_DATAVADDR0_Msk (0xFUL << DWT_FUNCTION_DATAVADDR0_Pos) /*!< DWT FUNCTION: DATAVADDR0 Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_LNK1ENA_Pos 9U /*!< DWT FUNCTION: LNK1ENA Position */
#define DWT_FUNCTION_LNK1ENA_Msk (0x1UL << DWT_FUNCTION_LNK1ENA_Pos) /*!< DWT FUNCTION: LNK1ENA Mask */
#define DWT_FUNCTION_DATAVMATCH_Pos 8U /*!< DWT FUNCTION: DATAVMATCH Position */
#define DWT_FUNCTION_DATAVMATCH_Msk (0x1UL << DWT_FUNCTION_DATAVMATCH_Pos) /*!< DWT FUNCTION: DATAVMATCH Mask */
#define DWT_FUNCTION_CYCMATCH_Pos 7U /*!< DWT FUNCTION: CYCMATCH Position */
#define DWT_FUNCTION_CYCMATCH_Msk (0x1UL << DWT_FUNCTION_CYCMATCH_Pos) /*!< DWT FUNCTION: CYCMATCH Mask */
#define DWT_FUNCTION_EMITRANGE_Pos 5U /*!< DWT FUNCTION: EMITRANGE Position */
#define DWT_FUNCTION_EMITRANGE_Msk (0x1UL << DWT_FUNCTION_EMITRANGE_Pos) /*!< DWT FUNCTION: EMITRANGE Mask */
#define DWT_FUNCTION_FUNCTION_Pos 0U /*!< DWT FUNCTION: FUNCTION Position */
#define DWT_FUNCTION_FUNCTION_Msk (0xFUL /*<< DWT_FUNCTION_FUNCTION_Pos*/) /*!< DWT FUNCTION: FUNCTION Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Size Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Size Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IM uint32_t FSCR; /*!< Offset: 0x308 (R/ ) Formatter Synchronization Counter Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER Register */
__IM uint32_t FIFO0; /*!< Offset: 0xEEC (R/ ) Integration ETM Data */
__IM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/ ) ITATBCTR2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) ITATBCTR0 */
__IM uint32_t FIFO1; /*!< Offset: 0xEFC (R/ ) Integration ITM Data */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) TPIU_DEVID */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) TPIU_DEVTYPE */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration ETM Data Register Definitions (FIFO0) */
#define TPI_FIFO0_ITM_ATVALID_Pos 29U /*!< TPI FIFO0: ITM_ATVALID Position */
#define TPI_FIFO0_ITM_ATVALID_Msk (0x1UL << TPI_FIFO0_ITM_ATVALID_Pos) /*!< TPI FIFO0: ITM_ATVALID Mask */
#define TPI_FIFO0_ITM_bytecount_Pos 27U /*!< TPI FIFO0: ITM_bytecount Position */
#define TPI_FIFO0_ITM_bytecount_Msk (0x3UL << TPI_FIFO0_ITM_bytecount_Pos) /*!< TPI FIFO0: ITM_bytecount Mask */
#define TPI_FIFO0_ETM_ATVALID_Pos 26U /*!< TPI FIFO0: ETM_ATVALID Position */
#define TPI_FIFO0_ETM_ATVALID_Msk (0x1UL << TPI_FIFO0_ETM_ATVALID_Pos) /*!< TPI FIFO0: ETM_ATVALID Mask */
#define TPI_FIFO0_ETM_bytecount_Pos 24U /*!< TPI FIFO0: ETM_bytecount Position */
#define TPI_FIFO0_ETM_bytecount_Msk (0x3UL << TPI_FIFO0_ETM_bytecount_Pos) /*!< TPI FIFO0: ETM_bytecount Mask */
#define TPI_FIFO0_ETM2_Pos 16U /*!< TPI FIFO0: ETM2 Position */
#define TPI_FIFO0_ETM2_Msk (0xFFUL << TPI_FIFO0_ETM2_Pos) /*!< TPI FIFO0: ETM2 Mask */
#define TPI_FIFO0_ETM1_Pos 8U /*!< TPI FIFO0: ETM1 Position */
#define TPI_FIFO0_ETM1_Msk (0xFFUL << TPI_FIFO0_ETM1_Pos) /*!< TPI FIFO0: ETM1 Mask */
#define TPI_FIFO0_ETM0_Pos 0U /*!< TPI FIFO0: ETM0 Position */
#define TPI_FIFO0_ETM0_Msk (0xFFUL /*<< TPI_FIFO0_ETM0_Pos*/) /*!< TPI FIFO0: ETM0 Mask */
/* TPI ITATBCTR2 Register Definitions */
#define TPI_ITATBCTR2_ATREADY2_Pos 0U /*!< TPI ITATBCTR2: ATREADY2 Position */
#define TPI_ITATBCTR2_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY2_Pos*/) /*!< TPI ITATBCTR2: ATREADY2 Mask */
#define TPI_ITATBCTR2_ATREADY1_Pos 0U /*!< TPI ITATBCTR2: ATREADY1 Position */
#define TPI_ITATBCTR2_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY1_Pos*/) /*!< TPI ITATBCTR2: ATREADY1 Mask */
/* TPI Integration ITM Data Register Definitions (FIFO1) */
#define TPI_FIFO1_ITM_ATVALID_Pos 29U /*!< TPI FIFO1: ITM_ATVALID Position */
#define TPI_FIFO1_ITM_ATVALID_Msk (0x1UL << TPI_FIFO1_ITM_ATVALID_Pos) /*!< TPI FIFO1: ITM_ATVALID Mask */
#define TPI_FIFO1_ITM_bytecount_Pos 27U /*!< TPI FIFO1: ITM_bytecount Position */
#define TPI_FIFO1_ITM_bytecount_Msk (0x3UL << TPI_FIFO1_ITM_bytecount_Pos) /*!< TPI FIFO1: ITM_bytecount Mask */
#define TPI_FIFO1_ETM_ATVALID_Pos 26U /*!< TPI FIFO1: ETM_ATVALID Position */
#define TPI_FIFO1_ETM_ATVALID_Msk (0x1UL << TPI_FIFO1_ETM_ATVALID_Pos) /*!< TPI FIFO1: ETM_ATVALID Mask */
#define TPI_FIFO1_ETM_bytecount_Pos 24U /*!< TPI FIFO1: ETM_bytecount Position */
#define TPI_FIFO1_ETM_bytecount_Msk (0x3UL << TPI_FIFO1_ETM_bytecount_Pos) /*!< TPI FIFO1: ETM_bytecount Mask */
#define TPI_FIFO1_ITM2_Pos 16U /*!< TPI FIFO1: ITM2 Position */
#define TPI_FIFO1_ITM2_Msk (0xFFUL << TPI_FIFO1_ITM2_Pos) /*!< TPI FIFO1: ITM2 Mask */
#define TPI_FIFO1_ITM1_Pos 8U /*!< TPI FIFO1: ITM1 Position */
#define TPI_FIFO1_ITM1_Msk (0xFFUL << TPI_FIFO1_ITM1_Pos) /*!< TPI FIFO1: ITM1 Mask */
#define TPI_FIFO1_ITM0_Pos 0U /*!< TPI FIFO1: ITM0 Position */
#define TPI_FIFO1_ITM0_Msk (0xFFUL /*<< TPI_FIFO1_ITM0_Pos*/) /*!< TPI FIFO1: ITM0 Mask */
/* TPI ITATBCTR0 Register Definitions */
#define TPI_ITATBCTR0_ATREADY2_Pos 0U /*!< TPI ITATBCTR0: ATREADY2 Position */
#define TPI_ITATBCTR0_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY2_Pos*/) /*!< TPI ITATBCTR0: ATREADY2 Mask */
#define TPI_ITATBCTR0_ATREADY1_Pos 0U /*!< TPI ITATBCTR0: ATREADY1 Position */
#define TPI_ITATBCTR0_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY1_Pos*/) /*!< TPI ITATBCTR0: ATREADY1 Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x3UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_MinBufSz_Pos 6U /*!< TPI DEVID: MinBufSz Position */
#define TPI_DEVID_MinBufSz_Msk (0x7UL << TPI_DEVID_MinBufSz_Pos) /*!< TPI DEVID: MinBufSz Mask */
#define TPI_DEVID_AsynClkIn_Pos 5U /*!< TPI DEVID: AsynClkIn Position */
#define TPI_DEVID_AsynClkIn_Msk (0x1UL << TPI_DEVID_AsynClkIn_Pos) /*!< TPI DEVID: AsynClkIn Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x1FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region RNRber Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RASR; /*!< Offset: 0x010 (R/W) MPU Region Attribute and Size Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Alias 1 Region Base Address Register */
__IOM uint32_t RASR_A1; /*!< Offset: 0x018 (R/W) MPU Alias 1 Region Attribute and Size Register */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Alias 2 Region Base Address Register */
__IOM uint32_t RASR_A2; /*!< Offset: 0x020 (R/W) MPU Alias 2 Region Attribute and Size Register */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Alias 3 Region Base Address Register */
__IOM uint32_t RASR_A3; /*!< Offset: 0x028 (R/W) MPU Alias 3 Region Attribute and Size Register */
} MPU_Type;
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_ADDR_Pos 5U /*!< MPU RBAR: ADDR Position */
#define MPU_RBAR_ADDR_Msk (0x7FFFFFFUL << MPU_RBAR_ADDR_Pos) /*!< MPU RBAR: ADDR Mask */
#define MPU_RBAR_VALID_Pos 4U /*!< MPU RBAR: VALID Position */
#define MPU_RBAR_VALID_Msk (1UL << MPU_RBAR_VALID_Pos) /*!< MPU RBAR: VALID Mask */
#define MPU_RBAR_REGION_Pos 0U /*!< MPU RBAR: REGION Position */
#define MPU_RBAR_REGION_Msk (0xFUL /*<< MPU_RBAR_REGION_Pos*/) /*!< MPU RBAR: REGION Mask */
/* MPU Region Attribute and Size Register Definitions */
#define MPU_RASR_ATTRS_Pos 16U /*!< MPU RASR: MPU Region Attribute field Position */
#define MPU_RASR_ATTRS_Msk (0xFFFFUL << MPU_RASR_ATTRS_Pos) /*!< MPU RASR: MPU Region Attribute field Mask */
#define MPU_RASR_XN_Pos 28U /*!< MPU RASR: ATTRS.XN Position */
#define MPU_RASR_XN_Msk (1UL << MPU_RASR_XN_Pos) /*!< MPU RASR: ATTRS.XN Mask */
#define MPU_RASR_AP_Pos 24U /*!< MPU RASR: ATTRS.AP Position */
#define MPU_RASR_AP_Msk (0x7UL << MPU_RASR_AP_Pos) /*!< MPU RASR: ATTRS.AP Mask */
#define MPU_RASR_TEX_Pos 19U /*!< MPU RASR: ATTRS.TEX Position */
#define MPU_RASR_TEX_Msk (0x7UL << MPU_RASR_TEX_Pos) /*!< MPU RASR: ATTRS.TEX Mask */
#define MPU_RASR_S_Pos 18U /*!< MPU RASR: ATTRS.S Position */
#define MPU_RASR_S_Msk (1UL << MPU_RASR_S_Pos) /*!< MPU RASR: ATTRS.S Mask */
#define MPU_RASR_C_Pos 17U /*!< MPU RASR: ATTRS.C Position */
#define MPU_RASR_C_Msk (1UL << MPU_RASR_C_Pos) /*!< MPU RASR: ATTRS.C Mask */
#define MPU_RASR_B_Pos 16U /*!< MPU RASR: ATTRS.B Position */
#define MPU_RASR_B_Msk (1UL << MPU_RASR_B_Pos) /*!< MPU RASR: ATTRS.B Mask */
#define MPU_RASR_SRD_Pos 8U /*!< MPU RASR: Sub-Region Disable Position */
#define MPU_RASR_SRD_Msk (0xFFUL << MPU_RASR_SRD_Pos) /*!< MPU RASR: Sub-Region Disable Mask */
#define MPU_RASR_SIZE_Pos 1U /*!< MPU RASR: Region Size Field Position */
#define MPU_RASR_SIZE_Msk (0x1FUL << MPU_RASR_SIZE_Pos) /*!< MPU RASR: Region Size Field Mask */
#define MPU_RASR_ENABLE_Pos 0U /*!< MPU RASR: Region enable bit Position */
#define MPU_RASR_ENABLE_Msk (1UL /*<< MPU_RASR_ENABLE_Pos*/) /*!< MPU RASR: Region enable bit Disable Mask */
/*@} end of group CMSIS_MPU */
#endif
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHP[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IP[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHP[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4)) = vector;
/* ARM Application Note 321 states that the M3 does not require the architectural barrier */
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
return (uint32_t)(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4));
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_SC300_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 108,414 | C | 55.672765 | 178 | 0.53244 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm1.h | /**************************************************************************//**
* @file core_cm1.h
* @brief CMSIS Cortex-M1 Core Peripheral Access Layer Header File
* @version V1.0.1
* @date 12. November 2018
******************************************************************************/
/*
* Copyright (c) 2009-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM1_H_GENERIC
#define __CORE_CM1_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M1
@{
*/
#include "cmsis_version.h"
/* CMSIS CM1 definitions */
#define __CM1_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM1_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM1_CMSIS_VERSION ((__CM1_CMSIS_VERSION_MAIN << 16U) | \
__CM1_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (1U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM1_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM1_H_DEPENDANT
#define __CORE_CM1_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM1_REV
#define __CM1_REV 0x0100U
#warning "__CM1_REV not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 2U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M1 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:28; /*!< bit: 0..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:15; /*!< bit: 9..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t _reserved1:3; /*!< bit: 25..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t _reserved0:1; /*!< bit: 0 Reserved */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[1U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[31U];
__IOM uint32_t ICER[1U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[31U];
__IOM uint32_t ISPR[1U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[31U];
__IOM uint32_t ICPR[1U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[31U];
uint32_t RESERVED4[64U];
__IOM uint32_t IP[8U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register */
} NVIC_Type;
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
uint32_t RESERVED0;
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
uint32_t RESERVED1;
__IOM uint32_t SHP[2U]; /*!< Offset: 0x01C (R/W) System Handlers Priority Registers. [0] is RESERVED */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[2U];
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
} SCnSCB_Type;
/* Auxiliary Control Register Definitions */
#define SCnSCB_ACTLR_ITCMUAEN_Pos 4U /*!< ACTLR: Instruction TCM Upper Alias Enable Position */
#define SCnSCB_ACTLR_ITCMUAEN_Msk (1UL << SCnSCB_ACTLR_ITCMUAEN_Pos) /*!< ACTLR: Instruction TCM Upper Alias Enable Mask */
#define SCnSCB_ACTLR_ITCMLAEN_Pos 3U /*!< ACTLR: Instruction TCM Lower Alias Enable Position */
#define SCnSCB_ACTLR_ITCMLAEN_Msk (1UL << SCnSCB_ACTLR_ITCMLAEN_Pos) /*!< ACTLR: Instruction TCM Lower Alias Enable Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Cortex-M1 Core Debug Registers (DCB registers, SHCSR, and DFSR) are only accessible over DAP and not via processor.
Therefore they are not covered by the Cortex-M1 header file.
@{
*/
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
/*#define NVIC_GetActive __NVIC_GetActive not available for Cortex-M1 */
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
/* Interrupt Priorities are WORD accessible only under Armv6-M */
/* The following MACROS handle generation of the register offset and byte masks */
#define _BIT_SHIFT(IRQn) ( ((((uint32_t)(int32_t)(IRQn)) ) & 0x03UL) * 8UL)
#define _SHP_IDX(IRQn) ( (((((uint32_t)(int32_t)(IRQn)) & 0x0FUL)-8UL) >> 2UL) )
#define _IP_IDX(IRQn) ( (((uint32_t)(int32_t)(IRQn)) >> 2UL) )
#define __NVIC_SetPriorityGrouping(X) (void)(X)
#define __NVIC_GetPriorityGrouping() (0U)
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[_IP_IDX(IRQn)] = ((uint32_t)(NVIC->IP[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB->SHP[_SHP_IDX(IRQn)] = ((uint32_t)(SCB->SHP[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IP[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB->SHP[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
Address 0 must be mapped to SRAM.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t *vectors = (uint32_t *)0x0U;
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
/* ARM Application Note 321 states that the M1 does not require the architectural barrier */
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t *vectors = (uint32_t *)0x0U;
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = ((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
SCB_AIRCR_SYSRESETREQ_Msk);
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM1_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 42,626 | C | 42.496939 | 178 | 0.558134 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm4.h | /**************************************************************************//**
* @file core_cm4.h
* @brief CMSIS Cortex-M4 Core Peripheral Access Layer Header File
* @version V5.1.0
* @date 13. March 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM4_H_GENERIC
#define __CORE_CM4_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M4
@{
*/
#include "cmsis_version.h"
/* CMSIS CM4 definitions */
#define __CM4_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM4_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM4_CMSIS_VERSION ((__CM4_CMSIS_VERSION_MAIN << 16U) | \
__CM4_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (4U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
For this, __FPU_PRESENT has to be checked prior to making use of FPU specific registers and functions.
*/
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#warning "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM4_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM4_H_DEPENDANT
#define __CORE_CM4_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM4_REV
#define __CM4_REV 0x0000U
#warning "__CM4_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M4 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core FPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:16; /*!< bit: 0..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:7; /*!< bit: 20..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
#define APSR_GE_Pos 16U /*!< APSR: GE Position */
#define APSR_GE_Msk (0xFUL << APSR_GE_Pos) /*!< APSR: GE Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:1; /*!< bit: 9 Reserved */
uint32_t ICI_IT_1:6; /*!< bit: 10..15 ICI/IT part 1 */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:4; /*!< bit: 20..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit */
uint32_t ICI_IT_2:2; /*!< bit: 25..26 ICI/IT part 2 */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_ICI_IT_2_Pos 25U /*!< xPSR: ICI/IT part 2 Position */
#define xPSR_ICI_IT_2_Msk (3UL << xPSR_ICI_IT_2_Pos) /*!< xPSR: ICI/IT part 2 Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_GE_Pos 16U /*!< xPSR: GE Position */
#define xPSR_GE_Msk (0xFUL << xPSR_GE_Pos) /*!< xPSR: GE Mask */
#define xPSR_ICI_IT_1_Pos 10U /*!< xPSR: ICI/IT part 1 Position */
#define xPSR_ICI_IT_1_Msk (0x3FUL << xPSR_ICI_IT_1_Pos) /*!< xPSR: ICI/IT part 1 Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t FPCA:1; /*!< bit: 2 FP extension active flag */
uint32_t _reserved0:29; /*!< bit: 3..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_FPCA_Pos 2U /*!< CONTROL: FPCA Position */
#define CONTROL_FPCA_Msk (1UL << CONTROL_FPCA_Pos) /*!< CONTROL: FPCA Mask */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[8U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[24U];
__IOM uint32_t ICER[8U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RESERVED1[24U];
__IOM uint32_t ISPR[8U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[24U];
__IOM uint32_t ICPR[8U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[24U];
__IOM uint32_t IABR[8U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[56U];
__IOM uint8_t IP[240U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED5[644U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHP[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ADR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t MMFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ISAR[5U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
uint32_t RESERVED0[5U];
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
#define SCB_AIRCR_VECTRESET_Pos 0U /*!< SCB AIRCR: VECTRESET Position */
#define SCB_AIRCR_VECTRESET_Msk (1UL /*<< SCB_AIRCR_VECTRESET_Pos*/) /*!< SCB AIRCR: VECTRESET Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
#define SCB_CCR_NONBASETHRDENA_Pos 0U /*!< SCB CCR: NONBASETHRDENA Position */
#define SCB_CCR_NONBASETHRDENA_Msk (1UL /*<< SCB_CCR_NONBASETHRDENA_Pos*/) /*!< SCB CCR: NONBASETHRDENA Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MLSPERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 5U) /*!< SCB CFSR (MMFSR): MLSPERR Position */
#define SCB_CFSR_MLSPERR_Msk (1UL << SCB_CFSR_MLSPERR_Pos) /*!< SCB CFSR (MMFSR): MLSPERR Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_LSPERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 5U) /*!< SCB CFSR (BFSR): LSPERR Position */
#define SCB_CFSR_LSPERR_Msk (1UL << SCB_CFSR_LSPERR_Pos) /*!< SCB CFSR (BFSR): LSPERR Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/* Auxiliary Control Register Definitions */
#define SCnSCB_ACTLR_DISOOFP_Pos 9U /*!< ACTLR: DISOOFP Position */
#define SCnSCB_ACTLR_DISOOFP_Msk (1UL << SCnSCB_ACTLR_DISOOFP_Pos) /*!< ACTLR: DISOOFP Mask */
#define SCnSCB_ACTLR_DISFPCA_Pos 8U /*!< ACTLR: DISFPCA Position */
#define SCnSCB_ACTLR_DISFPCA_Msk (1UL << SCnSCB_ACTLR_DISFPCA_Pos) /*!< ACTLR: DISFPCA Mask */
#define SCnSCB_ACTLR_DISFOLD_Pos 2U /*!< ACTLR: DISFOLD Position */
#define SCnSCB_ACTLR_DISFOLD_Msk (1UL << SCnSCB_ACTLR_DISFOLD_Pos) /*!< ACTLR: DISFOLD Mask */
#define SCnSCB_ACTLR_DISDEFWBUF_Pos 1U /*!< ACTLR: DISDEFWBUF Position */
#define SCnSCB_ACTLR_DISDEFWBUF_Msk (1UL << SCnSCB_ACTLR_DISDEFWBUF_Pos) /*!< ACTLR: DISDEFWBUF Mask */
#define SCnSCB_ACTLR_DISMCYCINT_Pos 0U /*!< ACTLR: DISMCYCINT Position */
#define SCnSCB_ACTLR_DISMCYCINT_Msk (1UL /*<< SCnSCB_ACTLR_DISMCYCINT_Pos*/) /*!< ACTLR: DISMCYCINT Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[32U];
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[6U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFFFFFFFFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TraceBusID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TraceBusID_Msk (0x7FUL << ITM_TCR_TraceBusID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPrescale_Pos 8U /*!< ITM TCR: TSPrescale Position */
#define ITM_TCR_TSPrescale_Msk (3UL << ITM_TCR_TSPrescale_Pos) /*!< ITM TCR: TSPrescale Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
__IOM uint32_t MASK0; /*!< Offset: 0x024 (R/W) Mask Register 0 */
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED0[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
__IOM uint32_t MASK1; /*!< Offset: 0x034 (R/W) Mask Register 1 */
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED1[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
__IOM uint32_t MASK2; /*!< Offset: 0x044 (R/W) Mask Register 2 */
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
__IOM uint32_t MASK3; /*!< Offset: 0x054 (R/W) Mask Register 3 */
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Mask Register Definitions */
#define DWT_MASK_MASK_Pos 0U /*!< DWT MASK: MASK Position */
#define DWT_MASK_MASK_Msk (0x1FUL /*<< DWT_MASK_MASK_Pos*/) /*!< DWT MASK: MASK Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVADDR1_Pos 16U /*!< DWT FUNCTION: DATAVADDR1 Position */
#define DWT_FUNCTION_DATAVADDR1_Msk (0xFUL << DWT_FUNCTION_DATAVADDR1_Pos) /*!< DWT FUNCTION: DATAVADDR1 Mask */
#define DWT_FUNCTION_DATAVADDR0_Pos 12U /*!< DWT FUNCTION: DATAVADDR0 Position */
#define DWT_FUNCTION_DATAVADDR0_Msk (0xFUL << DWT_FUNCTION_DATAVADDR0_Pos) /*!< DWT FUNCTION: DATAVADDR0 Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_LNK1ENA_Pos 9U /*!< DWT FUNCTION: LNK1ENA Position */
#define DWT_FUNCTION_LNK1ENA_Msk (0x1UL << DWT_FUNCTION_LNK1ENA_Pos) /*!< DWT FUNCTION: LNK1ENA Mask */
#define DWT_FUNCTION_DATAVMATCH_Pos 8U /*!< DWT FUNCTION: DATAVMATCH Position */
#define DWT_FUNCTION_DATAVMATCH_Msk (0x1UL << DWT_FUNCTION_DATAVMATCH_Pos) /*!< DWT FUNCTION: DATAVMATCH Mask */
#define DWT_FUNCTION_CYCMATCH_Pos 7U /*!< DWT FUNCTION: CYCMATCH Position */
#define DWT_FUNCTION_CYCMATCH_Msk (0x1UL << DWT_FUNCTION_CYCMATCH_Pos) /*!< DWT FUNCTION: CYCMATCH Mask */
#define DWT_FUNCTION_EMITRANGE_Pos 5U /*!< DWT FUNCTION: EMITRANGE Position */
#define DWT_FUNCTION_EMITRANGE_Msk (0x1UL << DWT_FUNCTION_EMITRANGE_Pos) /*!< DWT FUNCTION: EMITRANGE Mask */
#define DWT_FUNCTION_FUNCTION_Pos 0U /*!< DWT FUNCTION: FUNCTION Position */
#define DWT_FUNCTION_FUNCTION_Msk (0xFUL /*<< DWT_FUNCTION_FUNCTION_Pos*/) /*!< DWT FUNCTION: FUNCTION Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Size Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Size Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IM uint32_t FSCR; /*!< Offset: 0x308 (R/ ) Formatter Synchronization Counter Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER Register */
__IM uint32_t FIFO0; /*!< Offset: 0xEEC (R/ ) Integration ETM Data */
__IM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/ ) ITATBCTR2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) ITATBCTR0 */
__IM uint32_t FIFO1; /*!< Offset: 0xEFC (R/ ) Integration ITM Data */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) TPIU_DEVID */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) TPIU_DEVTYPE */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration ETM Data Register Definitions (FIFO0) */
#define TPI_FIFO0_ITM_ATVALID_Pos 29U /*!< TPI FIFO0: ITM_ATVALID Position */
#define TPI_FIFO0_ITM_ATVALID_Msk (0x1UL << TPI_FIFO0_ITM_ATVALID_Pos) /*!< TPI FIFO0: ITM_ATVALID Mask */
#define TPI_FIFO0_ITM_bytecount_Pos 27U /*!< TPI FIFO0: ITM_bytecount Position */
#define TPI_FIFO0_ITM_bytecount_Msk (0x3UL << TPI_FIFO0_ITM_bytecount_Pos) /*!< TPI FIFO0: ITM_bytecount Mask */
#define TPI_FIFO0_ETM_ATVALID_Pos 26U /*!< TPI FIFO0: ETM_ATVALID Position */
#define TPI_FIFO0_ETM_ATVALID_Msk (0x1UL << TPI_FIFO0_ETM_ATVALID_Pos) /*!< TPI FIFO0: ETM_ATVALID Mask */
#define TPI_FIFO0_ETM_bytecount_Pos 24U /*!< TPI FIFO0: ETM_bytecount Position */
#define TPI_FIFO0_ETM_bytecount_Msk (0x3UL << TPI_FIFO0_ETM_bytecount_Pos) /*!< TPI FIFO0: ETM_bytecount Mask */
#define TPI_FIFO0_ETM2_Pos 16U /*!< TPI FIFO0: ETM2 Position */
#define TPI_FIFO0_ETM2_Msk (0xFFUL << TPI_FIFO0_ETM2_Pos) /*!< TPI FIFO0: ETM2 Mask */
#define TPI_FIFO0_ETM1_Pos 8U /*!< TPI FIFO0: ETM1 Position */
#define TPI_FIFO0_ETM1_Msk (0xFFUL << TPI_FIFO0_ETM1_Pos) /*!< TPI FIFO0: ETM1 Mask */
#define TPI_FIFO0_ETM0_Pos 0U /*!< TPI FIFO0: ETM0 Position */
#define TPI_FIFO0_ETM0_Msk (0xFFUL /*<< TPI_FIFO0_ETM0_Pos*/) /*!< TPI FIFO0: ETM0 Mask */
/* TPI ITATBCTR2 Register Definitions */
#define TPI_ITATBCTR2_ATREADY2_Pos 0U /*!< TPI ITATBCTR2: ATREADY2 Position */
#define TPI_ITATBCTR2_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY2_Pos*/) /*!< TPI ITATBCTR2: ATREADY2 Mask */
#define TPI_ITATBCTR2_ATREADY1_Pos 0U /*!< TPI ITATBCTR2: ATREADY1 Position */
#define TPI_ITATBCTR2_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY1_Pos*/) /*!< TPI ITATBCTR2: ATREADY1 Mask */
/* TPI Integration ITM Data Register Definitions (FIFO1) */
#define TPI_FIFO1_ITM_ATVALID_Pos 29U /*!< TPI FIFO1: ITM_ATVALID Position */
#define TPI_FIFO1_ITM_ATVALID_Msk (0x1UL << TPI_FIFO1_ITM_ATVALID_Pos) /*!< TPI FIFO1: ITM_ATVALID Mask */
#define TPI_FIFO1_ITM_bytecount_Pos 27U /*!< TPI FIFO1: ITM_bytecount Position */
#define TPI_FIFO1_ITM_bytecount_Msk (0x3UL << TPI_FIFO1_ITM_bytecount_Pos) /*!< TPI FIFO1: ITM_bytecount Mask */
#define TPI_FIFO1_ETM_ATVALID_Pos 26U /*!< TPI FIFO1: ETM_ATVALID Position */
#define TPI_FIFO1_ETM_ATVALID_Msk (0x1UL << TPI_FIFO1_ETM_ATVALID_Pos) /*!< TPI FIFO1: ETM_ATVALID Mask */
#define TPI_FIFO1_ETM_bytecount_Pos 24U /*!< TPI FIFO1: ETM_bytecount Position */
#define TPI_FIFO1_ETM_bytecount_Msk (0x3UL << TPI_FIFO1_ETM_bytecount_Pos) /*!< TPI FIFO1: ETM_bytecount Mask */
#define TPI_FIFO1_ITM2_Pos 16U /*!< TPI FIFO1: ITM2 Position */
#define TPI_FIFO1_ITM2_Msk (0xFFUL << TPI_FIFO1_ITM2_Pos) /*!< TPI FIFO1: ITM2 Mask */
#define TPI_FIFO1_ITM1_Pos 8U /*!< TPI FIFO1: ITM1 Position */
#define TPI_FIFO1_ITM1_Msk (0xFFUL << TPI_FIFO1_ITM1_Pos) /*!< TPI FIFO1: ITM1 Mask */
#define TPI_FIFO1_ITM0_Pos 0U /*!< TPI FIFO1: ITM0 Position */
#define TPI_FIFO1_ITM0_Msk (0xFFUL /*<< TPI_FIFO1_ITM0_Pos*/) /*!< TPI FIFO1: ITM0 Mask */
/* TPI ITATBCTR0 Register Definitions */
#define TPI_ITATBCTR0_ATREADY2_Pos 0U /*!< TPI ITATBCTR0: ATREADY2 Position */
#define TPI_ITATBCTR0_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY2_Pos*/) /*!< TPI ITATBCTR0: ATREADY2 Mask */
#define TPI_ITATBCTR0_ATREADY1_Pos 0U /*!< TPI ITATBCTR0: ATREADY1 Position */
#define TPI_ITATBCTR0_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY1_Pos*/) /*!< TPI ITATBCTR0: ATREADY1 Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x3UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_MinBufSz_Pos 6U /*!< TPI DEVID: MinBufSz Position */
#define TPI_DEVID_MinBufSz_Msk (0x7UL << TPI_DEVID_MinBufSz_Pos) /*!< TPI DEVID: MinBufSz Mask */
#define TPI_DEVID_AsynClkIn_Pos 5U /*!< TPI DEVID: AsynClkIn Position */
#define TPI_DEVID_AsynClkIn_Msk (0x1UL << TPI_DEVID_AsynClkIn_Pos) /*!< TPI DEVID: AsynClkIn Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x1FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region RNRber Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RASR; /*!< Offset: 0x010 (R/W) MPU Region Attribute and Size Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Alias 1 Region Base Address Register */
__IOM uint32_t RASR_A1; /*!< Offset: 0x018 (R/W) MPU Alias 1 Region Attribute and Size Register */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Alias 2 Region Base Address Register */
__IOM uint32_t RASR_A2; /*!< Offset: 0x020 (R/W) MPU Alias 2 Region Attribute and Size Register */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Alias 3 Region Base Address Register */
__IOM uint32_t RASR_A3; /*!< Offset: 0x028 (R/W) MPU Alias 3 Region Attribute and Size Register */
} MPU_Type;
#define MPU_TYPE_RALIASES 4U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_ADDR_Pos 5U /*!< MPU RBAR: ADDR Position */
#define MPU_RBAR_ADDR_Msk (0x7FFFFFFUL << MPU_RBAR_ADDR_Pos) /*!< MPU RBAR: ADDR Mask */
#define MPU_RBAR_VALID_Pos 4U /*!< MPU RBAR: VALID Position */
#define MPU_RBAR_VALID_Msk (1UL << MPU_RBAR_VALID_Pos) /*!< MPU RBAR: VALID Mask */
#define MPU_RBAR_REGION_Pos 0U /*!< MPU RBAR: REGION Position */
#define MPU_RBAR_REGION_Msk (0xFUL /*<< MPU_RBAR_REGION_Pos*/) /*!< MPU RBAR: REGION Mask */
/* MPU Region Attribute and Size Register Definitions */
#define MPU_RASR_ATTRS_Pos 16U /*!< MPU RASR: MPU Region Attribute field Position */
#define MPU_RASR_ATTRS_Msk (0xFFFFUL << MPU_RASR_ATTRS_Pos) /*!< MPU RASR: MPU Region Attribute field Mask */
#define MPU_RASR_XN_Pos 28U /*!< MPU RASR: ATTRS.XN Position */
#define MPU_RASR_XN_Msk (1UL << MPU_RASR_XN_Pos) /*!< MPU RASR: ATTRS.XN Mask */
#define MPU_RASR_AP_Pos 24U /*!< MPU RASR: ATTRS.AP Position */
#define MPU_RASR_AP_Msk (0x7UL << MPU_RASR_AP_Pos) /*!< MPU RASR: ATTRS.AP Mask */
#define MPU_RASR_TEX_Pos 19U /*!< MPU RASR: ATTRS.TEX Position */
#define MPU_RASR_TEX_Msk (0x7UL << MPU_RASR_TEX_Pos) /*!< MPU RASR: ATTRS.TEX Mask */
#define MPU_RASR_S_Pos 18U /*!< MPU RASR: ATTRS.S Position */
#define MPU_RASR_S_Msk (1UL << MPU_RASR_S_Pos) /*!< MPU RASR: ATTRS.S Mask */
#define MPU_RASR_C_Pos 17U /*!< MPU RASR: ATTRS.C Position */
#define MPU_RASR_C_Msk (1UL << MPU_RASR_C_Pos) /*!< MPU RASR: ATTRS.C Mask */
#define MPU_RASR_B_Pos 16U /*!< MPU RASR: ATTRS.B Position */
#define MPU_RASR_B_Msk (1UL << MPU_RASR_B_Pos) /*!< MPU RASR: ATTRS.B Mask */
#define MPU_RASR_SRD_Pos 8U /*!< MPU RASR: Sub-Region Disable Position */
#define MPU_RASR_SRD_Msk (0xFFUL << MPU_RASR_SRD_Pos) /*!< MPU RASR: Sub-Region Disable Mask */
#define MPU_RASR_SIZE_Pos 1U /*!< MPU RASR: Region Size Field Position */
#define MPU_RASR_SIZE_Msk (0x1FUL << MPU_RASR_SIZE_Pos) /*!< MPU RASR: Region Size Field Mask */
#define MPU_RASR_ENABLE_Pos 0U /*!< MPU RASR: Region enable bit Position */
#define MPU_RASR_ENABLE_Msk (1UL /*<< MPU_RASR_ENABLE_Pos*/) /*!< MPU RASR: Region enable bit Disable Mask */
/*@} end of group CMSIS_MPU */
#endif /* defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_FPU Floating Point Unit (FPU)
\brief Type definitions for the Floating Point Unit (FPU)
@{
*/
/**
\brief Structure type to access the Floating Point Unit (FPU).
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IOM uint32_t FPCCR; /*!< Offset: 0x004 (R/W) Floating-Point Context Control Register */
__IOM uint32_t FPCAR; /*!< Offset: 0x008 (R/W) Floating-Point Context Address Register */
__IOM uint32_t FPDSCR; /*!< Offset: 0x00C (R/W) Floating-Point Default Status Control Register */
__IM uint32_t MVFR0; /*!< Offset: 0x010 (R/ ) Media and FP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x014 (R/ ) Media and FP Feature Register 1 */
__IM uint32_t MVFR2; /*!< Offset: 0x018 (R/ ) Media and FP Feature Register 2 */
} FPU_Type;
/* Floating-Point Context Control Register Definitions */
#define FPU_FPCCR_ASPEN_Pos 31U /*!< FPCCR: ASPEN bit Position */
#define FPU_FPCCR_ASPEN_Msk (1UL << FPU_FPCCR_ASPEN_Pos) /*!< FPCCR: ASPEN bit Mask */
#define FPU_FPCCR_LSPEN_Pos 30U /*!< FPCCR: LSPEN Position */
#define FPU_FPCCR_LSPEN_Msk (1UL << FPU_FPCCR_LSPEN_Pos) /*!< FPCCR: LSPEN bit Mask */
#define FPU_FPCCR_MONRDY_Pos 8U /*!< FPCCR: MONRDY Position */
#define FPU_FPCCR_MONRDY_Msk (1UL << FPU_FPCCR_MONRDY_Pos) /*!< FPCCR: MONRDY bit Mask */
#define FPU_FPCCR_BFRDY_Pos 6U /*!< FPCCR: BFRDY Position */
#define FPU_FPCCR_BFRDY_Msk (1UL << FPU_FPCCR_BFRDY_Pos) /*!< FPCCR: BFRDY bit Mask */
#define FPU_FPCCR_MMRDY_Pos 5U /*!< FPCCR: MMRDY Position */
#define FPU_FPCCR_MMRDY_Msk (1UL << FPU_FPCCR_MMRDY_Pos) /*!< FPCCR: MMRDY bit Mask */
#define FPU_FPCCR_HFRDY_Pos 4U /*!< FPCCR: HFRDY Position */
#define FPU_FPCCR_HFRDY_Msk (1UL << FPU_FPCCR_HFRDY_Pos) /*!< FPCCR: HFRDY bit Mask */
#define FPU_FPCCR_THREAD_Pos 3U /*!< FPCCR: processor mode bit Position */
#define FPU_FPCCR_THREAD_Msk (1UL << FPU_FPCCR_THREAD_Pos) /*!< FPCCR: processor mode active bit Mask */
#define FPU_FPCCR_USER_Pos 1U /*!< FPCCR: privilege level bit Position */
#define FPU_FPCCR_USER_Msk (1UL << FPU_FPCCR_USER_Pos) /*!< FPCCR: privilege level bit Mask */
#define FPU_FPCCR_LSPACT_Pos 0U /*!< FPCCR: Lazy state preservation active bit Position */
#define FPU_FPCCR_LSPACT_Msk (1UL /*<< FPU_FPCCR_LSPACT_Pos*/) /*!< FPCCR: Lazy state preservation active bit Mask */
/* Floating-Point Context Address Register Definitions */
#define FPU_FPCAR_ADDRESS_Pos 3U /*!< FPCAR: ADDRESS bit Position */
#define FPU_FPCAR_ADDRESS_Msk (0x1FFFFFFFUL << FPU_FPCAR_ADDRESS_Pos) /*!< FPCAR: ADDRESS bit Mask */
/* Floating-Point Default Status Control Register Definitions */
#define FPU_FPDSCR_AHP_Pos 26U /*!< FPDSCR: AHP bit Position */
#define FPU_FPDSCR_AHP_Msk (1UL << FPU_FPDSCR_AHP_Pos) /*!< FPDSCR: AHP bit Mask */
#define FPU_FPDSCR_DN_Pos 25U /*!< FPDSCR: DN bit Position */
#define FPU_FPDSCR_DN_Msk (1UL << FPU_FPDSCR_DN_Pos) /*!< FPDSCR: DN bit Mask */
#define FPU_FPDSCR_FZ_Pos 24U /*!< FPDSCR: FZ bit Position */
#define FPU_FPDSCR_FZ_Msk (1UL << FPU_FPDSCR_FZ_Pos) /*!< FPDSCR: FZ bit Mask */
#define FPU_FPDSCR_RMode_Pos 22U /*!< FPDSCR: RMode bit Position */
#define FPU_FPDSCR_RMode_Msk (3UL << FPU_FPDSCR_RMode_Pos) /*!< FPDSCR: RMode bit Mask */
/* Media and FP Feature Register 0 Definitions */
#define FPU_MVFR0_FP_rounding_modes_Pos 28U /*!< MVFR0: FP rounding modes bits Position */
#define FPU_MVFR0_FP_rounding_modes_Msk (0xFUL << FPU_MVFR0_FP_rounding_modes_Pos) /*!< MVFR0: FP rounding modes bits Mask */
#define FPU_MVFR0_Short_vectors_Pos 24U /*!< MVFR0: Short vectors bits Position */
#define FPU_MVFR0_Short_vectors_Msk (0xFUL << FPU_MVFR0_Short_vectors_Pos) /*!< MVFR0: Short vectors bits Mask */
#define FPU_MVFR0_Square_root_Pos 20U /*!< MVFR0: Square root bits Position */
#define FPU_MVFR0_Square_root_Msk (0xFUL << FPU_MVFR0_Square_root_Pos) /*!< MVFR0: Square root bits Mask */
#define FPU_MVFR0_Divide_Pos 16U /*!< MVFR0: Divide bits Position */
#define FPU_MVFR0_Divide_Msk (0xFUL << FPU_MVFR0_Divide_Pos) /*!< MVFR0: Divide bits Mask */
#define FPU_MVFR0_FP_excep_trapping_Pos 12U /*!< MVFR0: FP exception trapping bits Position */
#define FPU_MVFR0_FP_excep_trapping_Msk (0xFUL << FPU_MVFR0_FP_excep_trapping_Pos) /*!< MVFR0: FP exception trapping bits Mask */
#define FPU_MVFR0_Double_precision_Pos 8U /*!< MVFR0: Double-precision bits Position */
#define FPU_MVFR0_Double_precision_Msk (0xFUL << FPU_MVFR0_Double_precision_Pos) /*!< MVFR0: Double-precision bits Mask */
#define FPU_MVFR0_Single_precision_Pos 4U /*!< MVFR0: Single-precision bits Position */
#define FPU_MVFR0_Single_precision_Msk (0xFUL << FPU_MVFR0_Single_precision_Pos) /*!< MVFR0: Single-precision bits Mask */
#define FPU_MVFR0_A_SIMD_registers_Pos 0U /*!< MVFR0: A_SIMD registers bits Position */
#define FPU_MVFR0_A_SIMD_registers_Msk (0xFUL /*<< FPU_MVFR0_A_SIMD_registers_Pos*/) /*!< MVFR0: A_SIMD registers bits Mask */
/* Media and FP Feature Register 1 Definitions */
#define FPU_MVFR1_FP_fused_MAC_Pos 28U /*!< MVFR1: FP fused MAC bits Position */
#define FPU_MVFR1_FP_fused_MAC_Msk (0xFUL << FPU_MVFR1_FP_fused_MAC_Pos) /*!< MVFR1: FP fused MAC bits Mask */
#define FPU_MVFR1_FP_HPFP_Pos 24U /*!< MVFR1: FP HPFP bits Position */
#define FPU_MVFR1_FP_HPFP_Msk (0xFUL << FPU_MVFR1_FP_HPFP_Pos) /*!< MVFR1: FP HPFP bits Mask */
#define FPU_MVFR1_D_NaN_mode_Pos 4U /*!< MVFR1: D_NaN mode bits Position */
#define FPU_MVFR1_D_NaN_mode_Msk (0xFUL << FPU_MVFR1_D_NaN_mode_Pos) /*!< MVFR1: D_NaN mode bits Mask */
#define FPU_MVFR1_FtZ_mode_Pos 0U /*!< MVFR1: FtZ mode bits Position */
#define FPU_MVFR1_FtZ_mode_Msk (0xFUL /*<< FPU_MVFR1_FtZ_mode_Pos*/) /*!< MVFR1: FtZ mode bits Mask */
/* Media and FP Feature Register 2 Definitions */
#define FPU_MVFR2_VFP_Misc_Pos 4U /*!< MVFR2: VFP Misc bits Position */
#define FPU_MVFR2_VFP_Misc_Msk (0xFUL << FPU_MVFR2_VFP_Misc_Pos) /*!< MVFR2: VFP Misc bits Mask */
/*@} end of group CMSIS_FPU */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#define FPU_BASE (SCS_BASE + 0x0F30UL) /*!< Floating Point Unit */
#define FPU ((FPU_Type *) FPU_BASE ) /*!< Floating Point Unit */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
#define EXC_RETURN_HANDLER_FPU (0xFFFFFFE1UL) /* return to Handler mode, uses MSP after return, restore floating-point state */
#define EXC_RETURN_THREAD_MSP_FPU (0xFFFFFFE9UL) /* return to Thread mode, uses MSP after return, restore floating-point state */
#define EXC_RETURN_THREAD_PSP_FPU (0xFFFFFFEDUL) /* return to Thread mode, uses PSP after return, restore floating-point state */
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHP[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IP[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHP[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4)) = vector;
/* ARM Application Note 321 states that the M4 does not require the architectural barrier */
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
return (uint32_t)(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4));
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv7.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
uint32_t mvfr0;
mvfr0 = FPU->MVFR0;
if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x020U)
{
return 1U; /* Single precision FPU */
}
else
{
return 0U; /* No FPU */
}
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM4_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 120,867 | C | 55.879059 | 178 | 0.528804 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm35p.h | /**************************************************************************//**
* @file core_cm35p.h
* @brief CMSIS Cortex-M35P Core Peripheral Access Layer Header File
* @version V1.0.0
* @date 12. November 2018
******************************************************************************/
/*
* Copyright (c) 2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM35P_H_GENERIC
#define __CORE_CM35P_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M35P
@{
*/
#include "cmsis_version.h"
/* CMSIS CM35P definitions */
#define __CM35P_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM35P_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM35P_CMSIS_VERSION ((__CM35P_CMSIS_VERSION_MAIN << 16U) | \
__CM35P_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (35U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
For this, __FPU_PRESENT has to be checked prior to making use of FPU specific registers and functions.
*/
#if defined ( __CC_ARM )
#if defined (__TARGET_FPU_VFP)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined (__ARM_FP)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#warning "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __ICCARM__ )
#if defined (__ARMVFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __TI_ARM__ )
#if defined (__TI_VFP_SUPPORT__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TASKING__ )
#if defined (__FPU_VFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM35P_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM35P_H_DEPENDANT
#define __CORE_CM35P_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM35P_REV
#define __CM35P_REV 0x0000U
#warning "__CM35P_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __SAUREGION_PRESENT
#define __SAUREGION_PRESENT 0U
#warning "__SAUREGION_PRESENT not defined in device header file; using default!"
#endif
#ifndef __DSP_PRESENT
#define __DSP_PRESENT 0U
#warning "__DSP_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M35P */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core SAU Register
- Core FPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:16; /*!< bit: 0..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:7; /*!< bit: 20..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
#define APSR_GE_Pos 16U /*!< APSR: GE Position */
#define APSR_GE_Msk (0xFUL << APSR_GE_Pos) /*!< APSR: GE Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:7; /*!< bit: 9..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:4; /*!< bit: 20..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t IT:2; /*!< bit: 25..26 saved IT state (read 0) */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_IT_Pos 25U /*!< xPSR: IT Position */
#define xPSR_IT_Msk (3UL << xPSR_IT_Pos) /*!< xPSR: IT Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_GE_Pos 16U /*!< xPSR: GE Position */
#define xPSR_GE_Msk (0xFUL << xPSR_GE_Pos) /*!< xPSR: GE Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack-pointer select */
uint32_t FPCA:1; /*!< bit: 2 Floating-point context active */
uint32_t SFPA:1; /*!< bit: 3 Secure floating-point active */
uint32_t _reserved1:28; /*!< bit: 4..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SFPA_Pos 3U /*!< CONTROL: SFPA Position */
#define CONTROL_SFPA_Msk (1UL << CONTROL_SFPA_Pos) /*!< CONTROL: SFPA Mask */
#define CONTROL_FPCA_Pos 2U /*!< CONTROL: FPCA Position */
#define CONTROL_FPCA_Msk (1UL << CONTROL_FPCA_Pos) /*!< CONTROL: FPCA Mask */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[16U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[16U];
__IOM uint32_t ICER[16U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[16U];
__IOM uint32_t ISPR[16U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[16U];
__IOM uint32_t ICPR[16U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[16U];
__IOM uint32_t IABR[16U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[16U];
__IOM uint32_t ITNS[16U]; /*!< Offset: 0x280 (R/W) Interrupt Non-Secure State Register */
uint32_t RESERVED5[16U];
__IOM uint8_t IPR[496U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED6[580U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHPR[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t ID_PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t ID_DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ID_ADR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t ID_MMFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ID_ISAR[6U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
__IM uint32_t CLIDR; /*!< Offset: 0x078 (R/ ) Cache Level ID register */
__IM uint32_t CTR; /*!< Offset: 0x07C (R/ ) Cache Type register */
__IM uint32_t CCSIDR; /*!< Offset: 0x080 (R/ ) Cache Size ID Register */
__IOM uint32_t CSSELR; /*!< Offset: 0x084 (R/W) Cache Size Selection Register */
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
__IOM uint32_t NSACR; /*!< Offset: 0x08C (R/W) Non-Secure Access Control Register */
uint32_t RESERVED3[92U];
__OM uint32_t STIR; /*!< Offset: 0x200 ( /W) Software Triggered Interrupt Register */
uint32_t RESERVED4[15U];
__IM uint32_t MVFR0; /*!< Offset: 0x240 (R/ ) Media and VFP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x244 (R/ ) Media and VFP Feature Register 1 */
__IM uint32_t MVFR2; /*!< Offset: 0x248 (R/ ) Media and VFP Feature Register 2 */
uint32_t RESERVED5[1U];
__OM uint32_t ICIALLU; /*!< Offset: 0x250 ( /W) I-Cache Invalidate All to PoU */
uint32_t RESERVED6[1U];
__OM uint32_t ICIMVAU; /*!< Offset: 0x258 ( /W) I-Cache Invalidate by MVA to PoU */
__OM uint32_t DCIMVAC; /*!< Offset: 0x25C ( /W) D-Cache Invalidate by MVA to PoC */
__OM uint32_t DCISW; /*!< Offset: 0x260 ( /W) D-Cache Invalidate by Set-way */
__OM uint32_t DCCMVAU; /*!< Offset: 0x264 ( /W) D-Cache Clean by MVA to PoU */
__OM uint32_t DCCMVAC; /*!< Offset: 0x268 ( /W) D-Cache Clean by MVA to PoC */
__OM uint32_t DCCSW; /*!< Offset: 0x26C ( /W) D-Cache Clean by Set-way */
__OM uint32_t DCCIMVAC; /*!< Offset: 0x270 ( /W) D-Cache Clean and Invalidate by MVA to PoC */
__OM uint32_t DCCISW; /*!< Offset: 0x274 ( /W) D-Cache Clean and Invalidate by Set-way */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_PENDNMISET_Pos 31U /*!< SCB ICSR: PENDNMISET Position */
#define SCB_ICSR_PENDNMISET_Msk (1UL << SCB_ICSR_PENDNMISET_Pos) /*!< SCB ICSR: PENDNMISET Mask */
#define SCB_ICSR_NMIPENDSET_Pos SCB_ICSR_PENDNMISET_Pos /*!< SCB ICSR: NMIPENDSET Position, backward compatibility */
#define SCB_ICSR_NMIPENDSET_Msk SCB_ICSR_PENDNMISET_Msk /*!< SCB ICSR: NMIPENDSET Mask, backward compatibility */
#define SCB_ICSR_PENDNMICLR_Pos 30U /*!< SCB ICSR: PENDNMICLR Position */
#define SCB_ICSR_PENDNMICLR_Msk (1UL << SCB_ICSR_PENDNMICLR_Pos) /*!< SCB ICSR: PENDNMICLR Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_STTNS_Pos 24U /*!< SCB ICSR: STTNS Position (Security Extension) */
#define SCB_ICSR_STTNS_Msk (1UL << SCB_ICSR_STTNS_Pos) /*!< SCB ICSR: STTNS Mask (Security Extension) */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIS_Pos 14U /*!< SCB AIRCR: PRIS Position */
#define SCB_AIRCR_PRIS_Msk (1UL << SCB_AIRCR_PRIS_Pos) /*!< SCB AIRCR: PRIS Mask */
#define SCB_AIRCR_BFHFNMINS_Pos 13U /*!< SCB AIRCR: BFHFNMINS Position */
#define SCB_AIRCR_BFHFNMINS_Msk (1UL << SCB_AIRCR_BFHFNMINS_Pos) /*!< SCB AIRCR: BFHFNMINS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQS_Pos 3U /*!< SCB AIRCR: SYSRESETREQS Position */
#define SCB_AIRCR_SYSRESETREQS_Msk (1UL << SCB_AIRCR_SYSRESETREQS_Pos) /*!< SCB AIRCR: SYSRESETREQS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEPS_Pos 3U /*!< SCB SCR: SLEEPDEEPS Position */
#define SCB_SCR_SLEEPDEEPS_Msk (1UL << SCB_SCR_SLEEPDEEPS_Pos) /*!< SCB SCR: SLEEPDEEPS Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_BP_Pos 18U /*!< SCB CCR: BP Position */
#define SCB_CCR_BP_Msk (1UL << SCB_CCR_BP_Pos) /*!< SCB CCR: BP Mask */
#define SCB_CCR_IC_Pos 17U /*!< SCB CCR: IC Position */
#define SCB_CCR_IC_Msk (1UL << SCB_CCR_IC_Pos) /*!< SCB CCR: IC Mask */
#define SCB_CCR_DC_Pos 16U /*!< SCB CCR: DC Position */
#define SCB_CCR_DC_Msk (1UL << SCB_CCR_DC_Pos) /*!< SCB CCR: DC Mask */
#define SCB_CCR_STKOFHFNMIGN_Pos 10U /*!< SCB CCR: STKOFHFNMIGN Position */
#define SCB_CCR_STKOFHFNMIGN_Msk (1UL << SCB_CCR_STKOFHFNMIGN_Pos) /*!< SCB CCR: STKOFHFNMIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_HARDFAULTPENDED_Pos 21U /*!< SCB SHCSR: HARDFAULTPENDED Position */
#define SCB_SHCSR_HARDFAULTPENDED_Msk (1UL << SCB_SHCSR_HARDFAULTPENDED_Pos) /*!< SCB SHCSR: HARDFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTPENDED_Pos 20U /*!< SCB SHCSR: SECUREFAULTPENDED Position */
#define SCB_SHCSR_SECUREFAULTPENDED_Msk (1UL << SCB_SHCSR_SECUREFAULTPENDED_Pos) /*!< SCB SHCSR: SECUREFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTENA_Pos 19U /*!< SCB SHCSR: SECUREFAULTENA Position */
#define SCB_SHCSR_SECUREFAULTENA_Msk (1UL << SCB_SHCSR_SECUREFAULTENA_Pos) /*!< SCB SHCSR: SECUREFAULTENA Mask */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_NMIACT_Pos 5U /*!< SCB SHCSR: NMIACT Position */
#define SCB_SHCSR_NMIACT_Msk (1UL << SCB_SHCSR_NMIACT_Pos) /*!< SCB SHCSR: NMIACT Mask */
#define SCB_SHCSR_SECUREFAULTACT_Pos 4U /*!< SCB SHCSR: SECUREFAULTACT Position */
#define SCB_SHCSR_SECUREFAULTACT_Msk (1UL << SCB_SHCSR_SECUREFAULTACT_Pos) /*!< SCB SHCSR: SECUREFAULTACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_HARDFAULTACT_Pos 2U /*!< SCB SHCSR: HARDFAULTACT Position */
#define SCB_SHCSR_HARDFAULTACT_Msk (1UL << SCB_SHCSR_HARDFAULTACT_Pos) /*!< SCB SHCSR: HARDFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MLSPERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 5U) /*!< SCB CFSR (MMFSR): MLSPERR Position */
#define SCB_CFSR_MLSPERR_Msk (1UL << SCB_CFSR_MLSPERR_Pos) /*!< SCB CFSR (MMFSR): MLSPERR Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_LSPERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 5U) /*!< SCB CFSR (BFSR): LSPERR Position */
#define SCB_CFSR_LSPERR_Msk (1UL << SCB_CFSR_LSPERR_Pos) /*!< SCB CFSR (BFSR): LSPERR Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_STKOF_Pos (SCB_CFSR_USGFAULTSR_Pos + 4U) /*!< SCB CFSR (UFSR): STKOF Position */
#define SCB_CFSR_STKOF_Msk (1UL << SCB_CFSR_STKOF_Pos) /*!< SCB CFSR (UFSR): STKOF Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/* SCB Non-Secure Access Control Register Definitions */
#define SCB_NSACR_CP11_Pos 11U /*!< SCB NSACR: CP11 Position */
#define SCB_NSACR_CP11_Msk (1UL << SCB_NSACR_CP11_Pos) /*!< SCB NSACR: CP11 Mask */
#define SCB_NSACR_CP10_Pos 10U /*!< SCB NSACR: CP10 Position */
#define SCB_NSACR_CP10_Msk (1UL << SCB_NSACR_CP10_Pos) /*!< SCB NSACR: CP10 Mask */
#define SCB_NSACR_CPn_Pos 0U /*!< SCB NSACR: CPn Position */
#define SCB_NSACR_CPn_Msk (1UL /*<< SCB_NSACR_CPn_Pos*/) /*!< SCB NSACR: CPn Mask */
/* SCB Cache Level ID Register Definitions */
#define SCB_CLIDR_LOUU_Pos 27U /*!< SCB CLIDR: LoUU Position */
#define SCB_CLIDR_LOUU_Msk (7UL << SCB_CLIDR_LOUU_Pos) /*!< SCB CLIDR: LoUU Mask */
#define SCB_CLIDR_LOC_Pos 24U /*!< SCB CLIDR: LoC Position */
#define SCB_CLIDR_LOC_Msk (7UL << SCB_CLIDR_LOC_Pos) /*!< SCB CLIDR: LoC Mask */
/* SCB Cache Type Register Definitions */
#define SCB_CTR_FORMAT_Pos 29U /*!< SCB CTR: Format Position */
#define SCB_CTR_FORMAT_Msk (7UL << SCB_CTR_FORMAT_Pos) /*!< SCB CTR: Format Mask */
#define SCB_CTR_CWG_Pos 24U /*!< SCB CTR: CWG Position */
#define SCB_CTR_CWG_Msk (0xFUL << SCB_CTR_CWG_Pos) /*!< SCB CTR: CWG Mask */
#define SCB_CTR_ERG_Pos 20U /*!< SCB CTR: ERG Position */
#define SCB_CTR_ERG_Msk (0xFUL << SCB_CTR_ERG_Pos) /*!< SCB CTR: ERG Mask */
#define SCB_CTR_DMINLINE_Pos 16U /*!< SCB CTR: DminLine Position */
#define SCB_CTR_DMINLINE_Msk (0xFUL << SCB_CTR_DMINLINE_Pos) /*!< SCB CTR: DminLine Mask */
#define SCB_CTR_IMINLINE_Pos 0U /*!< SCB CTR: ImInLine Position */
#define SCB_CTR_IMINLINE_Msk (0xFUL /*<< SCB_CTR_IMINLINE_Pos*/) /*!< SCB CTR: ImInLine Mask */
/* SCB Cache Size ID Register Definitions */
#define SCB_CCSIDR_WT_Pos 31U /*!< SCB CCSIDR: WT Position */
#define SCB_CCSIDR_WT_Msk (1UL << SCB_CCSIDR_WT_Pos) /*!< SCB CCSIDR: WT Mask */
#define SCB_CCSIDR_WB_Pos 30U /*!< SCB CCSIDR: WB Position */
#define SCB_CCSIDR_WB_Msk (1UL << SCB_CCSIDR_WB_Pos) /*!< SCB CCSIDR: WB Mask */
#define SCB_CCSIDR_RA_Pos 29U /*!< SCB CCSIDR: RA Position */
#define SCB_CCSIDR_RA_Msk (1UL << SCB_CCSIDR_RA_Pos) /*!< SCB CCSIDR: RA Mask */
#define SCB_CCSIDR_WA_Pos 28U /*!< SCB CCSIDR: WA Position */
#define SCB_CCSIDR_WA_Msk (1UL << SCB_CCSIDR_WA_Pos) /*!< SCB CCSIDR: WA Mask */
#define SCB_CCSIDR_NUMSETS_Pos 13U /*!< SCB CCSIDR: NumSets Position */
#define SCB_CCSIDR_NUMSETS_Msk (0x7FFFUL << SCB_CCSIDR_NUMSETS_Pos) /*!< SCB CCSIDR: NumSets Mask */
#define SCB_CCSIDR_ASSOCIATIVITY_Pos 3U /*!< SCB CCSIDR: Associativity Position */
#define SCB_CCSIDR_ASSOCIATIVITY_Msk (0x3FFUL << SCB_CCSIDR_ASSOCIATIVITY_Pos) /*!< SCB CCSIDR: Associativity Mask */
#define SCB_CCSIDR_LINESIZE_Pos 0U /*!< SCB CCSIDR: LineSize Position */
#define SCB_CCSIDR_LINESIZE_Msk (7UL /*<< SCB_CCSIDR_LINESIZE_Pos*/) /*!< SCB CCSIDR: LineSize Mask */
/* SCB Cache Size Selection Register Definitions */
#define SCB_CSSELR_LEVEL_Pos 1U /*!< SCB CSSELR: Level Position */
#define SCB_CSSELR_LEVEL_Msk (7UL << SCB_CSSELR_LEVEL_Pos) /*!< SCB CSSELR: Level Mask */
#define SCB_CSSELR_IND_Pos 0U /*!< SCB CSSELR: InD Position */
#define SCB_CSSELR_IND_Msk (1UL /*<< SCB_CSSELR_IND_Pos*/) /*!< SCB CSSELR: InD Mask */
/* SCB Software Triggered Interrupt Register Definitions */
#define SCB_STIR_INTID_Pos 0U /*!< SCB STIR: INTID Position */
#define SCB_STIR_INTID_Msk (0x1FFUL /*<< SCB_STIR_INTID_Pos*/) /*!< SCB STIR: INTID Mask */
/* SCB D-Cache Invalidate by Set-way Register Definitions */
#define SCB_DCISW_WAY_Pos 30U /*!< SCB DCISW: Way Position */
#define SCB_DCISW_WAY_Msk (3UL << SCB_DCISW_WAY_Pos) /*!< SCB DCISW: Way Mask */
#define SCB_DCISW_SET_Pos 5U /*!< SCB DCISW: Set Position */
#define SCB_DCISW_SET_Msk (0x1FFUL << SCB_DCISW_SET_Pos) /*!< SCB DCISW: Set Mask */
/* SCB D-Cache Clean by Set-way Register Definitions */
#define SCB_DCCSW_WAY_Pos 30U /*!< SCB DCCSW: Way Position */
#define SCB_DCCSW_WAY_Msk (3UL << SCB_DCCSW_WAY_Pos) /*!< SCB DCCSW: Way Mask */
#define SCB_DCCSW_SET_Pos 5U /*!< SCB DCCSW: Set Position */
#define SCB_DCCSW_SET_Msk (0x1FFUL << SCB_DCCSW_SET_Pos) /*!< SCB DCCSW: Set Mask */
/* SCB D-Cache Clean and Invalidate by Set-way Register Definitions */
#define SCB_DCCISW_WAY_Pos 30U /*!< SCB DCCISW: Way Position */
#define SCB_DCCISW_WAY_Msk (3UL << SCB_DCCISW_WAY_Pos) /*!< SCB DCCISW: Way Mask */
#define SCB_DCCISW_SET_Pos 5U /*!< SCB DCCISW: Set Position */
#define SCB_DCCISW_SET_Msk (0x1FFUL << SCB_DCCISW_SET_Pos) /*!< SCB DCCISW: Set Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
__IOM uint32_t CPPWR; /*!< Offset: 0x00C (R/W) Coprocessor Power Control Register */
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[32U];
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) ITM Device Architecture Register */
uint32_t RESERVED6[4U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Stimulus Port Register Definitions */
#define ITM_STIM_DISABLED_Pos 1U /*!< ITM STIM: DISABLED Position */
#define ITM_STIM_DISABLED_Msk (0x1UL << ITM_STIM_DISABLED_Pos) /*!< ITM STIM: DISABLED Mask */
#define ITM_STIM_FIFOREADY_Pos 0U /*!< ITM STIM: FIFOREADY Position */
#define ITM_STIM_FIFOREADY_Msk (0x1UL /*<< ITM_STIM_FIFOREADY_Pos*/) /*!< ITM STIM: FIFOREADY Mask */
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFFFFFFFFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TRACEBUSID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TRACEBUSID_Msk (0x7FUL << ITM_TCR_TRACEBUSID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPRESCALE_Pos 8U /*!< ITM TCR: TSPRESCALE Position */
#define ITM_TCR_TSPRESCALE_Msk (3UL << ITM_TCR_TSPRESCALE_Pos) /*!< ITM TCR: TSPRESCALE Mask */
#define ITM_TCR_STALLENA_Pos 5U /*!< ITM TCR: STALLENA Position */
#define ITM_TCR_STALLENA_Msk (1UL << ITM_TCR_STALLENA_Pos) /*!< ITM TCR: STALLENA Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
uint32_t RESERVED1[1U];
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
uint32_t RESERVED3[1U];
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED4[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
uint32_t RESERVED5[1U];
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED6[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
uint32_t RESERVED7[1U];
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
uint32_t RESERVED8[1U];
__IOM uint32_t COMP4; /*!< Offset: 0x060 (R/W) Comparator Register 4 */
uint32_t RESERVED9[1U];
__IOM uint32_t FUNCTION4; /*!< Offset: 0x068 (R/W) Function Register 4 */
uint32_t RESERVED10[1U];
__IOM uint32_t COMP5; /*!< Offset: 0x070 (R/W) Comparator Register 5 */
uint32_t RESERVED11[1U];
__IOM uint32_t FUNCTION5; /*!< Offset: 0x078 (R/W) Function Register 5 */
uint32_t RESERVED12[1U];
__IOM uint32_t COMP6; /*!< Offset: 0x080 (R/W) Comparator Register 6 */
uint32_t RESERVED13[1U];
__IOM uint32_t FUNCTION6; /*!< Offset: 0x088 (R/W) Function Register 6 */
uint32_t RESERVED14[1U];
__IOM uint32_t COMP7; /*!< Offset: 0x090 (R/W) Comparator Register 7 */
uint32_t RESERVED15[1U];
__IOM uint32_t FUNCTION7; /*!< Offset: 0x098 (R/W) Function Register 7 */
uint32_t RESERVED16[1U];
__IOM uint32_t COMP8; /*!< Offset: 0x0A0 (R/W) Comparator Register 8 */
uint32_t RESERVED17[1U];
__IOM uint32_t FUNCTION8; /*!< Offset: 0x0A8 (R/W) Function Register 8 */
uint32_t RESERVED18[1U];
__IOM uint32_t COMP9; /*!< Offset: 0x0B0 (R/W) Comparator Register 9 */
uint32_t RESERVED19[1U];
__IOM uint32_t FUNCTION9; /*!< Offset: 0x0B8 (R/W) Function Register 9 */
uint32_t RESERVED20[1U];
__IOM uint32_t COMP10; /*!< Offset: 0x0C0 (R/W) Comparator Register 10 */
uint32_t RESERVED21[1U];
__IOM uint32_t FUNCTION10; /*!< Offset: 0x0C8 (R/W) Function Register 10 */
uint32_t RESERVED22[1U];
__IOM uint32_t COMP11; /*!< Offset: 0x0D0 (R/W) Comparator Register 11 */
uint32_t RESERVED23[1U];
__IOM uint32_t FUNCTION11; /*!< Offset: 0x0D8 (R/W) Function Register 11 */
uint32_t RESERVED24[1U];
__IOM uint32_t COMP12; /*!< Offset: 0x0E0 (R/W) Comparator Register 12 */
uint32_t RESERVED25[1U];
__IOM uint32_t FUNCTION12; /*!< Offset: 0x0E8 (R/W) Function Register 12 */
uint32_t RESERVED26[1U];
__IOM uint32_t COMP13; /*!< Offset: 0x0F0 (R/W) Comparator Register 13 */
uint32_t RESERVED27[1U];
__IOM uint32_t FUNCTION13; /*!< Offset: 0x0F8 (R/W) Function Register 13 */
uint32_t RESERVED28[1U];
__IOM uint32_t COMP14; /*!< Offset: 0x100 (R/W) Comparator Register 14 */
uint32_t RESERVED29[1U];
__IOM uint32_t FUNCTION14; /*!< Offset: 0x108 (R/W) Function Register 14 */
uint32_t RESERVED30[1U];
__IOM uint32_t COMP15; /*!< Offset: 0x110 (R/W) Comparator Register 15 */
uint32_t RESERVED31[1U];
__IOM uint32_t FUNCTION15; /*!< Offset: 0x118 (R/W) Function Register 15 */
uint32_t RESERVED32[934U];
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R ) Lock Status Register */
uint32_t RESERVED33[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) Device Architecture Register */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCDISS_Pos 23U /*!< DWT CTRL: CYCDISS Position */
#define DWT_CTRL_CYCDISS_Msk (0x1UL << DWT_CTRL_CYCDISS_Pos) /*!< DWT CTRL: CYCDISS Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_ID_Pos 27U /*!< DWT FUNCTION: ID Position */
#define DWT_FUNCTION_ID_Msk (0x1FUL << DWT_FUNCTION_ID_Pos) /*!< DWT FUNCTION: ID Mask */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_ACTION_Pos 4U /*!< DWT FUNCTION: ACTION Position */
#define DWT_FUNCTION_ACTION_Msk (0x1UL << DWT_FUNCTION_ACTION_Pos) /*!< DWT FUNCTION: ACTION Mask */
#define DWT_FUNCTION_MATCH_Pos 0U /*!< DWT FUNCTION: MATCH Position */
#define DWT_FUNCTION_MATCH_Msk (0xFUL /*<< DWT_FUNCTION_MATCH_Pos*/) /*!< DWT FUNCTION: MATCH Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Size Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Size Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IOM uint32_t PSCR; /*!< Offset: 0x308 (R/W) Periodic Synchronization Control Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER Register */
__IM uint32_t ITFTTD0; /*!< Offset: 0xEEC (R/ ) Integration Test FIFO Test Data 0 Register */
__IOM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/W) Integration Test ATB Control Register 2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) Integration Test ATB Control Register 0 */
__IM uint32_t ITFTTD1; /*!< Offset: 0xEFC (R/ ) Integration Test FIFO Test Data 1 Register */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) Device Configuration Register */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) Device Type Identifier Register */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_FOnMan_Pos 6U /*!< TPI FFCR: FOnMan Position */
#define TPI_FFCR_FOnMan_Msk (0x1UL << TPI_FFCR_FOnMan_Pos) /*!< TPI FFCR: FOnMan Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration Test FIFO Test Data 0 Register Definitions */
#define TPI_ITFTTD0_ATB_IF2_ATVALID_Pos 29U /*!< TPI ITFTTD0: ATB Interface 2 ATVALIDPosition */
#define TPI_ITFTTD0_ATB_IF2_ATVALID_Msk (0x3UL << TPI_ITFTTD0_ATB_IF2_ATVALID_Pos) /*!< TPI ITFTTD0: ATB Interface 2 ATVALID Mask */
#define TPI_ITFTTD0_ATB_IF2_bytecount_Pos 27U /*!< TPI ITFTTD0: ATB Interface 2 byte count Position */
#define TPI_ITFTTD0_ATB_IF2_bytecount_Msk (0x3UL << TPI_ITFTTD0_ATB_IF2_bytecount_Pos) /*!< TPI ITFTTD0: ATB Interface 2 byte count Mask */
#define TPI_ITFTTD0_ATB_IF1_ATVALID_Pos 26U /*!< TPI ITFTTD0: ATB Interface 1 ATVALID Position */
#define TPI_ITFTTD0_ATB_IF1_ATVALID_Msk (0x3UL << TPI_ITFTTD0_ATB_IF1_ATVALID_Pos) /*!< TPI ITFTTD0: ATB Interface 1 ATVALID Mask */
#define TPI_ITFTTD0_ATB_IF1_bytecount_Pos 24U /*!< TPI ITFTTD0: ATB Interface 1 byte count Position */
#define TPI_ITFTTD0_ATB_IF1_bytecount_Msk (0x3UL << TPI_ITFTTD0_ATB_IF1_bytecount_Pos) /*!< TPI ITFTTD0: ATB Interface 1 byte countt Mask */
#define TPI_ITFTTD0_ATB_IF1_data2_Pos 16U /*!< TPI ITFTTD0: ATB Interface 1 data2 Position */
#define TPI_ITFTTD0_ATB_IF1_data2_Msk (0xFFUL << TPI_ITFTTD0_ATB_IF1_data1_Pos) /*!< TPI ITFTTD0: ATB Interface 1 data2 Mask */
#define TPI_ITFTTD0_ATB_IF1_data1_Pos 8U /*!< TPI ITFTTD0: ATB Interface 1 data1 Position */
#define TPI_ITFTTD0_ATB_IF1_data1_Msk (0xFFUL << TPI_ITFTTD0_ATB_IF1_data1_Pos) /*!< TPI ITFTTD0: ATB Interface 1 data1 Mask */
#define TPI_ITFTTD0_ATB_IF1_data0_Pos 0U /*!< TPI ITFTTD0: ATB Interface 1 data0 Position */
#define TPI_ITFTTD0_ATB_IF1_data0_Msk (0xFFUL /*<< TPI_ITFTTD0_ATB_IF1_data0_Pos*/) /*!< TPI ITFTTD0: ATB Interface 1 data0 Mask */
/* TPI Integration Test ATB Control Register 2 Register Definitions */
#define TPI_ITATBCTR2_AFVALID2S_Pos 1U /*!< TPI ITATBCTR2: AFVALID2S Position */
#define TPI_ITATBCTR2_AFVALID2S_Msk (0x1UL << TPI_ITATBCTR2_AFVALID2S_Pos) /*!< TPI ITATBCTR2: AFVALID2SS Mask */
#define TPI_ITATBCTR2_AFVALID1S_Pos 1U /*!< TPI ITATBCTR2: AFVALID1S Position */
#define TPI_ITATBCTR2_AFVALID1S_Msk (0x1UL << TPI_ITATBCTR2_AFVALID1S_Pos) /*!< TPI ITATBCTR2: AFVALID1SS Mask */
#define TPI_ITATBCTR2_ATREADY2S_Pos 0U /*!< TPI ITATBCTR2: ATREADY2S Position */
#define TPI_ITATBCTR2_ATREADY2S_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY2S_Pos*/) /*!< TPI ITATBCTR2: ATREADY2S Mask */
#define TPI_ITATBCTR2_ATREADY1S_Pos 0U /*!< TPI ITATBCTR2: ATREADY1S Position */
#define TPI_ITATBCTR2_ATREADY1S_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY1S_Pos*/) /*!< TPI ITATBCTR2: ATREADY1S Mask */
/* TPI Integration Test FIFO Test Data 1 Register Definitions */
#define TPI_ITFTTD1_ATB_IF2_ATVALID_Pos 29U /*!< TPI ITFTTD1: ATB Interface 2 ATVALID Position */
#define TPI_ITFTTD1_ATB_IF2_ATVALID_Msk (0x3UL << TPI_ITFTTD1_ATB_IF2_ATVALID_Pos) /*!< TPI ITFTTD1: ATB Interface 2 ATVALID Mask */
#define TPI_ITFTTD1_ATB_IF2_bytecount_Pos 27U /*!< TPI ITFTTD1: ATB Interface 2 byte count Position */
#define TPI_ITFTTD1_ATB_IF2_bytecount_Msk (0x3UL << TPI_ITFTTD1_ATB_IF2_bytecount_Pos) /*!< TPI ITFTTD1: ATB Interface 2 byte count Mask */
#define TPI_ITFTTD1_ATB_IF1_ATVALID_Pos 26U /*!< TPI ITFTTD1: ATB Interface 1 ATVALID Position */
#define TPI_ITFTTD1_ATB_IF1_ATVALID_Msk (0x3UL << TPI_ITFTTD1_ATB_IF1_ATVALID_Pos) /*!< TPI ITFTTD1: ATB Interface 1 ATVALID Mask */
#define TPI_ITFTTD1_ATB_IF1_bytecount_Pos 24U /*!< TPI ITFTTD1: ATB Interface 1 byte count Position */
#define TPI_ITFTTD1_ATB_IF1_bytecount_Msk (0x3UL << TPI_ITFTTD1_ATB_IF1_bytecount_Pos) /*!< TPI ITFTTD1: ATB Interface 1 byte countt Mask */
#define TPI_ITFTTD1_ATB_IF2_data2_Pos 16U /*!< TPI ITFTTD1: ATB Interface 2 data2 Position */
#define TPI_ITFTTD1_ATB_IF2_data2_Msk (0xFFUL << TPI_ITFTTD1_ATB_IF2_data1_Pos) /*!< TPI ITFTTD1: ATB Interface 2 data2 Mask */
#define TPI_ITFTTD1_ATB_IF2_data1_Pos 8U /*!< TPI ITFTTD1: ATB Interface 2 data1 Position */
#define TPI_ITFTTD1_ATB_IF2_data1_Msk (0xFFUL << TPI_ITFTTD1_ATB_IF2_data1_Pos) /*!< TPI ITFTTD1: ATB Interface 2 data1 Mask */
#define TPI_ITFTTD1_ATB_IF2_data0_Pos 0U /*!< TPI ITFTTD1: ATB Interface 2 data0 Position */
#define TPI_ITFTTD1_ATB_IF2_data0_Msk (0xFFUL /*<< TPI_ITFTTD1_ATB_IF2_data0_Pos*/) /*!< TPI ITFTTD1: ATB Interface 2 data0 Mask */
/* TPI Integration Test ATB Control Register 0 Definitions */
#define TPI_ITATBCTR0_AFVALID2S_Pos 1U /*!< TPI ITATBCTR0: AFVALID2S Position */
#define TPI_ITATBCTR0_AFVALID2S_Msk (0x1UL << TPI_ITATBCTR0_AFVALID2S_Pos) /*!< TPI ITATBCTR0: AFVALID2SS Mask */
#define TPI_ITATBCTR0_AFVALID1S_Pos 1U /*!< TPI ITATBCTR0: AFVALID1S Position */
#define TPI_ITATBCTR0_AFVALID1S_Msk (0x1UL << TPI_ITATBCTR0_AFVALID1S_Pos) /*!< TPI ITATBCTR0: AFVALID1SS Mask */
#define TPI_ITATBCTR0_ATREADY2S_Pos 0U /*!< TPI ITATBCTR0: ATREADY2S Position */
#define TPI_ITATBCTR0_ATREADY2S_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY2S_Pos*/) /*!< TPI ITATBCTR0: ATREADY2S Mask */
#define TPI_ITATBCTR0_ATREADY1S_Pos 0U /*!< TPI ITATBCTR0: ATREADY1S Position */
#define TPI_ITATBCTR0_ATREADY1S_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY1S_Pos*/) /*!< TPI ITATBCTR0: ATREADY1S Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x3UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_FIFOSZ_Pos 6U /*!< TPI DEVID: FIFOSZ Position */
#define TPI_DEVID_FIFOSZ_Msk (0x7UL << TPI_DEVID_FIFOSZ_Pos) /*!< TPI DEVID: FIFOSZ Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x3FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) MPU Region Limit Address Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Region Base Address Register Alias 1 */
__IOM uint32_t RLAR_A1; /*!< Offset: 0x018 (R/W) MPU Region Limit Address Register Alias 1 */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Region Base Address Register Alias 2 */
__IOM uint32_t RLAR_A2; /*!< Offset: 0x020 (R/W) MPU Region Limit Address Register Alias 2 */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Region Base Address Register Alias 3 */
__IOM uint32_t RLAR_A3; /*!< Offset: 0x028 (R/W) MPU Region Limit Address Register Alias 3 */
uint32_t RESERVED0[1];
union {
__IOM uint32_t MAIR[2];
struct {
__IOM uint32_t MAIR0; /*!< Offset: 0x030 (R/W) MPU Memory Attribute Indirection Register 0 */
__IOM uint32_t MAIR1; /*!< Offset: 0x034 (R/W) MPU Memory Attribute Indirection Register 1 */
};
};
} MPU_Type;
#define MPU_TYPE_RALIASES 4U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_BASE_Pos 5U /*!< MPU RBAR: BASE Position */
#define MPU_RBAR_BASE_Msk (0x7FFFFFFUL << MPU_RBAR_BASE_Pos) /*!< MPU RBAR: BASE Mask */
#define MPU_RBAR_SH_Pos 3U /*!< MPU RBAR: SH Position */
#define MPU_RBAR_SH_Msk (0x3UL << MPU_RBAR_SH_Pos) /*!< MPU RBAR: SH Mask */
#define MPU_RBAR_AP_Pos 1U /*!< MPU RBAR: AP Position */
#define MPU_RBAR_AP_Msk (0x3UL << MPU_RBAR_AP_Pos) /*!< MPU RBAR: AP Mask */
#define MPU_RBAR_XN_Pos 0U /*!< MPU RBAR: XN Position */
#define MPU_RBAR_XN_Msk (01UL /*<< MPU_RBAR_XN_Pos*/) /*!< MPU RBAR: XN Mask */
/* MPU Region Limit Address Register Definitions */
#define MPU_RLAR_LIMIT_Pos 5U /*!< MPU RLAR: LIMIT Position */
#define MPU_RLAR_LIMIT_Msk (0x7FFFFFFUL << MPU_RLAR_LIMIT_Pos) /*!< MPU RLAR: LIMIT Mask */
#define MPU_RLAR_AttrIndx_Pos 1U /*!< MPU RLAR: AttrIndx Position */
#define MPU_RLAR_AttrIndx_Msk (0x7UL << MPU_RLAR_AttrIndx_Pos) /*!< MPU RLAR: AttrIndx Mask */
#define MPU_RLAR_EN_Pos 0U /*!< MPU RLAR: Region enable bit Position */
#define MPU_RLAR_EN_Msk (1UL /*<< MPU_RLAR_EN_Pos*/) /*!< MPU RLAR: Region enable bit Disable Mask */
/* MPU Memory Attribute Indirection Register 0 Definitions */
#define MPU_MAIR0_Attr3_Pos 24U /*!< MPU MAIR0: Attr3 Position */
#define MPU_MAIR0_Attr3_Msk (0xFFUL << MPU_MAIR0_Attr3_Pos) /*!< MPU MAIR0: Attr3 Mask */
#define MPU_MAIR0_Attr2_Pos 16U /*!< MPU MAIR0: Attr2 Position */
#define MPU_MAIR0_Attr2_Msk (0xFFUL << MPU_MAIR0_Attr2_Pos) /*!< MPU MAIR0: Attr2 Mask */
#define MPU_MAIR0_Attr1_Pos 8U /*!< MPU MAIR0: Attr1 Position */
#define MPU_MAIR0_Attr1_Msk (0xFFUL << MPU_MAIR0_Attr1_Pos) /*!< MPU MAIR0: Attr1 Mask */
#define MPU_MAIR0_Attr0_Pos 0U /*!< MPU MAIR0: Attr0 Position */
#define MPU_MAIR0_Attr0_Msk (0xFFUL /*<< MPU_MAIR0_Attr0_Pos*/) /*!< MPU MAIR0: Attr0 Mask */
/* MPU Memory Attribute Indirection Register 1 Definitions */
#define MPU_MAIR1_Attr7_Pos 24U /*!< MPU MAIR1: Attr7 Position */
#define MPU_MAIR1_Attr7_Msk (0xFFUL << MPU_MAIR1_Attr7_Pos) /*!< MPU MAIR1: Attr7 Mask */
#define MPU_MAIR1_Attr6_Pos 16U /*!< MPU MAIR1: Attr6 Position */
#define MPU_MAIR1_Attr6_Msk (0xFFUL << MPU_MAIR1_Attr6_Pos) /*!< MPU MAIR1: Attr6 Mask */
#define MPU_MAIR1_Attr5_Pos 8U /*!< MPU MAIR1: Attr5 Position */
#define MPU_MAIR1_Attr5_Msk (0xFFUL << MPU_MAIR1_Attr5_Pos) /*!< MPU MAIR1: Attr5 Mask */
#define MPU_MAIR1_Attr4_Pos 0U /*!< MPU MAIR1: Attr4 Position */
#define MPU_MAIR1_Attr4_Msk (0xFFUL /*<< MPU_MAIR1_Attr4_Pos*/) /*!< MPU MAIR1: Attr4 Mask */
/*@} end of group CMSIS_MPU */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SAU Security Attribution Unit (SAU)
\brief Type definitions for the Security Attribution Unit (SAU)
@{
*/
/**
\brief Structure type to access the Security Attribution Unit (SAU).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SAU Control Register */
__IM uint32_t TYPE; /*!< Offset: 0x004 (R/ ) SAU Type Register */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) SAU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) SAU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) SAU Region Limit Address Register */
#else
uint32_t RESERVED0[3];
#endif
__IOM uint32_t SFSR; /*!< Offset: 0x014 (R/W) Secure Fault Status Register */
__IOM uint32_t SFAR; /*!< Offset: 0x018 (R/W) Secure Fault Address Register */
} SAU_Type;
/* SAU Control Register Definitions */
#define SAU_CTRL_ALLNS_Pos 1U /*!< SAU CTRL: ALLNS Position */
#define SAU_CTRL_ALLNS_Msk (1UL << SAU_CTRL_ALLNS_Pos) /*!< SAU CTRL: ALLNS Mask */
#define SAU_CTRL_ENABLE_Pos 0U /*!< SAU CTRL: ENABLE Position */
#define SAU_CTRL_ENABLE_Msk (1UL /*<< SAU_CTRL_ENABLE_Pos*/) /*!< SAU CTRL: ENABLE Mask */
/* SAU Type Register Definitions */
#define SAU_TYPE_SREGION_Pos 0U /*!< SAU TYPE: SREGION Position */
#define SAU_TYPE_SREGION_Msk (0xFFUL /*<< SAU_TYPE_SREGION_Pos*/) /*!< SAU TYPE: SREGION Mask */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
/* SAU Region Number Register Definitions */
#define SAU_RNR_REGION_Pos 0U /*!< SAU RNR: REGION Position */
#define SAU_RNR_REGION_Msk (0xFFUL /*<< SAU_RNR_REGION_Pos*/) /*!< SAU RNR: REGION Mask */
/* SAU Region Base Address Register Definitions */
#define SAU_RBAR_BADDR_Pos 5U /*!< SAU RBAR: BADDR Position */
#define SAU_RBAR_BADDR_Msk (0x7FFFFFFUL << SAU_RBAR_BADDR_Pos) /*!< SAU RBAR: BADDR Mask */
/* SAU Region Limit Address Register Definitions */
#define SAU_RLAR_LADDR_Pos 5U /*!< SAU RLAR: LADDR Position */
#define SAU_RLAR_LADDR_Msk (0x7FFFFFFUL << SAU_RLAR_LADDR_Pos) /*!< SAU RLAR: LADDR Mask */
#define SAU_RLAR_NSC_Pos 1U /*!< SAU RLAR: NSC Position */
#define SAU_RLAR_NSC_Msk (1UL << SAU_RLAR_NSC_Pos) /*!< SAU RLAR: NSC Mask */
#define SAU_RLAR_ENABLE_Pos 0U /*!< SAU RLAR: ENABLE Position */
#define SAU_RLAR_ENABLE_Msk (1UL /*<< SAU_RLAR_ENABLE_Pos*/) /*!< SAU RLAR: ENABLE Mask */
#endif /* defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U) */
/* Secure Fault Status Register Definitions */
#define SAU_SFSR_LSERR_Pos 7U /*!< SAU SFSR: LSERR Position */
#define SAU_SFSR_LSERR_Msk (1UL << SAU_SFSR_LSERR_Pos) /*!< SAU SFSR: LSERR Mask */
#define SAU_SFSR_SFARVALID_Pos 6U /*!< SAU SFSR: SFARVALID Position */
#define SAU_SFSR_SFARVALID_Msk (1UL << SAU_SFSR_SFARVALID_Pos) /*!< SAU SFSR: SFARVALID Mask */
#define SAU_SFSR_LSPERR_Pos 5U /*!< SAU SFSR: LSPERR Position */
#define SAU_SFSR_LSPERR_Msk (1UL << SAU_SFSR_LSPERR_Pos) /*!< SAU SFSR: LSPERR Mask */
#define SAU_SFSR_INVTRAN_Pos 4U /*!< SAU SFSR: INVTRAN Position */
#define SAU_SFSR_INVTRAN_Msk (1UL << SAU_SFSR_INVTRAN_Pos) /*!< SAU SFSR: INVTRAN Mask */
#define SAU_SFSR_AUVIOL_Pos 3U /*!< SAU SFSR: AUVIOL Position */
#define SAU_SFSR_AUVIOL_Msk (1UL << SAU_SFSR_AUVIOL_Pos) /*!< SAU SFSR: AUVIOL Mask */
#define SAU_SFSR_INVER_Pos 2U /*!< SAU SFSR: INVER Position */
#define SAU_SFSR_INVER_Msk (1UL << SAU_SFSR_INVER_Pos) /*!< SAU SFSR: INVER Mask */
#define SAU_SFSR_INVIS_Pos 1U /*!< SAU SFSR: INVIS Position */
#define SAU_SFSR_INVIS_Msk (1UL << SAU_SFSR_INVIS_Pos) /*!< SAU SFSR: INVIS Mask */
#define SAU_SFSR_INVEP_Pos 0U /*!< SAU SFSR: INVEP Position */
#define SAU_SFSR_INVEP_Msk (1UL /*<< SAU_SFSR_INVEP_Pos*/) /*!< SAU SFSR: INVEP Mask */
/*@} end of group CMSIS_SAU */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_FPU Floating Point Unit (FPU)
\brief Type definitions for the Floating Point Unit (FPU)
@{
*/
/**
\brief Structure type to access the Floating Point Unit (FPU).
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IOM uint32_t FPCCR; /*!< Offset: 0x004 (R/W) Floating-Point Context Control Register */
__IOM uint32_t FPCAR; /*!< Offset: 0x008 (R/W) Floating-Point Context Address Register */
__IOM uint32_t FPDSCR; /*!< Offset: 0x00C (R/W) Floating-Point Default Status Control Register */
__IM uint32_t MVFR0; /*!< Offset: 0x010 (R/ ) Media and FP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x014 (R/ ) Media and FP Feature Register 1 */
} FPU_Type;
/* Floating-Point Context Control Register Definitions */
#define FPU_FPCCR_ASPEN_Pos 31U /*!< FPCCR: ASPEN bit Position */
#define FPU_FPCCR_ASPEN_Msk (1UL << FPU_FPCCR_ASPEN_Pos) /*!< FPCCR: ASPEN bit Mask */
#define FPU_FPCCR_LSPEN_Pos 30U /*!< FPCCR: LSPEN Position */
#define FPU_FPCCR_LSPEN_Msk (1UL << FPU_FPCCR_LSPEN_Pos) /*!< FPCCR: LSPEN bit Mask */
#define FPU_FPCCR_LSPENS_Pos 29U /*!< FPCCR: LSPENS Position */
#define FPU_FPCCR_LSPENS_Msk (1UL << FPU_FPCCR_LSPENS_Pos) /*!< FPCCR: LSPENS bit Mask */
#define FPU_FPCCR_CLRONRET_Pos 28U /*!< FPCCR: CLRONRET Position */
#define FPU_FPCCR_CLRONRET_Msk (1UL << FPU_FPCCR_CLRONRET_Pos) /*!< FPCCR: CLRONRET bit Mask */
#define FPU_FPCCR_CLRONRETS_Pos 27U /*!< FPCCR: CLRONRETS Position */
#define FPU_FPCCR_CLRONRETS_Msk (1UL << FPU_FPCCR_CLRONRETS_Pos) /*!< FPCCR: CLRONRETS bit Mask */
#define FPU_FPCCR_TS_Pos 26U /*!< FPCCR: TS Position */
#define FPU_FPCCR_TS_Msk (1UL << FPU_FPCCR_TS_Pos) /*!< FPCCR: TS bit Mask */
#define FPU_FPCCR_UFRDY_Pos 10U /*!< FPCCR: UFRDY Position */
#define FPU_FPCCR_UFRDY_Msk (1UL << FPU_FPCCR_UFRDY_Pos) /*!< FPCCR: UFRDY bit Mask */
#define FPU_FPCCR_SPLIMVIOL_Pos 9U /*!< FPCCR: SPLIMVIOL Position */
#define FPU_FPCCR_SPLIMVIOL_Msk (1UL << FPU_FPCCR_SPLIMVIOL_Pos) /*!< FPCCR: SPLIMVIOL bit Mask */
#define FPU_FPCCR_MONRDY_Pos 8U /*!< FPCCR: MONRDY Position */
#define FPU_FPCCR_MONRDY_Msk (1UL << FPU_FPCCR_MONRDY_Pos) /*!< FPCCR: MONRDY bit Mask */
#define FPU_FPCCR_SFRDY_Pos 7U /*!< FPCCR: SFRDY Position */
#define FPU_FPCCR_SFRDY_Msk (1UL << FPU_FPCCR_SFRDY_Pos) /*!< FPCCR: SFRDY bit Mask */
#define FPU_FPCCR_BFRDY_Pos 6U /*!< FPCCR: BFRDY Position */
#define FPU_FPCCR_BFRDY_Msk (1UL << FPU_FPCCR_BFRDY_Pos) /*!< FPCCR: BFRDY bit Mask */
#define FPU_FPCCR_MMRDY_Pos 5U /*!< FPCCR: MMRDY Position */
#define FPU_FPCCR_MMRDY_Msk (1UL << FPU_FPCCR_MMRDY_Pos) /*!< FPCCR: MMRDY bit Mask */
#define FPU_FPCCR_HFRDY_Pos 4U /*!< FPCCR: HFRDY Position */
#define FPU_FPCCR_HFRDY_Msk (1UL << FPU_FPCCR_HFRDY_Pos) /*!< FPCCR: HFRDY bit Mask */
#define FPU_FPCCR_THREAD_Pos 3U /*!< FPCCR: processor mode bit Position */
#define FPU_FPCCR_THREAD_Msk (1UL << FPU_FPCCR_THREAD_Pos) /*!< FPCCR: processor mode active bit Mask */
#define FPU_FPCCR_S_Pos 2U /*!< FPCCR: Security status of the FP context bit Position */
#define FPU_FPCCR_S_Msk (1UL << FPU_FPCCR_S_Pos) /*!< FPCCR: Security status of the FP context bit Mask */
#define FPU_FPCCR_USER_Pos 1U /*!< FPCCR: privilege level bit Position */
#define FPU_FPCCR_USER_Msk (1UL << FPU_FPCCR_USER_Pos) /*!< FPCCR: privilege level bit Mask */
#define FPU_FPCCR_LSPACT_Pos 0U /*!< FPCCR: Lazy state preservation active bit Position */
#define FPU_FPCCR_LSPACT_Msk (1UL /*<< FPU_FPCCR_LSPACT_Pos*/) /*!< FPCCR: Lazy state preservation active bit Mask */
/* Floating-Point Context Address Register Definitions */
#define FPU_FPCAR_ADDRESS_Pos 3U /*!< FPCAR: ADDRESS bit Position */
#define FPU_FPCAR_ADDRESS_Msk (0x1FFFFFFFUL << FPU_FPCAR_ADDRESS_Pos) /*!< FPCAR: ADDRESS bit Mask */
/* Floating-Point Default Status Control Register Definitions */
#define FPU_FPDSCR_AHP_Pos 26U /*!< FPDSCR: AHP bit Position */
#define FPU_FPDSCR_AHP_Msk (1UL << FPU_FPDSCR_AHP_Pos) /*!< FPDSCR: AHP bit Mask */
#define FPU_FPDSCR_DN_Pos 25U /*!< FPDSCR: DN bit Position */
#define FPU_FPDSCR_DN_Msk (1UL << FPU_FPDSCR_DN_Pos) /*!< FPDSCR: DN bit Mask */
#define FPU_FPDSCR_FZ_Pos 24U /*!< FPDSCR: FZ bit Position */
#define FPU_FPDSCR_FZ_Msk (1UL << FPU_FPDSCR_FZ_Pos) /*!< FPDSCR: FZ bit Mask */
#define FPU_FPDSCR_RMode_Pos 22U /*!< FPDSCR: RMode bit Position */
#define FPU_FPDSCR_RMode_Msk (3UL << FPU_FPDSCR_RMode_Pos) /*!< FPDSCR: RMode bit Mask */
/* Media and FP Feature Register 0 Definitions */
#define FPU_MVFR0_FP_rounding_modes_Pos 28U /*!< MVFR0: FP rounding modes bits Position */
#define FPU_MVFR0_FP_rounding_modes_Msk (0xFUL << FPU_MVFR0_FP_rounding_modes_Pos) /*!< MVFR0: FP rounding modes bits Mask */
#define FPU_MVFR0_Short_vectors_Pos 24U /*!< MVFR0: Short vectors bits Position */
#define FPU_MVFR0_Short_vectors_Msk (0xFUL << FPU_MVFR0_Short_vectors_Pos) /*!< MVFR0: Short vectors bits Mask */
#define FPU_MVFR0_Square_root_Pos 20U /*!< MVFR0: Square root bits Position */
#define FPU_MVFR0_Square_root_Msk (0xFUL << FPU_MVFR0_Square_root_Pos) /*!< MVFR0: Square root bits Mask */
#define FPU_MVFR0_Divide_Pos 16U /*!< MVFR0: Divide bits Position */
#define FPU_MVFR0_Divide_Msk (0xFUL << FPU_MVFR0_Divide_Pos) /*!< MVFR0: Divide bits Mask */
#define FPU_MVFR0_FP_excep_trapping_Pos 12U /*!< MVFR0: FP exception trapping bits Position */
#define FPU_MVFR0_FP_excep_trapping_Msk (0xFUL << FPU_MVFR0_FP_excep_trapping_Pos) /*!< MVFR0: FP exception trapping bits Mask */
#define FPU_MVFR0_Double_precision_Pos 8U /*!< MVFR0: Double-precision bits Position */
#define FPU_MVFR0_Double_precision_Msk (0xFUL << FPU_MVFR0_Double_precision_Pos) /*!< MVFR0: Double-precision bits Mask */
#define FPU_MVFR0_Single_precision_Pos 4U /*!< MVFR0: Single-precision bits Position */
#define FPU_MVFR0_Single_precision_Msk (0xFUL << FPU_MVFR0_Single_precision_Pos) /*!< MVFR0: Single-precision bits Mask */
#define FPU_MVFR0_A_SIMD_registers_Pos 0U /*!< MVFR0: A_SIMD registers bits Position */
#define FPU_MVFR0_A_SIMD_registers_Msk (0xFUL /*<< FPU_MVFR0_A_SIMD_registers_Pos*/) /*!< MVFR0: A_SIMD registers bits Mask */
/* Media and FP Feature Register 1 Definitions */
#define FPU_MVFR1_FP_fused_MAC_Pos 28U /*!< MVFR1: FP fused MAC bits Position */
#define FPU_MVFR1_FP_fused_MAC_Msk (0xFUL << FPU_MVFR1_FP_fused_MAC_Pos) /*!< MVFR1: FP fused MAC bits Mask */
#define FPU_MVFR1_FP_HPFP_Pos 24U /*!< MVFR1: FP HPFP bits Position */
#define FPU_MVFR1_FP_HPFP_Msk (0xFUL << FPU_MVFR1_FP_HPFP_Pos) /*!< MVFR1: FP HPFP bits Mask */
#define FPU_MVFR1_D_NaN_mode_Pos 4U /*!< MVFR1: D_NaN mode bits Position */
#define FPU_MVFR1_D_NaN_mode_Msk (0xFUL << FPU_MVFR1_D_NaN_mode_Pos) /*!< MVFR1: D_NaN mode bits Mask */
#define FPU_MVFR1_FtZ_mode_Pos 0U /*!< MVFR1: FtZ mode bits Position */
#define FPU_MVFR1_FtZ_mode_Msk (0xFUL /*<< FPU_MVFR1_FtZ_mode_Pos*/) /*!< MVFR1: FtZ mode bits Mask */
/*@} end of group CMSIS_FPU */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
uint32_t RESERVED4[1U];
__IOM uint32_t DAUTHCTRL; /*!< Offset: 0x014 (R/W) Debug Authentication Control Register */
__IOM uint32_t DSCSR; /*!< Offset: 0x018 (R/W) Debug Security Control and Status Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESTART_ST_Pos 26U /*!< CoreDebug DHCSR: S_RESTART_ST Position */
#define CoreDebug_DHCSR_S_RESTART_ST_Msk (1UL << CoreDebug_DHCSR_S_RESTART_ST_Pos) /*!< CoreDebug DHCSR: S_RESTART_ST Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/* Debug Authentication Control Register Definitions */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos 3U /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Position */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Mask */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos 2U /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Msk (1UL << CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos) /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Mask */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Pos 1U /*!< CoreDebug DAUTHCTRL: INTSPIDEN Position */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPIDEN Mask */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Pos 0U /*!< CoreDebug DAUTHCTRL: SPIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Msk (1UL /*<< CoreDebug_DAUTHCTRL_SPIDENSEL_Pos*/) /*!< CoreDebug DAUTHCTRL: SPIDENSEL Mask */
/* Debug Security Control and Status Register Definitions */
#define CoreDebug_DSCSR_CDS_Pos 16U /*!< CoreDebug DSCSR: CDS Position */
#define CoreDebug_DSCSR_CDS_Msk (1UL << CoreDebug_DSCSR_CDS_Pos) /*!< CoreDebug DSCSR: CDS Mask */
#define CoreDebug_DSCSR_SBRSEL_Pos 1U /*!< CoreDebug DSCSR: SBRSEL Position */
#define CoreDebug_DSCSR_SBRSEL_Msk (1UL << CoreDebug_DSCSR_SBRSEL_Pos) /*!< CoreDebug DSCSR: SBRSEL Mask */
#define CoreDebug_DSCSR_SBRSELEN_Pos 0U /*!< CoreDebug DSCSR: SBRSELEN Position */
#define CoreDebug_DSCSR_SBRSELEN_Msk (1UL /*<< CoreDebug_DSCSR_SBRSELEN_Pos*/) /*!< CoreDebug DSCSR: SBRSELEN Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE ) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SAU_BASE (SCS_BASE + 0x0DD0UL) /*!< Security Attribution Unit */
#define SAU ((SAU_Type *) SAU_BASE ) /*!< Security Attribution Unit */
#endif
#define FPU_BASE (SCS_BASE + 0x0F30UL) /*!< Floating Point Unit */
#define FPU ((FPU_Type *) FPU_BASE ) /*!< Floating Point Unit */
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SCS_BASE_NS (0xE002E000UL) /*!< System Control Space Base Address (non-secure address space) */
#define CoreDebug_BASE_NS (0xE002EDF0UL) /*!< Core Debug Base Address (non-secure address space) */
#define SysTick_BASE_NS (SCS_BASE_NS + 0x0010UL) /*!< SysTick Base Address (non-secure address space) */
#define NVIC_BASE_NS (SCS_BASE_NS + 0x0100UL) /*!< NVIC Base Address (non-secure address space) */
#define SCB_BASE_NS (SCS_BASE_NS + 0x0D00UL) /*!< System Control Block Base Address (non-secure address space) */
#define SCnSCB_NS ((SCnSCB_Type *) SCS_BASE_NS ) /*!< System control Register not in SCB(non-secure address space) */
#define SCB_NS ((SCB_Type *) SCB_BASE_NS ) /*!< SCB configuration struct (non-secure address space) */
#define SysTick_NS ((SysTick_Type *) SysTick_BASE_NS ) /*!< SysTick configuration struct (non-secure address space) */
#define NVIC_NS ((NVIC_Type *) NVIC_BASE_NS ) /*!< NVIC configuration struct (non-secure address space) */
#define CoreDebug_NS ((CoreDebug_Type *) CoreDebug_BASE_NS) /*!< Core Debug configuration struct (non-secure address space) */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE_NS (SCS_BASE_NS + 0x0D90UL) /*!< Memory Protection Unit (non-secure address space) */
#define MPU_NS ((MPU_Type *) MPU_BASE_NS ) /*!< Memory Protection Unit (non-secure address space) */
#endif
#define FPU_BASE_NS (SCS_BASE_NS + 0x0F30UL) /*!< Floating Point Unit (non-secure address space) */
#define FPU_NS ((FPU_Type *) FPU_BASE_NS ) /*!< Floating Point Unit (non-secure address space) */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* Special LR values for Secure/Non-Secure call handling and exception handling */
/* Function Return Payload (from ARMv8-M Architecture Reference Manual) LR value on entry from Secure BLXNS */
#define FNC_RETURN (0xFEFFFFFFUL) /* bit [0] ignored when processing a branch */
/* The following EXC_RETURN mask values are used to evaluate the LR on exception entry */
#define EXC_RETURN_PREFIX (0xFF000000UL) /* bits [31:24] set to indicate an EXC_RETURN value */
#define EXC_RETURN_S (0x00000040UL) /* bit [6] stack used to push registers: 0=Non-secure 1=Secure */
#define EXC_RETURN_DCRS (0x00000020UL) /* bit [5] stacking rules for called registers: 0=skipped 1=saved */
#define EXC_RETURN_FTYPE (0x00000010UL) /* bit [4] allocate stack for floating-point context: 0=done 1=skipped */
#define EXC_RETURN_MODE (0x00000008UL) /* bit [3] processor mode for return: 0=Handler mode 1=Thread mode */
#define EXC_RETURN_SPSEL (0x00000004UL) /* bit [2] stack pointer used to restore context: 0=MSP 1=PSP */
#define EXC_RETURN_ES (0x00000001UL) /* bit [0] security state exception was taken to: 0=Non-secure 1=Secure */
/* Integrity Signature (from ARMv8-M Architecture Reference Manual) for exception context stacking */
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U) /* Value for processors with floating-point extension: */
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125AUL) /* bit [0] SFTC must match LR bit[4] EXC_RETURN_FTYPE */
#else
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125BUL) /* Value for processors without floating-point extension */
#endif
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Get Interrupt Target State
\details Reads the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
\return 1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_GetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Target State
\details Sets the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_SetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] |= ((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Clear Interrupt Target State
\details Clears the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_ClearTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] &= ~((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
__DSB();
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Set Priority Grouping (non-secure)
\details Sets the non-secure priority grouping field when in secure state using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void TZ_NVIC_SetPriorityGrouping_NS(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB_NS->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB_NS->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping (non-secure)
\details Reads the priority grouping field from the non-secure NVIC when in secure state.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriorityGrouping_NS(void)
{
return ((uint32_t)((SCB_NS->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt (non-secure)
\details Enables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_EnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Interrupt Enable status (non-secure)
\details Returns a device specific interrupt enable status from the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetEnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt (non-secure)
\details Disables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_DisableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Pending Interrupt (non-secure)
\details Reads the NVIC pending register in the non-secure NVIC when in secure state and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt (non-secure)
\details Sets the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_SetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt (non-secure)
\details Clears the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_ClearPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt (non-secure)
\details Reads the active register in non-secure NVIC when in secure state and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetActive_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority (non-secure)
\details Sets the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every non-secure processor exception.
*/
__STATIC_INLINE void TZ_NVIC_SetPriority_NS(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority (non-secure)
\details Reads the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority. Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriority_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC_NS->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
#endif /* defined (__ARM_FEATURE_CMSE) &&(__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv8.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
uint32_t mvfr0;
mvfr0 = FPU->MVFR0;
if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x220U)
{
return 2U; /* Double + Single precision FPU */
}
else if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x020U)
{
return 1U; /* Single precision FPU */
}
else
{
return 0U; /* No FPU */
}
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ########################## SAU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SAUFunctions SAU Functions
\brief Functions that configure the SAU.
@{
*/
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable SAU
\details Enables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Enable(void)
{
SAU->CTRL |= (SAU_CTRL_ENABLE_Msk);
}
/**
\brief Disable SAU
\details Disables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Disable(void)
{
SAU->CTRL &= ~(SAU_CTRL_ENABLE_Msk);
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_SAUFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief System Tick Configuration (non-secure)
\details Initializes the non-secure System Timer and its interrupt when in secure state, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>TZ_SysTick_Config_NS</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t TZ_SysTick_Config_NS(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick_NS->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
TZ_NVIC_SetPriority_NS (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick_NS->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick_NS->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM35P_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 165,095 | C | 55.714531 | 178 | 0.533069 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm33.h | /**************************************************************************//**
* @file core_cm33.h
* @brief CMSIS Cortex-M33 Core Peripheral Access Layer Header File
* @version V5.1.0
* @date 12. November 2018
******************************************************************************/
/*
* Copyright (c) 2009-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM33_H_GENERIC
#define __CORE_CM33_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M33
@{
*/
#include "cmsis_version.h"
/* CMSIS CM33 definitions */
#define __CM33_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM33_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM33_CMSIS_VERSION ((__CM33_CMSIS_VERSION_MAIN << 16U) | \
__CM33_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (33U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
For this, __FPU_PRESENT has to be checked prior to making use of FPU specific registers and functions.
*/
#if defined ( __CC_ARM )
#if defined (__TARGET_FPU_VFP)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined (__ARM_FP)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#warning "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __ICCARM__ )
#if defined (__ARMVFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1U)
#if defined (__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __TI_ARM__ )
#if defined (__TI_VFP_SUPPORT__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TASKING__ )
#if defined (__FPU_VFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM33_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM33_H_DEPENDANT
#define __CORE_CM33_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM33_REV
#define __CM33_REV 0x0000U
#warning "__CM33_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __SAUREGION_PRESENT
#define __SAUREGION_PRESENT 0U
#warning "__SAUREGION_PRESENT not defined in device header file; using default!"
#endif
#ifndef __DSP_PRESENT
#define __DSP_PRESENT 0U
#warning "__DSP_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M33 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core SAU Register
- Core FPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:16; /*!< bit: 0..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:7; /*!< bit: 20..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
#define APSR_GE_Pos 16U /*!< APSR: GE Position */
#define APSR_GE_Msk (0xFUL << APSR_GE_Pos) /*!< APSR: GE Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:7; /*!< bit: 9..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:4; /*!< bit: 20..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t IT:2; /*!< bit: 25..26 saved IT state (read 0) */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_IT_Pos 25U /*!< xPSR: IT Position */
#define xPSR_IT_Msk (3UL << xPSR_IT_Pos) /*!< xPSR: IT Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_GE_Pos 16U /*!< xPSR: GE Position */
#define xPSR_GE_Msk (0xFUL << xPSR_GE_Pos) /*!< xPSR: GE Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack-pointer select */
uint32_t FPCA:1; /*!< bit: 2 Floating-point context active */
uint32_t SFPA:1; /*!< bit: 3 Secure floating-point active */
uint32_t _reserved1:28; /*!< bit: 4..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SFPA_Pos 3U /*!< CONTROL: SFPA Position */
#define CONTROL_SFPA_Msk (1UL << CONTROL_SFPA_Pos) /*!< CONTROL: SFPA Mask */
#define CONTROL_FPCA_Pos 2U /*!< CONTROL: FPCA Position */
#define CONTROL_FPCA_Msk (1UL << CONTROL_FPCA_Pos) /*!< CONTROL: FPCA Mask */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[16U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[16U];
__IOM uint32_t ICER[16U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[16U];
__IOM uint32_t ISPR[16U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[16U];
__IOM uint32_t ICPR[16U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[16U];
__IOM uint32_t IABR[16U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[16U];
__IOM uint32_t ITNS[16U]; /*!< Offset: 0x280 (R/W) Interrupt Non-Secure State Register */
uint32_t RESERVED5[16U];
__IOM uint8_t IPR[496U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED6[580U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHPR[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t ID_PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t ID_DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ID_ADR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t ID_MMFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ID_ISAR[6U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
__IM uint32_t CLIDR; /*!< Offset: 0x078 (R/ ) Cache Level ID register */
__IM uint32_t CTR; /*!< Offset: 0x07C (R/ ) Cache Type register */
__IM uint32_t CCSIDR; /*!< Offset: 0x080 (R/ ) Cache Size ID Register */
__IOM uint32_t CSSELR; /*!< Offset: 0x084 (R/W) Cache Size Selection Register */
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
__IOM uint32_t NSACR; /*!< Offset: 0x08C (R/W) Non-Secure Access Control Register */
uint32_t RESERVED3[92U];
__OM uint32_t STIR; /*!< Offset: 0x200 ( /W) Software Triggered Interrupt Register */
uint32_t RESERVED4[15U];
__IM uint32_t MVFR0; /*!< Offset: 0x240 (R/ ) Media and VFP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x244 (R/ ) Media and VFP Feature Register 1 */
__IM uint32_t MVFR2; /*!< Offset: 0x248 (R/ ) Media and VFP Feature Register 2 */
uint32_t RESERVED5[1U];
__OM uint32_t ICIALLU; /*!< Offset: 0x250 ( /W) I-Cache Invalidate All to PoU */
uint32_t RESERVED6[1U];
__OM uint32_t ICIMVAU; /*!< Offset: 0x258 ( /W) I-Cache Invalidate by MVA to PoU */
__OM uint32_t DCIMVAC; /*!< Offset: 0x25C ( /W) D-Cache Invalidate by MVA to PoC */
__OM uint32_t DCISW; /*!< Offset: 0x260 ( /W) D-Cache Invalidate by Set-way */
__OM uint32_t DCCMVAU; /*!< Offset: 0x264 ( /W) D-Cache Clean by MVA to PoU */
__OM uint32_t DCCMVAC; /*!< Offset: 0x268 ( /W) D-Cache Clean by MVA to PoC */
__OM uint32_t DCCSW; /*!< Offset: 0x26C ( /W) D-Cache Clean by Set-way */
__OM uint32_t DCCIMVAC; /*!< Offset: 0x270 ( /W) D-Cache Clean and Invalidate by MVA to PoC */
__OM uint32_t DCCISW; /*!< Offset: 0x274 ( /W) D-Cache Clean and Invalidate by Set-way */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_PENDNMISET_Pos 31U /*!< SCB ICSR: PENDNMISET Position */
#define SCB_ICSR_PENDNMISET_Msk (1UL << SCB_ICSR_PENDNMISET_Pos) /*!< SCB ICSR: PENDNMISET Mask */
#define SCB_ICSR_NMIPENDSET_Pos SCB_ICSR_PENDNMISET_Pos /*!< SCB ICSR: NMIPENDSET Position, backward compatibility */
#define SCB_ICSR_NMIPENDSET_Msk SCB_ICSR_PENDNMISET_Msk /*!< SCB ICSR: NMIPENDSET Mask, backward compatibility */
#define SCB_ICSR_PENDNMICLR_Pos 30U /*!< SCB ICSR: PENDNMICLR Position */
#define SCB_ICSR_PENDNMICLR_Msk (1UL << SCB_ICSR_PENDNMICLR_Pos) /*!< SCB ICSR: PENDNMICLR Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_STTNS_Pos 24U /*!< SCB ICSR: STTNS Position (Security Extension) */
#define SCB_ICSR_STTNS_Msk (1UL << SCB_ICSR_STTNS_Pos) /*!< SCB ICSR: STTNS Mask (Security Extension) */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIS_Pos 14U /*!< SCB AIRCR: PRIS Position */
#define SCB_AIRCR_PRIS_Msk (1UL << SCB_AIRCR_PRIS_Pos) /*!< SCB AIRCR: PRIS Mask */
#define SCB_AIRCR_BFHFNMINS_Pos 13U /*!< SCB AIRCR: BFHFNMINS Position */
#define SCB_AIRCR_BFHFNMINS_Msk (1UL << SCB_AIRCR_BFHFNMINS_Pos) /*!< SCB AIRCR: BFHFNMINS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQS_Pos 3U /*!< SCB AIRCR: SYSRESETREQS Position */
#define SCB_AIRCR_SYSRESETREQS_Msk (1UL << SCB_AIRCR_SYSRESETREQS_Pos) /*!< SCB AIRCR: SYSRESETREQS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEPS_Pos 3U /*!< SCB SCR: SLEEPDEEPS Position */
#define SCB_SCR_SLEEPDEEPS_Msk (1UL << SCB_SCR_SLEEPDEEPS_Pos) /*!< SCB SCR: SLEEPDEEPS Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_BP_Pos 18U /*!< SCB CCR: BP Position */
#define SCB_CCR_BP_Msk (1UL << SCB_CCR_BP_Pos) /*!< SCB CCR: BP Mask */
#define SCB_CCR_IC_Pos 17U /*!< SCB CCR: IC Position */
#define SCB_CCR_IC_Msk (1UL << SCB_CCR_IC_Pos) /*!< SCB CCR: IC Mask */
#define SCB_CCR_DC_Pos 16U /*!< SCB CCR: DC Position */
#define SCB_CCR_DC_Msk (1UL << SCB_CCR_DC_Pos) /*!< SCB CCR: DC Mask */
#define SCB_CCR_STKOFHFNMIGN_Pos 10U /*!< SCB CCR: STKOFHFNMIGN Position */
#define SCB_CCR_STKOFHFNMIGN_Msk (1UL << SCB_CCR_STKOFHFNMIGN_Pos) /*!< SCB CCR: STKOFHFNMIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_HARDFAULTPENDED_Pos 21U /*!< SCB SHCSR: HARDFAULTPENDED Position */
#define SCB_SHCSR_HARDFAULTPENDED_Msk (1UL << SCB_SHCSR_HARDFAULTPENDED_Pos) /*!< SCB SHCSR: HARDFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTPENDED_Pos 20U /*!< SCB SHCSR: SECUREFAULTPENDED Position */
#define SCB_SHCSR_SECUREFAULTPENDED_Msk (1UL << SCB_SHCSR_SECUREFAULTPENDED_Pos) /*!< SCB SHCSR: SECUREFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTENA_Pos 19U /*!< SCB SHCSR: SECUREFAULTENA Position */
#define SCB_SHCSR_SECUREFAULTENA_Msk (1UL << SCB_SHCSR_SECUREFAULTENA_Pos) /*!< SCB SHCSR: SECUREFAULTENA Mask */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_NMIACT_Pos 5U /*!< SCB SHCSR: NMIACT Position */
#define SCB_SHCSR_NMIACT_Msk (1UL << SCB_SHCSR_NMIACT_Pos) /*!< SCB SHCSR: NMIACT Mask */
#define SCB_SHCSR_SECUREFAULTACT_Pos 4U /*!< SCB SHCSR: SECUREFAULTACT Position */
#define SCB_SHCSR_SECUREFAULTACT_Msk (1UL << SCB_SHCSR_SECUREFAULTACT_Pos) /*!< SCB SHCSR: SECUREFAULTACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_HARDFAULTACT_Pos 2U /*!< SCB SHCSR: HARDFAULTACT Position */
#define SCB_SHCSR_HARDFAULTACT_Msk (1UL << SCB_SHCSR_HARDFAULTACT_Pos) /*!< SCB SHCSR: HARDFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MLSPERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 5U) /*!< SCB CFSR (MMFSR): MLSPERR Position */
#define SCB_CFSR_MLSPERR_Msk (1UL << SCB_CFSR_MLSPERR_Pos) /*!< SCB CFSR (MMFSR): MLSPERR Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_LSPERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 5U) /*!< SCB CFSR (BFSR): LSPERR Position */
#define SCB_CFSR_LSPERR_Msk (1UL << SCB_CFSR_LSPERR_Pos) /*!< SCB CFSR (BFSR): LSPERR Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_STKOF_Pos (SCB_CFSR_USGFAULTSR_Pos + 4U) /*!< SCB CFSR (UFSR): STKOF Position */
#define SCB_CFSR_STKOF_Msk (1UL << SCB_CFSR_STKOF_Pos) /*!< SCB CFSR (UFSR): STKOF Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/* SCB Non-Secure Access Control Register Definitions */
#define SCB_NSACR_CP11_Pos 11U /*!< SCB NSACR: CP11 Position */
#define SCB_NSACR_CP11_Msk (1UL << SCB_NSACR_CP11_Pos) /*!< SCB NSACR: CP11 Mask */
#define SCB_NSACR_CP10_Pos 10U /*!< SCB NSACR: CP10 Position */
#define SCB_NSACR_CP10_Msk (1UL << SCB_NSACR_CP10_Pos) /*!< SCB NSACR: CP10 Mask */
#define SCB_NSACR_CPn_Pos 0U /*!< SCB NSACR: CPn Position */
#define SCB_NSACR_CPn_Msk (1UL /*<< SCB_NSACR_CPn_Pos*/) /*!< SCB NSACR: CPn Mask */
/* SCB Cache Level ID Register Definitions */
#define SCB_CLIDR_LOUU_Pos 27U /*!< SCB CLIDR: LoUU Position */
#define SCB_CLIDR_LOUU_Msk (7UL << SCB_CLIDR_LOUU_Pos) /*!< SCB CLIDR: LoUU Mask */
#define SCB_CLIDR_LOC_Pos 24U /*!< SCB CLIDR: LoC Position */
#define SCB_CLIDR_LOC_Msk (7UL << SCB_CLIDR_LOC_Pos) /*!< SCB CLIDR: LoC Mask */
/* SCB Cache Type Register Definitions */
#define SCB_CTR_FORMAT_Pos 29U /*!< SCB CTR: Format Position */
#define SCB_CTR_FORMAT_Msk (7UL << SCB_CTR_FORMAT_Pos) /*!< SCB CTR: Format Mask */
#define SCB_CTR_CWG_Pos 24U /*!< SCB CTR: CWG Position */
#define SCB_CTR_CWG_Msk (0xFUL << SCB_CTR_CWG_Pos) /*!< SCB CTR: CWG Mask */
#define SCB_CTR_ERG_Pos 20U /*!< SCB CTR: ERG Position */
#define SCB_CTR_ERG_Msk (0xFUL << SCB_CTR_ERG_Pos) /*!< SCB CTR: ERG Mask */
#define SCB_CTR_DMINLINE_Pos 16U /*!< SCB CTR: DminLine Position */
#define SCB_CTR_DMINLINE_Msk (0xFUL << SCB_CTR_DMINLINE_Pos) /*!< SCB CTR: DminLine Mask */
#define SCB_CTR_IMINLINE_Pos 0U /*!< SCB CTR: ImInLine Position */
#define SCB_CTR_IMINLINE_Msk (0xFUL /*<< SCB_CTR_IMINLINE_Pos*/) /*!< SCB CTR: ImInLine Mask */
/* SCB Cache Size ID Register Definitions */
#define SCB_CCSIDR_WT_Pos 31U /*!< SCB CCSIDR: WT Position */
#define SCB_CCSIDR_WT_Msk (1UL << SCB_CCSIDR_WT_Pos) /*!< SCB CCSIDR: WT Mask */
#define SCB_CCSIDR_WB_Pos 30U /*!< SCB CCSIDR: WB Position */
#define SCB_CCSIDR_WB_Msk (1UL << SCB_CCSIDR_WB_Pos) /*!< SCB CCSIDR: WB Mask */
#define SCB_CCSIDR_RA_Pos 29U /*!< SCB CCSIDR: RA Position */
#define SCB_CCSIDR_RA_Msk (1UL << SCB_CCSIDR_RA_Pos) /*!< SCB CCSIDR: RA Mask */
#define SCB_CCSIDR_WA_Pos 28U /*!< SCB CCSIDR: WA Position */
#define SCB_CCSIDR_WA_Msk (1UL << SCB_CCSIDR_WA_Pos) /*!< SCB CCSIDR: WA Mask */
#define SCB_CCSIDR_NUMSETS_Pos 13U /*!< SCB CCSIDR: NumSets Position */
#define SCB_CCSIDR_NUMSETS_Msk (0x7FFFUL << SCB_CCSIDR_NUMSETS_Pos) /*!< SCB CCSIDR: NumSets Mask */
#define SCB_CCSIDR_ASSOCIATIVITY_Pos 3U /*!< SCB CCSIDR: Associativity Position */
#define SCB_CCSIDR_ASSOCIATIVITY_Msk (0x3FFUL << SCB_CCSIDR_ASSOCIATIVITY_Pos) /*!< SCB CCSIDR: Associativity Mask */
#define SCB_CCSIDR_LINESIZE_Pos 0U /*!< SCB CCSIDR: LineSize Position */
#define SCB_CCSIDR_LINESIZE_Msk (7UL /*<< SCB_CCSIDR_LINESIZE_Pos*/) /*!< SCB CCSIDR: LineSize Mask */
/* SCB Cache Size Selection Register Definitions */
#define SCB_CSSELR_LEVEL_Pos 1U /*!< SCB CSSELR: Level Position */
#define SCB_CSSELR_LEVEL_Msk (7UL << SCB_CSSELR_LEVEL_Pos) /*!< SCB CSSELR: Level Mask */
#define SCB_CSSELR_IND_Pos 0U /*!< SCB CSSELR: InD Position */
#define SCB_CSSELR_IND_Msk (1UL /*<< SCB_CSSELR_IND_Pos*/) /*!< SCB CSSELR: InD Mask */
/* SCB Software Triggered Interrupt Register Definitions */
#define SCB_STIR_INTID_Pos 0U /*!< SCB STIR: INTID Position */
#define SCB_STIR_INTID_Msk (0x1FFUL /*<< SCB_STIR_INTID_Pos*/) /*!< SCB STIR: INTID Mask */
/* SCB D-Cache Invalidate by Set-way Register Definitions */
#define SCB_DCISW_WAY_Pos 30U /*!< SCB DCISW: Way Position */
#define SCB_DCISW_WAY_Msk (3UL << SCB_DCISW_WAY_Pos) /*!< SCB DCISW: Way Mask */
#define SCB_DCISW_SET_Pos 5U /*!< SCB DCISW: Set Position */
#define SCB_DCISW_SET_Msk (0x1FFUL << SCB_DCISW_SET_Pos) /*!< SCB DCISW: Set Mask */
/* SCB D-Cache Clean by Set-way Register Definitions */
#define SCB_DCCSW_WAY_Pos 30U /*!< SCB DCCSW: Way Position */
#define SCB_DCCSW_WAY_Msk (3UL << SCB_DCCSW_WAY_Pos) /*!< SCB DCCSW: Way Mask */
#define SCB_DCCSW_SET_Pos 5U /*!< SCB DCCSW: Set Position */
#define SCB_DCCSW_SET_Msk (0x1FFUL << SCB_DCCSW_SET_Pos) /*!< SCB DCCSW: Set Mask */
/* SCB D-Cache Clean and Invalidate by Set-way Register Definitions */
#define SCB_DCCISW_WAY_Pos 30U /*!< SCB DCCISW: Way Position */
#define SCB_DCCISW_WAY_Msk (3UL << SCB_DCCISW_WAY_Pos) /*!< SCB DCCISW: Way Mask */
#define SCB_DCCISW_SET_Pos 5U /*!< SCB DCCISW: Set Position */
#define SCB_DCCISW_SET_Msk (0x1FFUL << SCB_DCCISW_SET_Pos) /*!< SCB DCCISW: Set Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
__IOM uint32_t CPPWR; /*!< Offset: 0x00C (R/W) Coprocessor Power Control Register */
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[32U];
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) ITM Device Architecture Register */
uint32_t RESERVED6[4U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Stimulus Port Register Definitions */
#define ITM_STIM_DISABLED_Pos 1U /*!< ITM STIM: DISABLED Position */
#define ITM_STIM_DISABLED_Msk (0x1UL << ITM_STIM_DISABLED_Pos) /*!< ITM STIM: DISABLED Mask */
#define ITM_STIM_FIFOREADY_Pos 0U /*!< ITM STIM: FIFOREADY Position */
#define ITM_STIM_FIFOREADY_Msk (0x1UL /*<< ITM_STIM_FIFOREADY_Pos*/) /*!< ITM STIM: FIFOREADY Mask */
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFFFFFFFFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TRACEBUSID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TRACEBUSID_Msk (0x7FUL << ITM_TCR_TRACEBUSID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPRESCALE_Pos 8U /*!< ITM TCR: TSPRESCALE Position */
#define ITM_TCR_TSPRESCALE_Msk (3UL << ITM_TCR_TSPRESCALE_Pos) /*!< ITM TCR: TSPRESCALE Mask */
#define ITM_TCR_STALLENA_Pos 5U /*!< ITM TCR: STALLENA Position */
#define ITM_TCR_STALLENA_Msk (1UL << ITM_TCR_STALLENA_Pos) /*!< ITM TCR: STALLENA Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
uint32_t RESERVED1[1U];
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
uint32_t RESERVED3[1U];
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED4[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
uint32_t RESERVED5[1U];
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED6[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
uint32_t RESERVED7[1U];
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
uint32_t RESERVED8[1U];
__IOM uint32_t COMP4; /*!< Offset: 0x060 (R/W) Comparator Register 4 */
uint32_t RESERVED9[1U];
__IOM uint32_t FUNCTION4; /*!< Offset: 0x068 (R/W) Function Register 4 */
uint32_t RESERVED10[1U];
__IOM uint32_t COMP5; /*!< Offset: 0x070 (R/W) Comparator Register 5 */
uint32_t RESERVED11[1U];
__IOM uint32_t FUNCTION5; /*!< Offset: 0x078 (R/W) Function Register 5 */
uint32_t RESERVED12[1U];
__IOM uint32_t COMP6; /*!< Offset: 0x080 (R/W) Comparator Register 6 */
uint32_t RESERVED13[1U];
__IOM uint32_t FUNCTION6; /*!< Offset: 0x088 (R/W) Function Register 6 */
uint32_t RESERVED14[1U];
__IOM uint32_t COMP7; /*!< Offset: 0x090 (R/W) Comparator Register 7 */
uint32_t RESERVED15[1U];
__IOM uint32_t FUNCTION7; /*!< Offset: 0x098 (R/W) Function Register 7 */
uint32_t RESERVED16[1U];
__IOM uint32_t COMP8; /*!< Offset: 0x0A0 (R/W) Comparator Register 8 */
uint32_t RESERVED17[1U];
__IOM uint32_t FUNCTION8; /*!< Offset: 0x0A8 (R/W) Function Register 8 */
uint32_t RESERVED18[1U];
__IOM uint32_t COMP9; /*!< Offset: 0x0B0 (R/W) Comparator Register 9 */
uint32_t RESERVED19[1U];
__IOM uint32_t FUNCTION9; /*!< Offset: 0x0B8 (R/W) Function Register 9 */
uint32_t RESERVED20[1U];
__IOM uint32_t COMP10; /*!< Offset: 0x0C0 (R/W) Comparator Register 10 */
uint32_t RESERVED21[1U];
__IOM uint32_t FUNCTION10; /*!< Offset: 0x0C8 (R/W) Function Register 10 */
uint32_t RESERVED22[1U];
__IOM uint32_t COMP11; /*!< Offset: 0x0D0 (R/W) Comparator Register 11 */
uint32_t RESERVED23[1U];
__IOM uint32_t FUNCTION11; /*!< Offset: 0x0D8 (R/W) Function Register 11 */
uint32_t RESERVED24[1U];
__IOM uint32_t COMP12; /*!< Offset: 0x0E0 (R/W) Comparator Register 12 */
uint32_t RESERVED25[1U];
__IOM uint32_t FUNCTION12; /*!< Offset: 0x0E8 (R/W) Function Register 12 */
uint32_t RESERVED26[1U];
__IOM uint32_t COMP13; /*!< Offset: 0x0F0 (R/W) Comparator Register 13 */
uint32_t RESERVED27[1U];
__IOM uint32_t FUNCTION13; /*!< Offset: 0x0F8 (R/W) Function Register 13 */
uint32_t RESERVED28[1U];
__IOM uint32_t COMP14; /*!< Offset: 0x100 (R/W) Comparator Register 14 */
uint32_t RESERVED29[1U];
__IOM uint32_t FUNCTION14; /*!< Offset: 0x108 (R/W) Function Register 14 */
uint32_t RESERVED30[1U];
__IOM uint32_t COMP15; /*!< Offset: 0x110 (R/W) Comparator Register 15 */
uint32_t RESERVED31[1U];
__IOM uint32_t FUNCTION15; /*!< Offset: 0x118 (R/W) Function Register 15 */
uint32_t RESERVED32[934U];
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R ) Lock Status Register */
uint32_t RESERVED33[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) Device Architecture Register */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCDISS_Pos 23U /*!< DWT CTRL: CYCDISS Position */
#define DWT_CTRL_CYCDISS_Msk (0x1UL << DWT_CTRL_CYCDISS_Pos) /*!< DWT CTRL: CYCDISS Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_ID_Pos 27U /*!< DWT FUNCTION: ID Position */
#define DWT_FUNCTION_ID_Msk (0x1FUL << DWT_FUNCTION_ID_Pos) /*!< DWT FUNCTION: ID Mask */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_ACTION_Pos 4U /*!< DWT FUNCTION: ACTION Position */
#define DWT_FUNCTION_ACTION_Msk (0x1UL << DWT_FUNCTION_ACTION_Pos) /*!< DWT FUNCTION: ACTION Mask */
#define DWT_FUNCTION_MATCH_Pos 0U /*!< DWT FUNCTION: MATCH Position */
#define DWT_FUNCTION_MATCH_Msk (0xFUL /*<< DWT_FUNCTION_MATCH_Pos*/) /*!< DWT FUNCTION: MATCH Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Size Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Size Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IOM uint32_t PSCR; /*!< Offset: 0x308 (R/W) Periodic Synchronization Control Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER Register */
__IM uint32_t ITFTTD0; /*!< Offset: 0xEEC (R/ ) Integration Test FIFO Test Data 0 Register */
__IOM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/W) Integration Test ATB Control Register 2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) Integration Test ATB Control Register 0 */
__IM uint32_t ITFTTD1; /*!< Offset: 0xEFC (R/ ) Integration Test FIFO Test Data 1 Register */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) Device Configuration Register */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) Device Type Identifier Register */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_FOnMan_Pos 6U /*!< TPI FFCR: FOnMan Position */
#define TPI_FFCR_FOnMan_Msk (0x1UL << TPI_FFCR_FOnMan_Pos) /*!< TPI FFCR: FOnMan Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration Test FIFO Test Data 0 Register Definitions */
#define TPI_ITFTTD0_ATB_IF2_ATVALID_Pos 29U /*!< TPI ITFTTD0: ATB Interface 2 ATVALIDPosition */
#define TPI_ITFTTD0_ATB_IF2_ATVALID_Msk (0x3UL << TPI_ITFTTD0_ATB_IF2_ATVALID_Pos) /*!< TPI ITFTTD0: ATB Interface 2 ATVALID Mask */
#define TPI_ITFTTD0_ATB_IF2_bytecount_Pos 27U /*!< TPI ITFTTD0: ATB Interface 2 byte count Position */
#define TPI_ITFTTD0_ATB_IF2_bytecount_Msk (0x3UL << TPI_ITFTTD0_ATB_IF2_bytecount_Pos) /*!< TPI ITFTTD0: ATB Interface 2 byte count Mask */
#define TPI_ITFTTD0_ATB_IF1_ATVALID_Pos 26U /*!< TPI ITFTTD0: ATB Interface 1 ATVALID Position */
#define TPI_ITFTTD0_ATB_IF1_ATVALID_Msk (0x3UL << TPI_ITFTTD0_ATB_IF1_ATVALID_Pos) /*!< TPI ITFTTD0: ATB Interface 1 ATVALID Mask */
#define TPI_ITFTTD0_ATB_IF1_bytecount_Pos 24U /*!< TPI ITFTTD0: ATB Interface 1 byte count Position */
#define TPI_ITFTTD0_ATB_IF1_bytecount_Msk (0x3UL << TPI_ITFTTD0_ATB_IF1_bytecount_Pos) /*!< TPI ITFTTD0: ATB Interface 1 byte countt Mask */
#define TPI_ITFTTD0_ATB_IF1_data2_Pos 16U /*!< TPI ITFTTD0: ATB Interface 1 data2 Position */
#define TPI_ITFTTD0_ATB_IF1_data2_Msk (0xFFUL << TPI_ITFTTD0_ATB_IF1_data1_Pos) /*!< TPI ITFTTD0: ATB Interface 1 data2 Mask */
#define TPI_ITFTTD0_ATB_IF1_data1_Pos 8U /*!< TPI ITFTTD0: ATB Interface 1 data1 Position */
#define TPI_ITFTTD0_ATB_IF1_data1_Msk (0xFFUL << TPI_ITFTTD0_ATB_IF1_data1_Pos) /*!< TPI ITFTTD0: ATB Interface 1 data1 Mask */
#define TPI_ITFTTD0_ATB_IF1_data0_Pos 0U /*!< TPI ITFTTD0: ATB Interface 1 data0 Position */
#define TPI_ITFTTD0_ATB_IF1_data0_Msk (0xFFUL /*<< TPI_ITFTTD0_ATB_IF1_data0_Pos*/) /*!< TPI ITFTTD0: ATB Interface 1 data0 Mask */
/* TPI Integration Test ATB Control Register 2 Register Definitions */
#define TPI_ITATBCTR2_AFVALID2S_Pos 1U /*!< TPI ITATBCTR2: AFVALID2S Position */
#define TPI_ITATBCTR2_AFVALID2S_Msk (0x1UL << TPI_ITATBCTR2_AFVALID2S_Pos) /*!< TPI ITATBCTR2: AFVALID2SS Mask */
#define TPI_ITATBCTR2_AFVALID1S_Pos 1U /*!< TPI ITATBCTR2: AFVALID1S Position */
#define TPI_ITATBCTR2_AFVALID1S_Msk (0x1UL << TPI_ITATBCTR2_AFVALID1S_Pos) /*!< TPI ITATBCTR2: AFVALID1SS Mask */
#define TPI_ITATBCTR2_ATREADY2S_Pos 0U /*!< TPI ITATBCTR2: ATREADY2S Position */
#define TPI_ITATBCTR2_ATREADY2S_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY2S_Pos*/) /*!< TPI ITATBCTR2: ATREADY2S Mask */
#define TPI_ITATBCTR2_ATREADY1S_Pos 0U /*!< TPI ITATBCTR2: ATREADY1S Position */
#define TPI_ITATBCTR2_ATREADY1S_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY1S_Pos*/) /*!< TPI ITATBCTR2: ATREADY1S Mask */
/* TPI Integration Test FIFO Test Data 1 Register Definitions */
#define TPI_ITFTTD1_ATB_IF2_ATVALID_Pos 29U /*!< TPI ITFTTD1: ATB Interface 2 ATVALID Position */
#define TPI_ITFTTD1_ATB_IF2_ATVALID_Msk (0x3UL << TPI_ITFTTD1_ATB_IF2_ATVALID_Pos) /*!< TPI ITFTTD1: ATB Interface 2 ATVALID Mask */
#define TPI_ITFTTD1_ATB_IF2_bytecount_Pos 27U /*!< TPI ITFTTD1: ATB Interface 2 byte count Position */
#define TPI_ITFTTD1_ATB_IF2_bytecount_Msk (0x3UL << TPI_ITFTTD1_ATB_IF2_bytecount_Pos) /*!< TPI ITFTTD1: ATB Interface 2 byte count Mask */
#define TPI_ITFTTD1_ATB_IF1_ATVALID_Pos 26U /*!< TPI ITFTTD1: ATB Interface 1 ATVALID Position */
#define TPI_ITFTTD1_ATB_IF1_ATVALID_Msk (0x3UL << TPI_ITFTTD1_ATB_IF1_ATVALID_Pos) /*!< TPI ITFTTD1: ATB Interface 1 ATVALID Mask */
#define TPI_ITFTTD1_ATB_IF1_bytecount_Pos 24U /*!< TPI ITFTTD1: ATB Interface 1 byte count Position */
#define TPI_ITFTTD1_ATB_IF1_bytecount_Msk (0x3UL << TPI_ITFTTD1_ATB_IF1_bytecount_Pos) /*!< TPI ITFTTD1: ATB Interface 1 byte countt Mask */
#define TPI_ITFTTD1_ATB_IF2_data2_Pos 16U /*!< TPI ITFTTD1: ATB Interface 2 data2 Position */
#define TPI_ITFTTD1_ATB_IF2_data2_Msk (0xFFUL << TPI_ITFTTD1_ATB_IF2_data1_Pos) /*!< TPI ITFTTD1: ATB Interface 2 data2 Mask */
#define TPI_ITFTTD1_ATB_IF2_data1_Pos 8U /*!< TPI ITFTTD1: ATB Interface 2 data1 Position */
#define TPI_ITFTTD1_ATB_IF2_data1_Msk (0xFFUL << TPI_ITFTTD1_ATB_IF2_data1_Pos) /*!< TPI ITFTTD1: ATB Interface 2 data1 Mask */
#define TPI_ITFTTD1_ATB_IF2_data0_Pos 0U /*!< TPI ITFTTD1: ATB Interface 2 data0 Position */
#define TPI_ITFTTD1_ATB_IF2_data0_Msk (0xFFUL /*<< TPI_ITFTTD1_ATB_IF2_data0_Pos*/) /*!< TPI ITFTTD1: ATB Interface 2 data0 Mask */
/* TPI Integration Test ATB Control Register 0 Definitions */
#define TPI_ITATBCTR0_AFVALID2S_Pos 1U /*!< TPI ITATBCTR0: AFVALID2S Position */
#define TPI_ITATBCTR0_AFVALID2S_Msk (0x1UL << TPI_ITATBCTR0_AFVALID2S_Pos) /*!< TPI ITATBCTR0: AFVALID2SS Mask */
#define TPI_ITATBCTR0_AFVALID1S_Pos 1U /*!< TPI ITATBCTR0: AFVALID1S Position */
#define TPI_ITATBCTR0_AFVALID1S_Msk (0x1UL << TPI_ITATBCTR0_AFVALID1S_Pos) /*!< TPI ITATBCTR0: AFVALID1SS Mask */
#define TPI_ITATBCTR0_ATREADY2S_Pos 0U /*!< TPI ITATBCTR0: ATREADY2S Position */
#define TPI_ITATBCTR0_ATREADY2S_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY2S_Pos*/) /*!< TPI ITATBCTR0: ATREADY2S Mask */
#define TPI_ITATBCTR0_ATREADY1S_Pos 0U /*!< TPI ITATBCTR0: ATREADY1S Position */
#define TPI_ITATBCTR0_ATREADY1S_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY1S_Pos*/) /*!< TPI ITATBCTR0: ATREADY1S Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x3UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_FIFOSZ_Pos 6U /*!< TPI DEVID: FIFOSZ Position */
#define TPI_DEVID_FIFOSZ_Msk (0x7UL << TPI_DEVID_FIFOSZ_Pos) /*!< TPI DEVID: FIFOSZ Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x3FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) MPU Region Limit Address Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Region Base Address Register Alias 1 */
__IOM uint32_t RLAR_A1; /*!< Offset: 0x018 (R/W) MPU Region Limit Address Register Alias 1 */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Region Base Address Register Alias 2 */
__IOM uint32_t RLAR_A2; /*!< Offset: 0x020 (R/W) MPU Region Limit Address Register Alias 2 */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Region Base Address Register Alias 3 */
__IOM uint32_t RLAR_A3; /*!< Offset: 0x028 (R/W) MPU Region Limit Address Register Alias 3 */
uint32_t RESERVED0[1];
union {
__IOM uint32_t MAIR[2];
struct {
__IOM uint32_t MAIR0; /*!< Offset: 0x030 (R/W) MPU Memory Attribute Indirection Register 0 */
__IOM uint32_t MAIR1; /*!< Offset: 0x034 (R/W) MPU Memory Attribute Indirection Register 1 */
};
};
} MPU_Type;
#define MPU_TYPE_RALIASES 4U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_BASE_Pos 5U /*!< MPU RBAR: BASE Position */
#define MPU_RBAR_BASE_Msk (0x7FFFFFFUL << MPU_RBAR_BASE_Pos) /*!< MPU RBAR: BASE Mask */
#define MPU_RBAR_SH_Pos 3U /*!< MPU RBAR: SH Position */
#define MPU_RBAR_SH_Msk (0x3UL << MPU_RBAR_SH_Pos) /*!< MPU RBAR: SH Mask */
#define MPU_RBAR_AP_Pos 1U /*!< MPU RBAR: AP Position */
#define MPU_RBAR_AP_Msk (0x3UL << MPU_RBAR_AP_Pos) /*!< MPU RBAR: AP Mask */
#define MPU_RBAR_XN_Pos 0U /*!< MPU RBAR: XN Position */
#define MPU_RBAR_XN_Msk (01UL /*<< MPU_RBAR_XN_Pos*/) /*!< MPU RBAR: XN Mask */
/* MPU Region Limit Address Register Definitions */
#define MPU_RLAR_LIMIT_Pos 5U /*!< MPU RLAR: LIMIT Position */
#define MPU_RLAR_LIMIT_Msk (0x7FFFFFFUL << MPU_RLAR_LIMIT_Pos) /*!< MPU RLAR: LIMIT Mask */
#define MPU_RLAR_AttrIndx_Pos 1U /*!< MPU RLAR: AttrIndx Position */
#define MPU_RLAR_AttrIndx_Msk (0x7UL << MPU_RLAR_AttrIndx_Pos) /*!< MPU RLAR: AttrIndx Mask */
#define MPU_RLAR_EN_Pos 0U /*!< MPU RLAR: Region enable bit Position */
#define MPU_RLAR_EN_Msk (1UL /*<< MPU_RLAR_EN_Pos*/) /*!< MPU RLAR: Region enable bit Disable Mask */
/* MPU Memory Attribute Indirection Register 0 Definitions */
#define MPU_MAIR0_Attr3_Pos 24U /*!< MPU MAIR0: Attr3 Position */
#define MPU_MAIR0_Attr3_Msk (0xFFUL << MPU_MAIR0_Attr3_Pos) /*!< MPU MAIR0: Attr3 Mask */
#define MPU_MAIR0_Attr2_Pos 16U /*!< MPU MAIR0: Attr2 Position */
#define MPU_MAIR0_Attr2_Msk (0xFFUL << MPU_MAIR0_Attr2_Pos) /*!< MPU MAIR0: Attr2 Mask */
#define MPU_MAIR0_Attr1_Pos 8U /*!< MPU MAIR0: Attr1 Position */
#define MPU_MAIR0_Attr1_Msk (0xFFUL << MPU_MAIR0_Attr1_Pos) /*!< MPU MAIR0: Attr1 Mask */
#define MPU_MAIR0_Attr0_Pos 0U /*!< MPU MAIR0: Attr0 Position */
#define MPU_MAIR0_Attr0_Msk (0xFFUL /*<< MPU_MAIR0_Attr0_Pos*/) /*!< MPU MAIR0: Attr0 Mask */
/* MPU Memory Attribute Indirection Register 1 Definitions */
#define MPU_MAIR1_Attr7_Pos 24U /*!< MPU MAIR1: Attr7 Position */
#define MPU_MAIR1_Attr7_Msk (0xFFUL << MPU_MAIR1_Attr7_Pos) /*!< MPU MAIR1: Attr7 Mask */
#define MPU_MAIR1_Attr6_Pos 16U /*!< MPU MAIR1: Attr6 Position */
#define MPU_MAIR1_Attr6_Msk (0xFFUL << MPU_MAIR1_Attr6_Pos) /*!< MPU MAIR1: Attr6 Mask */
#define MPU_MAIR1_Attr5_Pos 8U /*!< MPU MAIR1: Attr5 Position */
#define MPU_MAIR1_Attr5_Msk (0xFFUL << MPU_MAIR1_Attr5_Pos) /*!< MPU MAIR1: Attr5 Mask */
#define MPU_MAIR1_Attr4_Pos 0U /*!< MPU MAIR1: Attr4 Position */
#define MPU_MAIR1_Attr4_Msk (0xFFUL /*<< MPU_MAIR1_Attr4_Pos*/) /*!< MPU MAIR1: Attr4 Mask */
/*@} end of group CMSIS_MPU */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SAU Security Attribution Unit (SAU)
\brief Type definitions for the Security Attribution Unit (SAU)
@{
*/
/**
\brief Structure type to access the Security Attribution Unit (SAU).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SAU Control Register */
__IM uint32_t TYPE; /*!< Offset: 0x004 (R/ ) SAU Type Register */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) SAU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) SAU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) SAU Region Limit Address Register */
#else
uint32_t RESERVED0[3];
#endif
__IOM uint32_t SFSR; /*!< Offset: 0x014 (R/W) Secure Fault Status Register */
__IOM uint32_t SFAR; /*!< Offset: 0x018 (R/W) Secure Fault Address Register */
} SAU_Type;
/* SAU Control Register Definitions */
#define SAU_CTRL_ALLNS_Pos 1U /*!< SAU CTRL: ALLNS Position */
#define SAU_CTRL_ALLNS_Msk (1UL << SAU_CTRL_ALLNS_Pos) /*!< SAU CTRL: ALLNS Mask */
#define SAU_CTRL_ENABLE_Pos 0U /*!< SAU CTRL: ENABLE Position */
#define SAU_CTRL_ENABLE_Msk (1UL /*<< SAU_CTRL_ENABLE_Pos*/) /*!< SAU CTRL: ENABLE Mask */
/* SAU Type Register Definitions */
#define SAU_TYPE_SREGION_Pos 0U /*!< SAU TYPE: SREGION Position */
#define SAU_TYPE_SREGION_Msk (0xFFUL /*<< SAU_TYPE_SREGION_Pos*/) /*!< SAU TYPE: SREGION Mask */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
/* SAU Region Number Register Definitions */
#define SAU_RNR_REGION_Pos 0U /*!< SAU RNR: REGION Position */
#define SAU_RNR_REGION_Msk (0xFFUL /*<< SAU_RNR_REGION_Pos*/) /*!< SAU RNR: REGION Mask */
/* SAU Region Base Address Register Definitions */
#define SAU_RBAR_BADDR_Pos 5U /*!< SAU RBAR: BADDR Position */
#define SAU_RBAR_BADDR_Msk (0x7FFFFFFUL << SAU_RBAR_BADDR_Pos) /*!< SAU RBAR: BADDR Mask */
/* SAU Region Limit Address Register Definitions */
#define SAU_RLAR_LADDR_Pos 5U /*!< SAU RLAR: LADDR Position */
#define SAU_RLAR_LADDR_Msk (0x7FFFFFFUL << SAU_RLAR_LADDR_Pos) /*!< SAU RLAR: LADDR Mask */
#define SAU_RLAR_NSC_Pos 1U /*!< SAU RLAR: NSC Position */
#define SAU_RLAR_NSC_Msk (1UL << SAU_RLAR_NSC_Pos) /*!< SAU RLAR: NSC Mask */
#define SAU_RLAR_ENABLE_Pos 0U /*!< SAU RLAR: ENABLE Position */
#define SAU_RLAR_ENABLE_Msk (1UL /*<< SAU_RLAR_ENABLE_Pos*/) /*!< SAU RLAR: ENABLE Mask */
#endif /* defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U) */
/* Secure Fault Status Register Definitions */
#define SAU_SFSR_LSERR_Pos 7U /*!< SAU SFSR: LSERR Position */
#define SAU_SFSR_LSERR_Msk (1UL << SAU_SFSR_LSERR_Pos) /*!< SAU SFSR: LSERR Mask */
#define SAU_SFSR_SFARVALID_Pos 6U /*!< SAU SFSR: SFARVALID Position */
#define SAU_SFSR_SFARVALID_Msk (1UL << SAU_SFSR_SFARVALID_Pos) /*!< SAU SFSR: SFARVALID Mask */
#define SAU_SFSR_LSPERR_Pos 5U /*!< SAU SFSR: LSPERR Position */
#define SAU_SFSR_LSPERR_Msk (1UL << SAU_SFSR_LSPERR_Pos) /*!< SAU SFSR: LSPERR Mask */
#define SAU_SFSR_INVTRAN_Pos 4U /*!< SAU SFSR: INVTRAN Position */
#define SAU_SFSR_INVTRAN_Msk (1UL << SAU_SFSR_INVTRAN_Pos) /*!< SAU SFSR: INVTRAN Mask */
#define SAU_SFSR_AUVIOL_Pos 3U /*!< SAU SFSR: AUVIOL Position */
#define SAU_SFSR_AUVIOL_Msk (1UL << SAU_SFSR_AUVIOL_Pos) /*!< SAU SFSR: AUVIOL Mask */
#define SAU_SFSR_INVER_Pos 2U /*!< SAU SFSR: INVER Position */
#define SAU_SFSR_INVER_Msk (1UL << SAU_SFSR_INVER_Pos) /*!< SAU SFSR: INVER Mask */
#define SAU_SFSR_INVIS_Pos 1U /*!< SAU SFSR: INVIS Position */
#define SAU_SFSR_INVIS_Msk (1UL << SAU_SFSR_INVIS_Pos) /*!< SAU SFSR: INVIS Mask */
#define SAU_SFSR_INVEP_Pos 0U /*!< SAU SFSR: INVEP Position */
#define SAU_SFSR_INVEP_Msk (1UL /*<< SAU_SFSR_INVEP_Pos*/) /*!< SAU SFSR: INVEP Mask */
/*@} end of group CMSIS_SAU */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_FPU Floating Point Unit (FPU)
\brief Type definitions for the Floating Point Unit (FPU)
@{
*/
/**
\brief Structure type to access the Floating Point Unit (FPU).
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IOM uint32_t FPCCR; /*!< Offset: 0x004 (R/W) Floating-Point Context Control Register */
__IOM uint32_t FPCAR; /*!< Offset: 0x008 (R/W) Floating-Point Context Address Register */
__IOM uint32_t FPDSCR; /*!< Offset: 0x00C (R/W) Floating-Point Default Status Control Register */
__IM uint32_t MVFR0; /*!< Offset: 0x010 (R/ ) Media and FP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x014 (R/ ) Media and FP Feature Register 1 */
} FPU_Type;
/* Floating-Point Context Control Register Definitions */
#define FPU_FPCCR_ASPEN_Pos 31U /*!< FPCCR: ASPEN bit Position */
#define FPU_FPCCR_ASPEN_Msk (1UL << FPU_FPCCR_ASPEN_Pos) /*!< FPCCR: ASPEN bit Mask */
#define FPU_FPCCR_LSPEN_Pos 30U /*!< FPCCR: LSPEN Position */
#define FPU_FPCCR_LSPEN_Msk (1UL << FPU_FPCCR_LSPEN_Pos) /*!< FPCCR: LSPEN bit Mask */
#define FPU_FPCCR_LSPENS_Pos 29U /*!< FPCCR: LSPENS Position */
#define FPU_FPCCR_LSPENS_Msk (1UL << FPU_FPCCR_LSPENS_Pos) /*!< FPCCR: LSPENS bit Mask */
#define FPU_FPCCR_CLRONRET_Pos 28U /*!< FPCCR: CLRONRET Position */
#define FPU_FPCCR_CLRONRET_Msk (1UL << FPU_FPCCR_CLRONRET_Pos) /*!< FPCCR: CLRONRET bit Mask */
#define FPU_FPCCR_CLRONRETS_Pos 27U /*!< FPCCR: CLRONRETS Position */
#define FPU_FPCCR_CLRONRETS_Msk (1UL << FPU_FPCCR_CLRONRETS_Pos) /*!< FPCCR: CLRONRETS bit Mask */
#define FPU_FPCCR_TS_Pos 26U /*!< FPCCR: TS Position */
#define FPU_FPCCR_TS_Msk (1UL << FPU_FPCCR_TS_Pos) /*!< FPCCR: TS bit Mask */
#define FPU_FPCCR_UFRDY_Pos 10U /*!< FPCCR: UFRDY Position */
#define FPU_FPCCR_UFRDY_Msk (1UL << FPU_FPCCR_UFRDY_Pos) /*!< FPCCR: UFRDY bit Mask */
#define FPU_FPCCR_SPLIMVIOL_Pos 9U /*!< FPCCR: SPLIMVIOL Position */
#define FPU_FPCCR_SPLIMVIOL_Msk (1UL << FPU_FPCCR_SPLIMVIOL_Pos) /*!< FPCCR: SPLIMVIOL bit Mask */
#define FPU_FPCCR_MONRDY_Pos 8U /*!< FPCCR: MONRDY Position */
#define FPU_FPCCR_MONRDY_Msk (1UL << FPU_FPCCR_MONRDY_Pos) /*!< FPCCR: MONRDY bit Mask */
#define FPU_FPCCR_SFRDY_Pos 7U /*!< FPCCR: SFRDY Position */
#define FPU_FPCCR_SFRDY_Msk (1UL << FPU_FPCCR_SFRDY_Pos) /*!< FPCCR: SFRDY bit Mask */
#define FPU_FPCCR_BFRDY_Pos 6U /*!< FPCCR: BFRDY Position */
#define FPU_FPCCR_BFRDY_Msk (1UL << FPU_FPCCR_BFRDY_Pos) /*!< FPCCR: BFRDY bit Mask */
#define FPU_FPCCR_MMRDY_Pos 5U /*!< FPCCR: MMRDY Position */
#define FPU_FPCCR_MMRDY_Msk (1UL << FPU_FPCCR_MMRDY_Pos) /*!< FPCCR: MMRDY bit Mask */
#define FPU_FPCCR_HFRDY_Pos 4U /*!< FPCCR: HFRDY Position */
#define FPU_FPCCR_HFRDY_Msk (1UL << FPU_FPCCR_HFRDY_Pos) /*!< FPCCR: HFRDY bit Mask */
#define FPU_FPCCR_THREAD_Pos 3U /*!< FPCCR: processor mode bit Position */
#define FPU_FPCCR_THREAD_Msk (1UL << FPU_FPCCR_THREAD_Pos) /*!< FPCCR: processor mode active bit Mask */
#define FPU_FPCCR_S_Pos 2U /*!< FPCCR: Security status of the FP context bit Position */
#define FPU_FPCCR_S_Msk (1UL << FPU_FPCCR_S_Pos) /*!< FPCCR: Security status of the FP context bit Mask */
#define FPU_FPCCR_USER_Pos 1U /*!< FPCCR: privilege level bit Position */
#define FPU_FPCCR_USER_Msk (1UL << FPU_FPCCR_USER_Pos) /*!< FPCCR: privilege level bit Mask */
#define FPU_FPCCR_LSPACT_Pos 0U /*!< FPCCR: Lazy state preservation active bit Position */
#define FPU_FPCCR_LSPACT_Msk (1UL /*<< FPU_FPCCR_LSPACT_Pos*/) /*!< FPCCR: Lazy state preservation active bit Mask */
/* Floating-Point Context Address Register Definitions */
#define FPU_FPCAR_ADDRESS_Pos 3U /*!< FPCAR: ADDRESS bit Position */
#define FPU_FPCAR_ADDRESS_Msk (0x1FFFFFFFUL << FPU_FPCAR_ADDRESS_Pos) /*!< FPCAR: ADDRESS bit Mask */
/* Floating-Point Default Status Control Register Definitions */
#define FPU_FPDSCR_AHP_Pos 26U /*!< FPDSCR: AHP bit Position */
#define FPU_FPDSCR_AHP_Msk (1UL << FPU_FPDSCR_AHP_Pos) /*!< FPDSCR: AHP bit Mask */
#define FPU_FPDSCR_DN_Pos 25U /*!< FPDSCR: DN bit Position */
#define FPU_FPDSCR_DN_Msk (1UL << FPU_FPDSCR_DN_Pos) /*!< FPDSCR: DN bit Mask */
#define FPU_FPDSCR_FZ_Pos 24U /*!< FPDSCR: FZ bit Position */
#define FPU_FPDSCR_FZ_Msk (1UL << FPU_FPDSCR_FZ_Pos) /*!< FPDSCR: FZ bit Mask */
#define FPU_FPDSCR_RMode_Pos 22U /*!< FPDSCR: RMode bit Position */
#define FPU_FPDSCR_RMode_Msk (3UL << FPU_FPDSCR_RMode_Pos) /*!< FPDSCR: RMode bit Mask */
/* Media and FP Feature Register 0 Definitions */
#define FPU_MVFR0_FP_rounding_modes_Pos 28U /*!< MVFR0: FP rounding modes bits Position */
#define FPU_MVFR0_FP_rounding_modes_Msk (0xFUL << FPU_MVFR0_FP_rounding_modes_Pos) /*!< MVFR0: FP rounding modes bits Mask */
#define FPU_MVFR0_Short_vectors_Pos 24U /*!< MVFR0: Short vectors bits Position */
#define FPU_MVFR0_Short_vectors_Msk (0xFUL << FPU_MVFR0_Short_vectors_Pos) /*!< MVFR0: Short vectors bits Mask */
#define FPU_MVFR0_Square_root_Pos 20U /*!< MVFR0: Square root bits Position */
#define FPU_MVFR0_Square_root_Msk (0xFUL << FPU_MVFR0_Square_root_Pos) /*!< MVFR0: Square root bits Mask */
#define FPU_MVFR0_Divide_Pos 16U /*!< MVFR0: Divide bits Position */
#define FPU_MVFR0_Divide_Msk (0xFUL << FPU_MVFR0_Divide_Pos) /*!< MVFR0: Divide bits Mask */
#define FPU_MVFR0_FP_excep_trapping_Pos 12U /*!< MVFR0: FP exception trapping bits Position */
#define FPU_MVFR0_FP_excep_trapping_Msk (0xFUL << FPU_MVFR0_FP_excep_trapping_Pos) /*!< MVFR0: FP exception trapping bits Mask */
#define FPU_MVFR0_Double_precision_Pos 8U /*!< MVFR0: Double-precision bits Position */
#define FPU_MVFR0_Double_precision_Msk (0xFUL << FPU_MVFR0_Double_precision_Pos) /*!< MVFR0: Double-precision bits Mask */
#define FPU_MVFR0_Single_precision_Pos 4U /*!< MVFR0: Single-precision bits Position */
#define FPU_MVFR0_Single_precision_Msk (0xFUL << FPU_MVFR0_Single_precision_Pos) /*!< MVFR0: Single-precision bits Mask */
#define FPU_MVFR0_A_SIMD_registers_Pos 0U /*!< MVFR0: A_SIMD registers bits Position */
#define FPU_MVFR0_A_SIMD_registers_Msk (0xFUL /*<< FPU_MVFR0_A_SIMD_registers_Pos*/) /*!< MVFR0: A_SIMD registers bits Mask */
/* Media and FP Feature Register 1 Definitions */
#define FPU_MVFR1_FP_fused_MAC_Pos 28U /*!< MVFR1: FP fused MAC bits Position */
#define FPU_MVFR1_FP_fused_MAC_Msk (0xFUL << FPU_MVFR1_FP_fused_MAC_Pos) /*!< MVFR1: FP fused MAC bits Mask */
#define FPU_MVFR1_FP_HPFP_Pos 24U /*!< MVFR1: FP HPFP bits Position */
#define FPU_MVFR1_FP_HPFP_Msk (0xFUL << FPU_MVFR1_FP_HPFP_Pos) /*!< MVFR1: FP HPFP bits Mask */
#define FPU_MVFR1_D_NaN_mode_Pos 4U /*!< MVFR1: D_NaN mode bits Position */
#define FPU_MVFR1_D_NaN_mode_Msk (0xFUL << FPU_MVFR1_D_NaN_mode_Pos) /*!< MVFR1: D_NaN mode bits Mask */
#define FPU_MVFR1_FtZ_mode_Pos 0U /*!< MVFR1: FtZ mode bits Position */
#define FPU_MVFR1_FtZ_mode_Msk (0xFUL /*<< FPU_MVFR1_FtZ_mode_Pos*/) /*!< MVFR1: FtZ mode bits Mask */
/*@} end of group CMSIS_FPU */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
uint32_t RESERVED4[1U];
__IOM uint32_t DAUTHCTRL; /*!< Offset: 0x014 (R/W) Debug Authentication Control Register */
__IOM uint32_t DSCSR; /*!< Offset: 0x018 (R/W) Debug Security Control and Status Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESTART_ST_Pos 26U /*!< CoreDebug DHCSR: S_RESTART_ST Position */
#define CoreDebug_DHCSR_S_RESTART_ST_Msk (1UL << CoreDebug_DHCSR_S_RESTART_ST_Pos) /*!< CoreDebug DHCSR: S_RESTART_ST Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/* Debug Authentication Control Register Definitions */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos 3U /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Position */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Mask */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos 2U /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Msk (1UL << CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos) /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Mask */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Pos 1U /*!< CoreDebug DAUTHCTRL: INTSPIDEN Position */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPIDEN Mask */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Pos 0U /*!< CoreDebug DAUTHCTRL: SPIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Msk (1UL /*<< CoreDebug_DAUTHCTRL_SPIDENSEL_Pos*/) /*!< CoreDebug DAUTHCTRL: SPIDENSEL Mask */
/* Debug Security Control and Status Register Definitions */
#define CoreDebug_DSCSR_CDS_Pos 16U /*!< CoreDebug DSCSR: CDS Position */
#define CoreDebug_DSCSR_CDS_Msk (1UL << CoreDebug_DSCSR_CDS_Pos) /*!< CoreDebug DSCSR: CDS Mask */
#define CoreDebug_DSCSR_SBRSEL_Pos 1U /*!< CoreDebug DSCSR: SBRSEL Position */
#define CoreDebug_DSCSR_SBRSEL_Msk (1UL << CoreDebug_DSCSR_SBRSEL_Pos) /*!< CoreDebug DSCSR: SBRSEL Mask */
#define CoreDebug_DSCSR_SBRSELEN_Pos 0U /*!< CoreDebug DSCSR: SBRSELEN Position */
#define CoreDebug_DSCSR_SBRSELEN_Msk (1UL /*<< CoreDebug_DSCSR_SBRSELEN_Pos*/) /*!< CoreDebug DSCSR: SBRSELEN Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE ) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SAU_BASE (SCS_BASE + 0x0DD0UL) /*!< Security Attribution Unit */
#define SAU ((SAU_Type *) SAU_BASE ) /*!< Security Attribution Unit */
#endif
#define FPU_BASE (SCS_BASE + 0x0F30UL) /*!< Floating Point Unit */
#define FPU ((FPU_Type *) FPU_BASE ) /*!< Floating Point Unit */
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SCS_BASE_NS (0xE002E000UL) /*!< System Control Space Base Address (non-secure address space) */
#define CoreDebug_BASE_NS (0xE002EDF0UL) /*!< Core Debug Base Address (non-secure address space) */
#define SysTick_BASE_NS (SCS_BASE_NS + 0x0010UL) /*!< SysTick Base Address (non-secure address space) */
#define NVIC_BASE_NS (SCS_BASE_NS + 0x0100UL) /*!< NVIC Base Address (non-secure address space) */
#define SCB_BASE_NS (SCS_BASE_NS + 0x0D00UL) /*!< System Control Block Base Address (non-secure address space) */
#define SCnSCB_NS ((SCnSCB_Type *) SCS_BASE_NS ) /*!< System control Register not in SCB(non-secure address space) */
#define SCB_NS ((SCB_Type *) SCB_BASE_NS ) /*!< SCB configuration struct (non-secure address space) */
#define SysTick_NS ((SysTick_Type *) SysTick_BASE_NS ) /*!< SysTick configuration struct (non-secure address space) */
#define NVIC_NS ((NVIC_Type *) NVIC_BASE_NS ) /*!< NVIC configuration struct (non-secure address space) */
#define CoreDebug_NS ((CoreDebug_Type *) CoreDebug_BASE_NS) /*!< Core Debug configuration struct (non-secure address space) */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE_NS (SCS_BASE_NS + 0x0D90UL) /*!< Memory Protection Unit (non-secure address space) */
#define MPU_NS ((MPU_Type *) MPU_BASE_NS ) /*!< Memory Protection Unit (non-secure address space) */
#endif
#define FPU_BASE_NS (SCS_BASE_NS + 0x0F30UL) /*!< Floating Point Unit (non-secure address space) */
#define FPU_NS ((FPU_Type *) FPU_BASE_NS ) /*!< Floating Point Unit (non-secure address space) */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* Special LR values for Secure/Non-Secure call handling and exception handling */
/* Function Return Payload (from ARMv8-M Architecture Reference Manual) LR value on entry from Secure BLXNS */
#define FNC_RETURN (0xFEFFFFFFUL) /* bit [0] ignored when processing a branch */
/* The following EXC_RETURN mask values are used to evaluate the LR on exception entry */
#define EXC_RETURN_PREFIX (0xFF000000UL) /* bits [31:24] set to indicate an EXC_RETURN value */
#define EXC_RETURN_S (0x00000040UL) /* bit [6] stack used to push registers: 0=Non-secure 1=Secure */
#define EXC_RETURN_DCRS (0x00000020UL) /* bit [5] stacking rules for called registers: 0=skipped 1=saved */
#define EXC_RETURN_FTYPE (0x00000010UL) /* bit [4] allocate stack for floating-point context: 0=done 1=skipped */
#define EXC_RETURN_MODE (0x00000008UL) /* bit [3] processor mode for return: 0=Handler mode 1=Thread mode */
#define EXC_RETURN_SPSEL (0x00000004UL) /* bit [2] stack pointer used to restore context: 0=MSP 1=PSP */
#define EXC_RETURN_ES (0x00000001UL) /* bit [0] security state exception was taken to: 0=Non-secure 1=Secure */
/* Integrity Signature (from ARMv8-M Architecture Reference Manual) for exception context stacking */
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U) /* Value for processors with floating-point extension: */
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125AUL) /* bit [0] SFTC must match LR bit[4] EXC_RETURN_FTYPE */
#else
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125BUL) /* Value for processors without floating-point extension */
#endif
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Get Interrupt Target State
\details Reads the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
\return 1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_GetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Target State
\details Sets the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_SetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] |= ((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Clear Interrupt Target State
\details Clears the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_ClearTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] &= ~((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
__DSB();
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Set Priority Grouping (non-secure)
\details Sets the non-secure priority grouping field when in secure state using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void TZ_NVIC_SetPriorityGrouping_NS(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB_NS->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB_NS->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping (non-secure)
\details Reads the priority grouping field from the non-secure NVIC when in secure state.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriorityGrouping_NS(void)
{
return ((uint32_t)((SCB_NS->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt (non-secure)
\details Enables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_EnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Interrupt Enable status (non-secure)
\details Returns a device specific interrupt enable status from the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetEnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt (non-secure)
\details Disables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_DisableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Pending Interrupt (non-secure)
\details Reads the NVIC pending register in the non-secure NVIC when in secure state and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt (non-secure)
\details Sets the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_SetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt (non-secure)
\details Clears the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_ClearPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt (non-secure)
\details Reads the active register in non-secure NVIC when in secure state and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetActive_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority (non-secure)
\details Sets the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every non-secure processor exception.
*/
__STATIC_INLINE void TZ_NVIC_SetPriority_NS(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority (non-secure)
\details Reads the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority. Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriority_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC_NS->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
#endif /* defined (__ARM_FEATURE_CMSE) &&(__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv8.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
uint32_t mvfr0;
mvfr0 = FPU->MVFR0;
if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x220U)
{
return 2U; /* Double + Single precision FPU */
}
else if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x020U)
{
return 1U; /* Single precision FPU */
}
else
{
return 0U; /* No FPU */
}
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ########################## SAU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SAUFunctions SAU Functions
\brief Functions that configure the SAU.
@{
*/
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable SAU
\details Enables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Enable(void)
{
SAU->CTRL |= (SAU_CTRL_ENABLE_Msk);
}
/**
\brief Disable SAU
\details Disables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Disable(void)
{
SAU->CTRL &= ~(SAU_CTRL_ENABLE_Msk);
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_SAUFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief System Tick Configuration (non-secure)
\details Initializes the non-secure System Timer and its interrupt when in secure state, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>TZ_SysTick_Config_NS</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t TZ_SysTick_Config_NS(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick_NS->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
TZ_NVIC_SetPriority_NS (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick_NS->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick_NS->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM33_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 165,085 | C | 55.711096 | 178 | 0.53301 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/cmsis_version.h | /**************************************************************************//**
* @file cmsis_version.h
* @brief CMSIS Core(M) Version definitions
* @version V5.0.3
* @date 24. June 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 ARM Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CMSIS_VERSION_H
#define __CMSIS_VERSION_H
/* CMSIS Version definitions */
#define __CM_CMSIS_VERSION_MAIN ( 5U) /*!< [31:16] CMSIS Core(M) main version */
#define __CM_CMSIS_VERSION_SUB ( 3U) /*!< [15:0] CMSIS Core(M) sub version */
#define __CM_CMSIS_VERSION ((__CM_CMSIS_VERSION_MAIN << 16U) | \
__CM_CMSIS_VERSION_SUB ) /*!< CMSIS Core(M) version number */
#endif
| 1,676 | C | 40.924999 | 118 | 0.569212 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_armv8mml.h | /**************************************************************************//**
* @file core_armv8mml.h
* @brief CMSIS Armv8-M Mainline Core Peripheral Access Layer Header File
* @version V5.1.0
* @date 12. September 2018
******************************************************************************/
/*
* Copyright (c) 2009-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_ARMV8MML_H_GENERIC
#define __CORE_ARMV8MML_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_ARMv8MML
@{
*/
#include "cmsis_version.h"
/* CMSIS Armv8MML definitions */
#define __ARMv8MML_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __ARMv8MML_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __ARMv8MML_CMSIS_VERSION ((__ARMv8MML_CMSIS_VERSION_MAIN << 16U) | \
__ARMv8MML_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (81U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
For this, __FPU_PRESENT has to be checked prior to making use of FPU specific registers and functions.
*/
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#warning "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_ARMV8MML_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_ARMV8MML_H_DEPENDANT
#define __CORE_ARMV8MML_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __ARMv8MML_REV
#define __ARMv8MML_REV 0x0000U
#warning "__ARMv8MML_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __SAUREGION_PRESENT
#define __SAUREGION_PRESENT 0U
#warning "__SAUREGION_PRESENT not defined in device header file; using default!"
#endif
#ifndef __DSP_PRESENT
#define __DSP_PRESENT 0U
#warning "__DSP_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group ARMv8MML */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core SAU Register
- Core FPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:16; /*!< bit: 0..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:7; /*!< bit: 20..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
#define APSR_GE_Pos 16U /*!< APSR: GE Position */
#define APSR_GE_Msk (0xFUL << APSR_GE_Pos) /*!< APSR: GE Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:7; /*!< bit: 9..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:4; /*!< bit: 20..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t IT:2; /*!< bit: 25..26 saved IT state (read 0) */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_IT_Pos 25U /*!< xPSR: IT Position */
#define xPSR_IT_Msk (3UL << xPSR_IT_Pos) /*!< xPSR: IT Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_GE_Pos 16U /*!< xPSR: GE Position */
#define xPSR_GE_Msk (0xFUL << xPSR_GE_Pos) /*!< xPSR: GE Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack-pointer select */
uint32_t FPCA:1; /*!< bit: 2 Floating-point context active */
uint32_t SFPA:1; /*!< bit: 3 Secure floating-point active */
uint32_t _reserved1:28; /*!< bit: 4..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SFPA_Pos 3U /*!< CONTROL: SFPA Position */
#define CONTROL_SFPA_Msk (1UL << CONTROL_SFPA_Pos) /*!< CONTROL: SFPA Mask */
#define CONTROL_FPCA_Pos 2U /*!< CONTROL: FPCA Position */
#define CONTROL_FPCA_Msk (1UL << CONTROL_FPCA_Pos) /*!< CONTROL: FPCA Mask */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[16U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[16U];
__IOM uint32_t ICER[16U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[16U];
__IOM uint32_t ISPR[16U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[16U];
__IOM uint32_t ICPR[16U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[16U];
__IOM uint32_t IABR[16U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[16U];
__IOM uint32_t ITNS[16U]; /*!< Offset: 0x280 (R/W) Interrupt Non-Secure State Register */
uint32_t RESERVED5[16U];
__IOM uint8_t IPR[496U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED6[580U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHPR[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t ID_PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t ID_DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ID_ADR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t ID_MMFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ID_ISAR[6U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
__IM uint32_t CLIDR; /*!< Offset: 0x078 (R/ ) Cache Level ID register */
__IM uint32_t CTR; /*!< Offset: 0x07C (R/ ) Cache Type register */
__IM uint32_t CCSIDR; /*!< Offset: 0x080 (R/ ) Cache Size ID Register */
__IOM uint32_t CSSELR; /*!< Offset: 0x084 (R/W) Cache Size Selection Register */
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
__IOM uint32_t NSACR; /*!< Offset: 0x08C (R/W) Non-Secure Access Control Register */
uint32_t RESERVED3[92U];
__OM uint32_t STIR; /*!< Offset: 0x200 ( /W) Software Triggered Interrupt Register */
uint32_t RESERVED4[15U];
__IM uint32_t MVFR0; /*!< Offset: 0x240 (R/ ) Media and VFP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x244 (R/ ) Media and VFP Feature Register 1 */
__IM uint32_t MVFR2; /*!< Offset: 0x248 (R/ ) Media and VFP Feature Register 2 */
uint32_t RESERVED5[1U];
__OM uint32_t ICIALLU; /*!< Offset: 0x250 ( /W) I-Cache Invalidate All to PoU */
uint32_t RESERVED6[1U];
__OM uint32_t ICIMVAU; /*!< Offset: 0x258 ( /W) I-Cache Invalidate by MVA to PoU */
__OM uint32_t DCIMVAC; /*!< Offset: 0x25C ( /W) D-Cache Invalidate by MVA to PoC */
__OM uint32_t DCISW; /*!< Offset: 0x260 ( /W) D-Cache Invalidate by Set-way */
__OM uint32_t DCCMVAU; /*!< Offset: 0x264 ( /W) D-Cache Clean by MVA to PoU */
__OM uint32_t DCCMVAC; /*!< Offset: 0x268 ( /W) D-Cache Clean by MVA to PoC */
__OM uint32_t DCCSW; /*!< Offset: 0x26C ( /W) D-Cache Clean by Set-way */
__OM uint32_t DCCIMVAC; /*!< Offset: 0x270 ( /W) D-Cache Clean and Invalidate by MVA to PoC */
__OM uint32_t DCCISW; /*!< Offset: 0x274 ( /W) D-Cache Clean and Invalidate by Set-way */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_PENDNMISET_Pos 31U /*!< SCB ICSR: PENDNMISET Position */
#define SCB_ICSR_PENDNMISET_Msk (1UL << SCB_ICSR_PENDNMISET_Pos) /*!< SCB ICSR: PENDNMISET Mask */
#define SCB_ICSR_NMIPENDSET_Pos SCB_ICSR_PENDNMISET_Pos /*!< SCB ICSR: NMIPENDSET Position, backward compatibility */
#define SCB_ICSR_NMIPENDSET_Msk SCB_ICSR_PENDNMISET_Msk /*!< SCB ICSR: NMIPENDSET Mask, backward compatibility */
#define SCB_ICSR_PENDNMICLR_Pos 30U /*!< SCB ICSR: PENDNMICLR Position */
#define SCB_ICSR_PENDNMICLR_Msk (1UL << SCB_ICSR_PENDNMICLR_Pos) /*!< SCB ICSR: PENDNMICLR Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_STTNS_Pos 24U /*!< SCB ICSR: STTNS Position (Security Extension) */
#define SCB_ICSR_STTNS_Msk (1UL << SCB_ICSR_STTNS_Pos) /*!< SCB ICSR: STTNS Mask (Security Extension) */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIS_Pos 14U /*!< SCB AIRCR: PRIS Position */
#define SCB_AIRCR_PRIS_Msk (1UL << SCB_AIRCR_PRIS_Pos) /*!< SCB AIRCR: PRIS Mask */
#define SCB_AIRCR_BFHFNMINS_Pos 13U /*!< SCB AIRCR: BFHFNMINS Position */
#define SCB_AIRCR_BFHFNMINS_Msk (1UL << SCB_AIRCR_BFHFNMINS_Pos) /*!< SCB AIRCR: BFHFNMINS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQS_Pos 3U /*!< SCB AIRCR: SYSRESETREQS Position */
#define SCB_AIRCR_SYSRESETREQS_Msk (1UL << SCB_AIRCR_SYSRESETREQS_Pos) /*!< SCB AIRCR: SYSRESETREQS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEPS_Pos 3U /*!< SCB SCR: SLEEPDEEPS Position */
#define SCB_SCR_SLEEPDEEPS_Msk (1UL << SCB_SCR_SLEEPDEEPS_Pos) /*!< SCB SCR: SLEEPDEEPS Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_BP_Pos 18U /*!< SCB CCR: BP Position */
#define SCB_CCR_BP_Msk (1UL << SCB_CCR_BP_Pos) /*!< SCB CCR: BP Mask */
#define SCB_CCR_IC_Pos 17U /*!< SCB CCR: IC Position */
#define SCB_CCR_IC_Msk (1UL << SCB_CCR_IC_Pos) /*!< SCB CCR: IC Mask */
#define SCB_CCR_DC_Pos 16U /*!< SCB CCR: DC Position */
#define SCB_CCR_DC_Msk (1UL << SCB_CCR_DC_Pos) /*!< SCB CCR: DC Mask */
#define SCB_CCR_STKOFHFNMIGN_Pos 10U /*!< SCB CCR: STKOFHFNMIGN Position */
#define SCB_CCR_STKOFHFNMIGN_Msk (1UL << SCB_CCR_STKOFHFNMIGN_Pos) /*!< SCB CCR: STKOFHFNMIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_HARDFAULTPENDED_Pos 21U /*!< SCB SHCSR: HARDFAULTPENDED Position */
#define SCB_SHCSR_HARDFAULTPENDED_Msk (1UL << SCB_SHCSR_HARDFAULTPENDED_Pos) /*!< SCB SHCSR: HARDFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTPENDED_Pos 20U /*!< SCB SHCSR: SECUREFAULTPENDED Position */
#define SCB_SHCSR_SECUREFAULTPENDED_Msk (1UL << SCB_SHCSR_SECUREFAULTPENDED_Pos) /*!< SCB SHCSR: SECUREFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTENA_Pos 19U /*!< SCB SHCSR: SECUREFAULTENA Position */
#define SCB_SHCSR_SECUREFAULTENA_Msk (1UL << SCB_SHCSR_SECUREFAULTENA_Pos) /*!< SCB SHCSR: SECUREFAULTENA Mask */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_NMIACT_Pos 5U /*!< SCB SHCSR: NMIACT Position */
#define SCB_SHCSR_NMIACT_Msk (1UL << SCB_SHCSR_NMIACT_Pos) /*!< SCB SHCSR: NMIACT Mask */
#define SCB_SHCSR_SECUREFAULTACT_Pos 4U /*!< SCB SHCSR: SECUREFAULTACT Position */
#define SCB_SHCSR_SECUREFAULTACT_Msk (1UL << SCB_SHCSR_SECUREFAULTACT_Pos) /*!< SCB SHCSR: SECUREFAULTACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_HARDFAULTACT_Pos 2U /*!< SCB SHCSR: HARDFAULTACT Position */
#define SCB_SHCSR_HARDFAULTACT_Msk (1UL << SCB_SHCSR_HARDFAULTACT_Pos) /*!< SCB SHCSR: HARDFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MLSPERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 5U) /*!< SCB CFSR (MMFSR): MLSPERR Position */
#define SCB_CFSR_MLSPERR_Msk (1UL << SCB_CFSR_MLSPERR_Pos) /*!< SCB CFSR (MMFSR): MLSPERR Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_LSPERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 5U) /*!< SCB CFSR (BFSR): LSPERR Position */
#define SCB_CFSR_LSPERR_Msk (1UL << SCB_CFSR_LSPERR_Pos) /*!< SCB CFSR (BFSR): LSPERR Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_STKOF_Pos (SCB_CFSR_USGFAULTSR_Pos + 4U) /*!< SCB CFSR (UFSR): STKOF Position */
#define SCB_CFSR_STKOF_Msk (1UL << SCB_CFSR_STKOF_Pos) /*!< SCB CFSR (UFSR): STKOF Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/* SCB Non-Secure Access Control Register Definitions */
#define SCB_NSACR_CP11_Pos 11U /*!< SCB NSACR: CP11 Position */
#define SCB_NSACR_CP11_Msk (1UL << SCB_NSACR_CP11_Pos) /*!< SCB NSACR: CP11 Mask */
#define SCB_NSACR_CP10_Pos 10U /*!< SCB NSACR: CP10 Position */
#define SCB_NSACR_CP10_Msk (1UL << SCB_NSACR_CP10_Pos) /*!< SCB NSACR: CP10 Mask */
#define SCB_NSACR_CPn_Pos 0U /*!< SCB NSACR: CPn Position */
#define SCB_NSACR_CPn_Msk (1UL /*<< SCB_NSACR_CPn_Pos*/) /*!< SCB NSACR: CPn Mask */
/* SCB Cache Level ID Register Definitions */
#define SCB_CLIDR_LOUU_Pos 27U /*!< SCB CLIDR: LoUU Position */
#define SCB_CLIDR_LOUU_Msk (7UL << SCB_CLIDR_LOUU_Pos) /*!< SCB CLIDR: LoUU Mask */
#define SCB_CLIDR_LOC_Pos 24U /*!< SCB CLIDR: LoC Position */
#define SCB_CLIDR_LOC_Msk (7UL << SCB_CLIDR_LOC_Pos) /*!< SCB CLIDR: LoC Mask */
/* SCB Cache Type Register Definitions */
#define SCB_CTR_FORMAT_Pos 29U /*!< SCB CTR: Format Position */
#define SCB_CTR_FORMAT_Msk (7UL << SCB_CTR_FORMAT_Pos) /*!< SCB CTR: Format Mask */
#define SCB_CTR_CWG_Pos 24U /*!< SCB CTR: CWG Position */
#define SCB_CTR_CWG_Msk (0xFUL << SCB_CTR_CWG_Pos) /*!< SCB CTR: CWG Mask */
#define SCB_CTR_ERG_Pos 20U /*!< SCB CTR: ERG Position */
#define SCB_CTR_ERG_Msk (0xFUL << SCB_CTR_ERG_Pos) /*!< SCB CTR: ERG Mask */
#define SCB_CTR_DMINLINE_Pos 16U /*!< SCB CTR: DminLine Position */
#define SCB_CTR_DMINLINE_Msk (0xFUL << SCB_CTR_DMINLINE_Pos) /*!< SCB CTR: DminLine Mask */
#define SCB_CTR_IMINLINE_Pos 0U /*!< SCB CTR: ImInLine Position */
#define SCB_CTR_IMINLINE_Msk (0xFUL /*<< SCB_CTR_IMINLINE_Pos*/) /*!< SCB CTR: ImInLine Mask */
/* SCB Cache Size ID Register Definitions */
#define SCB_CCSIDR_WT_Pos 31U /*!< SCB CCSIDR: WT Position */
#define SCB_CCSIDR_WT_Msk (1UL << SCB_CCSIDR_WT_Pos) /*!< SCB CCSIDR: WT Mask */
#define SCB_CCSIDR_WB_Pos 30U /*!< SCB CCSIDR: WB Position */
#define SCB_CCSIDR_WB_Msk (1UL << SCB_CCSIDR_WB_Pos) /*!< SCB CCSIDR: WB Mask */
#define SCB_CCSIDR_RA_Pos 29U /*!< SCB CCSIDR: RA Position */
#define SCB_CCSIDR_RA_Msk (1UL << SCB_CCSIDR_RA_Pos) /*!< SCB CCSIDR: RA Mask */
#define SCB_CCSIDR_WA_Pos 28U /*!< SCB CCSIDR: WA Position */
#define SCB_CCSIDR_WA_Msk (1UL << SCB_CCSIDR_WA_Pos) /*!< SCB CCSIDR: WA Mask */
#define SCB_CCSIDR_NUMSETS_Pos 13U /*!< SCB CCSIDR: NumSets Position */
#define SCB_CCSIDR_NUMSETS_Msk (0x7FFFUL << SCB_CCSIDR_NUMSETS_Pos) /*!< SCB CCSIDR: NumSets Mask */
#define SCB_CCSIDR_ASSOCIATIVITY_Pos 3U /*!< SCB CCSIDR: Associativity Position */
#define SCB_CCSIDR_ASSOCIATIVITY_Msk (0x3FFUL << SCB_CCSIDR_ASSOCIATIVITY_Pos) /*!< SCB CCSIDR: Associativity Mask */
#define SCB_CCSIDR_LINESIZE_Pos 0U /*!< SCB CCSIDR: LineSize Position */
#define SCB_CCSIDR_LINESIZE_Msk (7UL /*<< SCB_CCSIDR_LINESIZE_Pos*/) /*!< SCB CCSIDR: LineSize Mask */
/* SCB Cache Size Selection Register Definitions */
#define SCB_CSSELR_LEVEL_Pos 1U /*!< SCB CSSELR: Level Position */
#define SCB_CSSELR_LEVEL_Msk (7UL << SCB_CSSELR_LEVEL_Pos) /*!< SCB CSSELR: Level Mask */
#define SCB_CSSELR_IND_Pos 0U /*!< SCB CSSELR: InD Position */
#define SCB_CSSELR_IND_Msk (1UL /*<< SCB_CSSELR_IND_Pos*/) /*!< SCB CSSELR: InD Mask */
/* SCB Software Triggered Interrupt Register Definitions */
#define SCB_STIR_INTID_Pos 0U /*!< SCB STIR: INTID Position */
#define SCB_STIR_INTID_Msk (0x1FFUL /*<< SCB_STIR_INTID_Pos*/) /*!< SCB STIR: INTID Mask */
/* SCB D-Cache Invalidate by Set-way Register Definitions */
#define SCB_DCISW_WAY_Pos 30U /*!< SCB DCISW: Way Position */
#define SCB_DCISW_WAY_Msk (3UL << SCB_DCISW_WAY_Pos) /*!< SCB DCISW: Way Mask */
#define SCB_DCISW_SET_Pos 5U /*!< SCB DCISW: Set Position */
#define SCB_DCISW_SET_Msk (0x1FFUL << SCB_DCISW_SET_Pos) /*!< SCB DCISW: Set Mask */
/* SCB D-Cache Clean by Set-way Register Definitions */
#define SCB_DCCSW_WAY_Pos 30U /*!< SCB DCCSW: Way Position */
#define SCB_DCCSW_WAY_Msk (3UL << SCB_DCCSW_WAY_Pos) /*!< SCB DCCSW: Way Mask */
#define SCB_DCCSW_SET_Pos 5U /*!< SCB DCCSW: Set Position */
#define SCB_DCCSW_SET_Msk (0x1FFUL << SCB_DCCSW_SET_Pos) /*!< SCB DCCSW: Set Mask */
/* SCB D-Cache Clean and Invalidate by Set-way Register Definitions */
#define SCB_DCCISW_WAY_Pos 30U /*!< SCB DCCISW: Way Position */
#define SCB_DCCISW_WAY_Msk (3UL << SCB_DCCISW_WAY_Pos) /*!< SCB DCCISW: Way Mask */
#define SCB_DCCISW_SET_Pos 5U /*!< SCB DCCISW: Set Position */
#define SCB_DCCISW_SET_Msk (0x1FFUL << SCB_DCCISW_SET_Pos) /*!< SCB DCCISW: Set Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
__IOM uint32_t CPPWR; /*!< Offset: 0x00C (R/W) Coprocessor Power Control Register */
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[32U];
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) ITM Device Architecture Register */
uint32_t RESERVED6[4U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Stimulus Port Register Definitions */
#define ITM_STIM_DISABLED_Pos 1U /*!< ITM STIM: DISABLED Position */
#define ITM_STIM_DISABLED_Msk (0x1UL << ITM_STIM_DISABLED_Pos) /*!< ITM STIM: DISABLED Mask */
#define ITM_STIM_FIFOREADY_Pos 0U /*!< ITM STIM: FIFOREADY Position */
#define ITM_STIM_FIFOREADY_Msk (0x1UL /*<< ITM_STIM_FIFOREADY_Pos*/) /*!< ITM STIM: FIFOREADY Mask */
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TRACEBUSID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TRACEBUSID_Msk (0x7FUL << ITM_TCR_TRACEBUSID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPRESCALE_Pos 8U /*!< ITM TCR: TSPRESCALE Position */
#define ITM_TCR_TSPRESCALE_Msk (3UL << ITM_TCR_TSPRESCALE_Pos) /*!< ITM TCR: TSPRESCALE Mask */
#define ITM_TCR_STALLENA_Pos 5U /*!< ITM TCR: STALLENA Position */
#define ITM_TCR_STALLENA_Msk (1UL << ITM_TCR_STALLENA_Pos) /*!< ITM TCR: STALLENA Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
uint32_t RESERVED1[1U];
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
uint32_t RESERVED3[1U];
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED4[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
uint32_t RESERVED5[1U];
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED6[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
uint32_t RESERVED7[1U];
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
uint32_t RESERVED8[1U];
__IOM uint32_t COMP4; /*!< Offset: 0x060 (R/W) Comparator Register 4 */
uint32_t RESERVED9[1U];
__IOM uint32_t FUNCTION4; /*!< Offset: 0x068 (R/W) Function Register 4 */
uint32_t RESERVED10[1U];
__IOM uint32_t COMP5; /*!< Offset: 0x070 (R/W) Comparator Register 5 */
uint32_t RESERVED11[1U];
__IOM uint32_t FUNCTION5; /*!< Offset: 0x078 (R/W) Function Register 5 */
uint32_t RESERVED12[1U];
__IOM uint32_t COMP6; /*!< Offset: 0x080 (R/W) Comparator Register 6 */
uint32_t RESERVED13[1U];
__IOM uint32_t FUNCTION6; /*!< Offset: 0x088 (R/W) Function Register 6 */
uint32_t RESERVED14[1U];
__IOM uint32_t COMP7; /*!< Offset: 0x090 (R/W) Comparator Register 7 */
uint32_t RESERVED15[1U];
__IOM uint32_t FUNCTION7; /*!< Offset: 0x098 (R/W) Function Register 7 */
uint32_t RESERVED16[1U];
__IOM uint32_t COMP8; /*!< Offset: 0x0A0 (R/W) Comparator Register 8 */
uint32_t RESERVED17[1U];
__IOM uint32_t FUNCTION8; /*!< Offset: 0x0A8 (R/W) Function Register 8 */
uint32_t RESERVED18[1U];
__IOM uint32_t COMP9; /*!< Offset: 0x0B0 (R/W) Comparator Register 9 */
uint32_t RESERVED19[1U];
__IOM uint32_t FUNCTION9; /*!< Offset: 0x0B8 (R/W) Function Register 9 */
uint32_t RESERVED20[1U];
__IOM uint32_t COMP10; /*!< Offset: 0x0C0 (R/W) Comparator Register 10 */
uint32_t RESERVED21[1U];
__IOM uint32_t FUNCTION10; /*!< Offset: 0x0C8 (R/W) Function Register 10 */
uint32_t RESERVED22[1U];
__IOM uint32_t COMP11; /*!< Offset: 0x0D0 (R/W) Comparator Register 11 */
uint32_t RESERVED23[1U];
__IOM uint32_t FUNCTION11; /*!< Offset: 0x0D8 (R/W) Function Register 11 */
uint32_t RESERVED24[1U];
__IOM uint32_t COMP12; /*!< Offset: 0x0E0 (R/W) Comparator Register 12 */
uint32_t RESERVED25[1U];
__IOM uint32_t FUNCTION12; /*!< Offset: 0x0E8 (R/W) Function Register 12 */
uint32_t RESERVED26[1U];
__IOM uint32_t COMP13; /*!< Offset: 0x0F0 (R/W) Comparator Register 13 */
uint32_t RESERVED27[1U];
__IOM uint32_t FUNCTION13; /*!< Offset: 0x0F8 (R/W) Function Register 13 */
uint32_t RESERVED28[1U];
__IOM uint32_t COMP14; /*!< Offset: 0x100 (R/W) Comparator Register 14 */
uint32_t RESERVED29[1U];
__IOM uint32_t FUNCTION14; /*!< Offset: 0x108 (R/W) Function Register 14 */
uint32_t RESERVED30[1U];
__IOM uint32_t COMP15; /*!< Offset: 0x110 (R/W) Comparator Register 15 */
uint32_t RESERVED31[1U];
__IOM uint32_t FUNCTION15; /*!< Offset: 0x118 (R/W) Function Register 15 */
uint32_t RESERVED32[934U];
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R ) Lock Status Register */
uint32_t RESERVED33[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) Device Architecture Register */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCDISS_Pos 23U /*!< DWT CTRL: CYCDISS Position */
#define DWT_CTRL_CYCDISS_Msk (0x1UL << DWT_CTRL_CYCDISS_Pos) /*!< DWT CTRL: CYCDISS Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_ID_Pos 27U /*!< DWT FUNCTION: ID Position */
#define DWT_FUNCTION_ID_Msk (0x1FUL << DWT_FUNCTION_ID_Pos) /*!< DWT FUNCTION: ID Mask */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_ACTION_Pos 4U /*!< DWT FUNCTION: ACTION Position */
#define DWT_FUNCTION_ACTION_Msk (0x1UL << DWT_FUNCTION_ACTION_Pos) /*!< DWT FUNCTION: ACTION Mask */
#define DWT_FUNCTION_MATCH_Pos 0U /*!< DWT FUNCTION: MATCH Position */
#define DWT_FUNCTION_MATCH_Msk (0xFUL /*<< DWT_FUNCTION_MATCH_Pos*/) /*!< DWT FUNCTION: MATCH Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Sizes Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Sizes Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IOM uint32_t PSCR; /*!< Offset: 0x308 (R/W) Periodic Synchronization Control Register */
uint32_t RESERVED3[809U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) Software Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) Software Lock Status Register */
uint32_t RESERVED4[4U];
__IM uint32_t TYPE; /*!< Offset: 0xFC8 (R/ ) Device Identifier Register */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) Device Type Register */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_SWOSCALER_Pos 0U /*!< TPI ACPR: SWOSCALER Position */
#define TPI_ACPR_SWOSCALER_Msk (0xFFFFUL /*<< TPI_ACPR_SWOSCALER_Pos*/) /*!< TPI ACPR: SWOSCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_FOnMan_Pos 6U /*!< TPI FFCR: FOnMan Position */
#define TPI_FFCR_FOnMan_Msk (0x1UL << TPI_FFCR_FOnMan_Pos) /*!< TPI FFCR: FOnMan Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI Periodic Synchronization Control Register Definitions */
#define TPI_PSCR_PSCount_Pos 0U /*!< TPI PSCR: PSCount Position */
#define TPI_PSCR_PSCount_Msk (0x1FUL /*<< TPI_PSCR_PSCount_Pos*/) /*!< TPI PSCR: TPSCount Mask */
/* TPI Software Lock Status Register Definitions */
#define TPI_LSR_nTT_Pos 1U /*!< TPI LSR: Not thirty-two bit. Position */
#define TPI_LSR_nTT_Msk (0x1UL << TPI_LSR_nTT_Pos) /*!< TPI LSR: Not thirty-two bit. Mask */
#define TPI_LSR_SLK_Pos 1U /*!< TPI LSR: Software Lock status Position */
#define TPI_LSR_SLK_Msk (0x1UL << TPI_LSR_SLK_Pos) /*!< TPI LSR: Software Lock status Mask */
#define TPI_LSR_SLI_Pos 0U /*!< TPI LSR: Software Lock implemented Position */
#define TPI_LSR_SLI_Msk (0x1UL /*<< TPI_LSR_SLI_Pos*/) /*!< TPI LSR: Software Lock implemented Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_FIFOSZ_Pos 6U /*!< TPI DEVID: FIFO depth Position */
#define TPI_DEVID_FIFOSZ_Msk (0x7UL << TPI_DEVID_FIFOSZ_Pos) /*!< TPI DEVID: FIFO depth Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) MPU Region Limit Address Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Region Base Address Register Alias 1 */
__IOM uint32_t RLAR_A1; /*!< Offset: 0x018 (R/W) MPU Region Limit Address Register Alias 1 */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Region Base Address Register Alias 2 */
__IOM uint32_t RLAR_A2; /*!< Offset: 0x020 (R/W) MPU Region Limit Address Register Alias 2 */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Region Base Address Register Alias 3 */
__IOM uint32_t RLAR_A3; /*!< Offset: 0x028 (R/W) MPU Region Limit Address Register Alias 3 */
uint32_t RESERVED0[1];
union {
__IOM uint32_t MAIR[2];
struct {
__IOM uint32_t MAIR0; /*!< Offset: 0x030 (R/W) MPU Memory Attribute Indirection Register 0 */
__IOM uint32_t MAIR1; /*!< Offset: 0x034 (R/W) MPU Memory Attribute Indirection Register 1 */
};
};
} MPU_Type;
#define MPU_TYPE_RALIASES 4U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_BASE_Pos 5U /*!< MPU RBAR: BASE Position */
#define MPU_RBAR_BASE_Msk (0x7FFFFFFUL << MPU_RBAR_BASE_Pos) /*!< MPU RBAR: BASE Mask */
#define MPU_RBAR_SH_Pos 3U /*!< MPU RBAR: SH Position */
#define MPU_RBAR_SH_Msk (0x3UL << MPU_RBAR_SH_Pos) /*!< MPU RBAR: SH Mask */
#define MPU_RBAR_AP_Pos 1U /*!< MPU RBAR: AP Position */
#define MPU_RBAR_AP_Msk (0x3UL << MPU_RBAR_AP_Pos) /*!< MPU RBAR: AP Mask */
#define MPU_RBAR_XN_Pos 0U /*!< MPU RBAR: XN Position */
#define MPU_RBAR_XN_Msk (01UL /*<< MPU_RBAR_XN_Pos*/) /*!< MPU RBAR: XN Mask */
/* MPU Region Limit Address Register Definitions */
#define MPU_RLAR_LIMIT_Pos 5U /*!< MPU RLAR: LIMIT Position */
#define MPU_RLAR_LIMIT_Msk (0x7FFFFFFUL << MPU_RLAR_LIMIT_Pos) /*!< MPU RLAR: LIMIT Mask */
#define MPU_RLAR_AttrIndx_Pos 1U /*!< MPU RLAR: AttrIndx Position */
#define MPU_RLAR_AttrIndx_Msk (0x7UL << MPU_RLAR_AttrIndx_Pos) /*!< MPU RLAR: AttrIndx Mask */
#define MPU_RLAR_EN_Pos 0U /*!< MPU RLAR: Region enable bit Position */
#define MPU_RLAR_EN_Msk (1UL /*<< MPU_RLAR_EN_Pos*/) /*!< MPU RLAR: Region enable bit Disable Mask */
/* MPU Memory Attribute Indirection Register 0 Definitions */
#define MPU_MAIR0_Attr3_Pos 24U /*!< MPU MAIR0: Attr3 Position */
#define MPU_MAIR0_Attr3_Msk (0xFFUL << MPU_MAIR0_Attr3_Pos) /*!< MPU MAIR0: Attr3 Mask */
#define MPU_MAIR0_Attr2_Pos 16U /*!< MPU MAIR0: Attr2 Position */
#define MPU_MAIR0_Attr2_Msk (0xFFUL << MPU_MAIR0_Attr2_Pos) /*!< MPU MAIR0: Attr2 Mask */
#define MPU_MAIR0_Attr1_Pos 8U /*!< MPU MAIR0: Attr1 Position */
#define MPU_MAIR0_Attr1_Msk (0xFFUL << MPU_MAIR0_Attr1_Pos) /*!< MPU MAIR0: Attr1 Mask */
#define MPU_MAIR0_Attr0_Pos 0U /*!< MPU MAIR0: Attr0 Position */
#define MPU_MAIR0_Attr0_Msk (0xFFUL /*<< MPU_MAIR0_Attr0_Pos*/) /*!< MPU MAIR0: Attr0 Mask */
/* MPU Memory Attribute Indirection Register 1 Definitions */
#define MPU_MAIR1_Attr7_Pos 24U /*!< MPU MAIR1: Attr7 Position */
#define MPU_MAIR1_Attr7_Msk (0xFFUL << MPU_MAIR1_Attr7_Pos) /*!< MPU MAIR1: Attr7 Mask */
#define MPU_MAIR1_Attr6_Pos 16U /*!< MPU MAIR1: Attr6 Position */
#define MPU_MAIR1_Attr6_Msk (0xFFUL << MPU_MAIR1_Attr6_Pos) /*!< MPU MAIR1: Attr6 Mask */
#define MPU_MAIR1_Attr5_Pos 8U /*!< MPU MAIR1: Attr5 Position */
#define MPU_MAIR1_Attr5_Msk (0xFFUL << MPU_MAIR1_Attr5_Pos) /*!< MPU MAIR1: Attr5 Mask */
#define MPU_MAIR1_Attr4_Pos 0U /*!< MPU MAIR1: Attr4 Position */
#define MPU_MAIR1_Attr4_Msk (0xFFUL /*<< MPU_MAIR1_Attr4_Pos*/) /*!< MPU MAIR1: Attr4 Mask */
/*@} end of group CMSIS_MPU */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SAU Security Attribution Unit (SAU)
\brief Type definitions for the Security Attribution Unit (SAU)
@{
*/
/**
\brief Structure type to access the Security Attribution Unit (SAU).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SAU Control Register */
__IM uint32_t TYPE; /*!< Offset: 0x004 (R/ ) SAU Type Register */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) SAU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) SAU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) SAU Region Limit Address Register */
#else
uint32_t RESERVED0[3];
#endif
__IOM uint32_t SFSR; /*!< Offset: 0x014 (R/W) Secure Fault Status Register */
__IOM uint32_t SFAR; /*!< Offset: 0x018 (R/W) Secure Fault Address Register */
} SAU_Type;
/* SAU Control Register Definitions */
#define SAU_CTRL_ALLNS_Pos 1U /*!< SAU CTRL: ALLNS Position */
#define SAU_CTRL_ALLNS_Msk (1UL << SAU_CTRL_ALLNS_Pos) /*!< SAU CTRL: ALLNS Mask */
#define SAU_CTRL_ENABLE_Pos 0U /*!< SAU CTRL: ENABLE Position */
#define SAU_CTRL_ENABLE_Msk (1UL /*<< SAU_CTRL_ENABLE_Pos*/) /*!< SAU CTRL: ENABLE Mask */
/* SAU Type Register Definitions */
#define SAU_TYPE_SREGION_Pos 0U /*!< SAU TYPE: SREGION Position */
#define SAU_TYPE_SREGION_Msk (0xFFUL /*<< SAU_TYPE_SREGION_Pos*/) /*!< SAU TYPE: SREGION Mask */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
/* SAU Region Number Register Definitions */
#define SAU_RNR_REGION_Pos 0U /*!< SAU RNR: REGION Position */
#define SAU_RNR_REGION_Msk (0xFFUL /*<< SAU_RNR_REGION_Pos*/) /*!< SAU RNR: REGION Mask */
/* SAU Region Base Address Register Definitions */
#define SAU_RBAR_BADDR_Pos 5U /*!< SAU RBAR: BADDR Position */
#define SAU_RBAR_BADDR_Msk (0x7FFFFFFUL << SAU_RBAR_BADDR_Pos) /*!< SAU RBAR: BADDR Mask */
/* SAU Region Limit Address Register Definitions */
#define SAU_RLAR_LADDR_Pos 5U /*!< SAU RLAR: LADDR Position */
#define SAU_RLAR_LADDR_Msk (0x7FFFFFFUL << SAU_RLAR_LADDR_Pos) /*!< SAU RLAR: LADDR Mask */
#define SAU_RLAR_NSC_Pos 1U /*!< SAU RLAR: NSC Position */
#define SAU_RLAR_NSC_Msk (1UL << SAU_RLAR_NSC_Pos) /*!< SAU RLAR: NSC Mask */
#define SAU_RLAR_ENABLE_Pos 0U /*!< SAU RLAR: ENABLE Position */
#define SAU_RLAR_ENABLE_Msk (1UL /*<< SAU_RLAR_ENABLE_Pos*/) /*!< SAU RLAR: ENABLE Mask */
#endif /* defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U) */
/* Secure Fault Status Register Definitions */
#define SAU_SFSR_LSERR_Pos 7U /*!< SAU SFSR: LSERR Position */
#define SAU_SFSR_LSERR_Msk (1UL << SAU_SFSR_LSERR_Pos) /*!< SAU SFSR: LSERR Mask */
#define SAU_SFSR_SFARVALID_Pos 6U /*!< SAU SFSR: SFARVALID Position */
#define SAU_SFSR_SFARVALID_Msk (1UL << SAU_SFSR_SFARVALID_Pos) /*!< SAU SFSR: SFARVALID Mask */
#define SAU_SFSR_LSPERR_Pos 5U /*!< SAU SFSR: LSPERR Position */
#define SAU_SFSR_LSPERR_Msk (1UL << SAU_SFSR_LSPERR_Pos) /*!< SAU SFSR: LSPERR Mask */
#define SAU_SFSR_INVTRAN_Pos 4U /*!< SAU SFSR: INVTRAN Position */
#define SAU_SFSR_INVTRAN_Msk (1UL << SAU_SFSR_INVTRAN_Pos) /*!< SAU SFSR: INVTRAN Mask */
#define SAU_SFSR_AUVIOL_Pos 3U /*!< SAU SFSR: AUVIOL Position */
#define SAU_SFSR_AUVIOL_Msk (1UL << SAU_SFSR_AUVIOL_Pos) /*!< SAU SFSR: AUVIOL Mask */
#define SAU_SFSR_INVER_Pos 2U /*!< SAU SFSR: INVER Position */
#define SAU_SFSR_INVER_Msk (1UL << SAU_SFSR_INVER_Pos) /*!< SAU SFSR: INVER Mask */
#define SAU_SFSR_INVIS_Pos 1U /*!< SAU SFSR: INVIS Position */
#define SAU_SFSR_INVIS_Msk (1UL << SAU_SFSR_INVIS_Pos) /*!< SAU SFSR: INVIS Mask */
#define SAU_SFSR_INVEP_Pos 0U /*!< SAU SFSR: INVEP Position */
#define SAU_SFSR_INVEP_Msk (1UL /*<< SAU_SFSR_INVEP_Pos*/) /*!< SAU SFSR: INVEP Mask */
/*@} end of group CMSIS_SAU */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_FPU Floating Point Unit (FPU)
\brief Type definitions for the Floating Point Unit (FPU)
@{
*/
/**
\brief Structure type to access the Floating Point Unit (FPU).
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IOM uint32_t FPCCR; /*!< Offset: 0x004 (R/W) Floating-Point Context Control Register */
__IOM uint32_t FPCAR; /*!< Offset: 0x008 (R/W) Floating-Point Context Address Register */
__IOM uint32_t FPDSCR; /*!< Offset: 0x00C (R/W) Floating-Point Default Status Control Register */
__IM uint32_t MVFR0; /*!< Offset: 0x010 (R/ ) Media and FP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x014 (R/ ) Media and FP Feature Register 1 */
} FPU_Type;
/* Floating-Point Context Control Register Definitions */
#define FPU_FPCCR_ASPEN_Pos 31U /*!< FPCCR: ASPEN bit Position */
#define FPU_FPCCR_ASPEN_Msk (1UL << FPU_FPCCR_ASPEN_Pos) /*!< FPCCR: ASPEN bit Mask */
#define FPU_FPCCR_LSPEN_Pos 30U /*!< FPCCR: LSPEN Position */
#define FPU_FPCCR_LSPEN_Msk (1UL << FPU_FPCCR_LSPEN_Pos) /*!< FPCCR: LSPEN bit Mask */
#define FPU_FPCCR_LSPENS_Pos 29U /*!< FPCCR: LSPENS Position */
#define FPU_FPCCR_LSPENS_Msk (1UL << FPU_FPCCR_LSPENS_Pos) /*!< FPCCR: LSPENS bit Mask */
#define FPU_FPCCR_CLRONRET_Pos 28U /*!< FPCCR: CLRONRET Position */
#define FPU_FPCCR_CLRONRET_Msk (1UL << FPU_FPCCR_CLRONRET_Pos) /*!< FPCCR: CLRONRET bit Mask */
#define FPU_FPCCR_CLRONRETS_Pos 27U /*!< FPCCR: CLRONRETS Position */
#define FPU_FPCCR_CLRONRETS_Msk (1UL << FPU_FPCCR_CLRONRETS_Pos) /*!< FPCCR: CLRONRETS bit Mask */
#define FPU_FPCCR_TS_Pos 26U /*!< FPCCR: TS Position */
#define FPU_FPCCR_TS_Msk (1UL << FPU_FPCCR_TS_Pos) /*!< FPCCR: TS bit Mask */
#define FPU_FPCCR_UFRDY_Pos 10U /*!< FPCCR: UFRDY Position */
#define FPU_FPCCR_UFRDY_Msk (1UL << FPU_FPCCR_UFRDY_Pos) /*!< FPCCR: UFRDY bit Mask */
#define FPU_FPCCR_SPLIMVIOL_Pos 9U /*!< FPCCR: SPLIMVIOL Position */
#define FPU_FPCCR_SPLIMVIOL_Msk (1UL << FPU_FPCCR_SPLIMVIOL_Pos) /*!< FPCCR: SPLIMVIOL bit Mask */
#define FPU_FPCCR_MONRDY_Pos 8U /*!< FPCCR: MONRDY Position */
#define FPU_FPCCR_MONRDY_Msk (1UL << FPU_FPCCR_MONRDY_Pos) /*!< FPCCR: MONRDY bit Mask */
#define FPU_FPCCR_SFRDY_Pos 7U /*!< FPCCR: SFRDY Position */
#define FPU_FPCCR_SFRDY_Msk (1UL << FPU_FPCCR_SFRDY_Pos) /*!< FPCCR: SFRDY bit Mask */
#define FPU_FPCCR_BFRDY_Pos 6U /*!< FPCCR: BFRDY Position */
#define FPU_FPCCR_BFRDY_Msk (1UL << FPU_FPCCR_BFRDY_Pos) /*!< FPCCR: BFRDY bit Mask */
#define FPU_FPCCR_MMRDY_Pos 5U /*!< FPCCR: MMRDY Position */
#define FPU_FPCCR_MMRDY_Msk (1UL << FPU_FPCCR_MMRDY_Pos) /*!< FPCCR: MMRDY bit Mask */
#define FPU_FPCCR_HFRDY_Pos 4U /*!< FPCCR: HFRDY Position */
#define FPU_FPCCR_HFRDY_Msk (1UL << FPU_FPCCR_HFRDY_Pos) /*!< FPCCR: HFRDY bit Mask */
#define FPU_FPCCR_THREAD_Pos 3U /*!< FPCCR: processor mode bit Position */
#define FPU_FPCCR_THREAD_Msk (1UL << FPU_FPCCR_THREAD_Pos) /*!< FPCCR: processor mode active bit Mask */
#define FPU_FPCCR_S_Pos 2U /*!< FPCCR: Security status of the FP context bit Position */
#define FPU_FPCCR_S_Msk (1UL << FPU_FPCCR_S_Pos) /*!< FPCCR: Security status of the FP context bit Mask */
#define FPU_FPCCR_USER_Pos 1U /*!< FPCCR: privilege level bit Position */
#define FPU_FPCCR_USER_Msk (1UL << FPU_FPCCR_USER_Pos) /*!< FPCCR: privilege level bit Mask */
#define FPU_FPCCR_LSPACT_Pos 0U /*!< FPCCR: Lazy state preservation active bit Position */
#define FPU_FPCCR_LSPACT_Msk (1UL /*<< FPU_FPCCR_LSPACT_Pos*/) /*!< FPCCR: Lazy state preservation active bit Mask */
/* Floating-Point Context Address Register Definitions */
#define FPU_FPCAR_ADDRESS_Pos 3U /*!< FPCAR: ADDRESS bit Position */
#define FPU_FPCAR_ADDRESS_Msk (0x1FFFFFFFUL << FPU_FPCAR_ADDRESS_Pos) /*!< FPCAR: ADDRESS bit Mask */
/* Floating-Point Default Status Control Register Definitions */
#define FPU_FPDSCR_AHP_Pos 26U /*!< FPDSCR: AHP bit Position */
#define FPU_FPDSCR_AHP_Msk (1UL << FPU_FPDSCR_AHP_Pos) /*!< FPDSCR: AHP bit Mask */
#define FPU_FPDSCR_DN_Pos 25U /*!< FPDSCR: DN bit Position */
#define FPU_FPDSCR_DN_Msk (1UL << FPU_FPDSCR_DN_Pos) /*!< FPDSCR: DN bit Mask */
#define FPU_FPDSCR_FZ_Pos 24U /*!< FPDSCR: FZ bit Position */
#define FPU_FPDSCR_FZ_Msk (1UL << FPU_FPDSCR_FZ_Pos) /*!< FPDSCR: FZ bit Mask */
#define FPU_FPDSCR_RMode_Pos 22U /*!< FPDSCR: RMode bit Position */
#define FPU_FPDSCR_RMode_Msk (3UL << FPU_FPDSCR_RMode_Pos) /*!< FPDSCR: RMode bit Mask */
/* Media and FP Feature Register 0 Definitions */
#define FPU_MVFR0_FP_rounding_modes_Pos 28U /*!< MVFR0: FP rounding modes bits Position */
#define FPU_MVFR0_FP_rounding_modes_Msk (0xFUL << FPU_MVFR0_FP_rounding_modes_Pos) /*!< MVFR0: FP rounding modes bits Mask */
#define FPU_MVFR0_Short_vectors_Pos 24U /*!< MVFR0: Short vectors bits Position */
#define FPU_MVFR0_Short_vectors_Msk (0xFUL << FPU_MVFR0_Short_vectors_Pos) /*!< MVFR0: Short vectors bits Mask */
#define FPU_MVFR0_Square_root_Pos 20U /*!< MVFR0: Square root bits Position */
#define FPU_MVFR0_Square_root_Msk (0xFUL << FPU_MVFR0_Square_root_Pos) /*!< MVFR0: Square root bits Mask */
#define FPU_MVFR0_Divide_Pos 16U /*!< MVFR0: Divide bits Position */
#define FPU_MVFR0_Divide_Msk (0xFUL << FPU_MVFR0_Divide_Pos) /*!< MVFR0: Divide bits Mask */
#define FPU_MVFR0_FP_excep_trapping_Pos 12U /*!< MVFR0: FP exception trapping bits Position */
#define FPU_MVFR0_FP_excep_trapping_Msk (0xFUL << FPU_MVFR0_FP_excep_trapping_Pos) /*!< MVFR0: FP exception trapping bits Mask */
#define FPU_MVFR0_Double_precision_Pos 8U /*!< MVFR0: Double-precision bits Position */
#define FPU_MVFR0_Double_precision_Msk (0xFUL << FPU_MVFR0_Double_precision_Pos) /*!< MVFR0: Double-precision bits Mask */
#define FPU_MVFR0_Single_precision_Pos 4U /*!< MVFR0: Single-precision bits Position */
#define FPU_MVFR0_Single_precision_Msk (0xFUL << FPU_MVFR0_Single_precision_Pos) /*!< MVFR0: Single-precision bits Mask */
#define FPU_MVFR0_A_SIMD_registers_Pos 0U /*!< MVFR0: A_SIMD registers bits Position */
#define FPU_MVFR0_A_SIMD_registers_Msk (0xFUL /*<< FPU_MVFR0_A_SIMD_registers_Pos*/) /*!< MVFR0: A_SIMD registers bits Mask */
/* Media and FP Feature Register 1 Definitions */
#define FPU_MVFR1_FP_fused_MAC_Pos 28U /*!< MVFR1: FP fused MAC bits Position */
#define FPU_MVFR1_FP_fused_MAC_Msk (0xFUL << FPU_MVFR1_FP_fused_MAC_Pos) /*!< MVFR1: FP fused MAC bits Mask */
#define FPU_MVFR1_FP_HPFP_Pos 24U /*!< MVFR1: FP HPFP bits Position */
#define FPU_MVFR1_FP_HPFP_Msk (0xFUL << FPU_MVFR1_FP_HPFP_Pos) /*!< MVFR1: FP HPFP bits Mask */
#define FPU_MVFR1_D_NaN_mode_Pos 4U /*!< MVFR1: D_NaN mode bits Position */
#define FPU_MVFR1_D_NaN_mode_Msk (0xFUL << FPU_MVFR1_D_NaN_mode_Pos) /*!< MVFR1: D_NaN mode bits Mask */
#define FPU_MVFR1_FtZ_mode_Pos 0U /*!< MVFR1: FtZ mode bits Position */
#define FPU_MVFR1_FtZ_mode_Msk (0xFUL /*<< FPU_MVFR1_FtZ_mode_Pos*/) /*!< MVFR1: FtZ mode bits Mask */
/*@} end of group CMSIS_FPU */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
uint32_t RESERVED4[1U];
__IOM uint32_t DAUTHCTRL; /*!< Offset: 0x014 (R/W) Debug Authentication Control Register */
__IOM uint32_t DSCSR; /*!< Offset: 0x018 (R/W) Debug Security Control and Status Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESTART_ST_Pos 26U /*!< CoreDebug DHCSR: S_RESTART_ST Position */
#define CoreDebug_DHCSR_S_RESTART_ST_Msk (1UL << CoreDebug_DHCSR_S_RESTART_ST_Pos) /*!< CoreDebug DHCSR: S_RESTART_ST Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/* Debug Authentication Control Register Definitions */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos 3U /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Position */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Mask */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos 2U /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Msk (1UL << CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos) /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Mask */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Pos 1U /*!< CoreDebug DAUTHCTRL: INTSPIDEN Position */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPIDEN Mask */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Pos 0U /*!< CoreDebug DAUTHCTRL: SPIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Msk (1UL /*<< CoreDebug_DAUTHCTRL_SPIDENSEL_Pos*/) /*!< CoreDebug DAUTHCTRL: SPIDENSEL Mask */
/* Debug Security Control and Status Register Definitions */
#define CoreDebug_DSCSR_CDS_Pos 16U /*!< CoreDebug DSCSR: CDS Position */
#define CoreDebug_DSCSR_CDS_Msk (1UL << CoreDebug_DSCSR_CDS_Pos) /*!< CoreDebug DSCSR: CDS Mask */
#define CoreDebug_DSCSR_SBRSEL_Pos 1U /*!< CoreDebug DSCSR: SBRSEL Position */
#define CoreDebug_DSCSR_SBRSEL_Msk (1UL << CoreDebug_DSCSR_SBRSEL_Pos) /*!< CoreDebug DSCSR: SBRSEL Mask */
#define CoreDebug_DSCSR_SBRSELEN_Pos 0U /*!< CoreDebug DSCSR: SBRSELEN Position */
#define CoreDebug_DSCSR_SBRSELEN_Msk (1UL /*<< CoreDebug_DSCSR_SBRSELEN_Pos*/) /*!< CoreDebug DSCSR: SBRSELEN Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE ) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SAU_BASE (SCS_BASE + 0x0DD0UL) /*!< Security Attribution Unit */
#define SAU ((SAU_Type *) SAU_BASE ) /*!< Security Attribution Unit */
#endif
#define FPU_BASE (SCS_BASE + 0x0F30UL) /*!< Floating Point Unit */
#define FPU ((FPU_Type *) FPU_BASE ) /*!< Floating Point Unit */
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SCS_BASE_NS (0xE002E000UL) /*!< System Control Space Base Address (non-secure address space) */
#define CoreDebug_BASE_NS (0xE002EDF0UL) /*!< Core Debug Base Address (non-secure address space) */
#define SysTick_BASE_NS (SCS_BASE_NS + 0x0010UL) /*!< SysTick Base Address (non-secure address space) */
#define NVIC_BASE_NS (SCS_BASE_NS + 0x0100UL) /*!< NVIC Base Address (non-secure address space) */
#define SCB_BASE_NS (SCS_BASE_NS + 0x0D00UL) /*!< System Control Block Base Address (non-secure address space) */
#define SCnSCB_NS ((SCnSCB_Type *) SCS_BASE_NS ) /*!< System control Register not in SCB(non-secure address space) */
#define SCB_NS ((SCB_Type *) SCB_BASE_NS ) /*!< SCB configuration struct (non-secure address space) */
#define SysTick_NS ((SysTick_Type *) SysTick_BASE_NS ) /*!< SysTick configuration struct (non-secure address space) */
#define NVIC_NS ((NVIC_Type *) NVIC_BASE_NS ) /*!< NVIC configuration struct (non-secure address space) */
#define CoreDebug_NS ((CoreDebug_Type *) CoreDebug_BASE_NS) /*!< Core Debug configuration struct (non-secure address space) */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE_NS (SCS_BASE_NS + 0x0D90UL) /*!< Memory Protection Unit (non-secure address space) */
#define MPU_NS ((MPU_Type *) MPU_BASE_NS ) /*!< Memory Protection Unit (non-secure address space) */
#endif
#define FPU_BASE_NS (SCS_BASE_NS + 0x0F30UL) /*!< Floating Point Unit (non-secure address space) */
#define FPU_NS ((FPU_Type *) FPU_BASE_NS ) /*!< Floating Point Unit (non-secure address space) */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* Special LR values for Secure/Non-Secure call handling and exception handling */
/* Function Return Payload (from ARMv8-M Architecture Reference Manual) LR value on entry from Secure BLXNS */
#define FNC_RETURN (0xFEFFFFFFUL) /* bit [0] ignored when processing a branch */
/* The following EXC_RETURN mask values are used to evaluate the LR on exception entry */
#define EXC_RETURN_PREFIX (0xFF000000UL) /* bits [31:24] set to indicate an EXC_RETURN value */
#define EXC_RETURN_S (0x00000040UL) /* bit [6] stack used to push registers: 0=Non-secure 1=Secure */
#define EXC_RETURN_DCRS (0x00000020UL) /* bit [5] stacking rules for called registers: 0=skipped 1=saved */
#define EXC_RETURN_FTYPE (0x00000010UL) /* bit [4] allocate stack for floating-point context: 0=done 1=skipped */
#define EXC_RETURN_MODE (0x00000008UL) /* bit [3] processor mode for return: 0=Handler mode 1=Thread mode */
#define EXC_RETURN_SPSEL (0x00000004UL) /* bit [2] stack pointer used to restore context: 0=MSP 1=PSP */
#define EXC_RETURN_ES (0x00000001UL) /* bit [0] security state exception was taken to: 0=Non-secure 1=Secure */
/* Integrity Signature (from ARMv8-M Architecture Reference Manual) for exception context stacking */
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U) /* Value for processors with floating-point extension: */
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125AUL) /* bit [0] SFTC must match LR bit[4] EXC_RETURN_FTYPE */
#else
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125BUL) /* Value for processors without floating-point extension */
#endif
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Get Interrupt Target State
\details Reads the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
\return 1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_GetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Target State
\details Sets the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_SetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] |= ((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Clear Interrupt Target State
\details Clears the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_ClearTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] &= ~((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
__DSB();
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Set Priority Grouping (non-secure)
\details Sets the non-secure priority grouping field when in secure state using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void TZ_NVIC_SetPriorityGrouping_NS(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB_NS->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB_NS->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping (non-secure)
\details Reads the priority grouping field from the non-secure NVIC when in secure state.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriorityGrouping_NS(void)
{
return ((uint32_t)((SCB_NS->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt (non-secure)
\details Enables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_EnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Interrupt Enable status (non-secure)
\details Returns a device specific interrupt enable status from the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetEnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt (non-secure)
\details Disables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_DisableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Pending Interrupt (non-secure)
\details Reads the NVIC pending register in the non-secure NVIC when in secure state and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt (non-secure)
\details Sets the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_SetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt (non-secure)
\details Clears the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_ClearPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt (non-secure)
\details Reads the active register in non-secure NVIC when in secure state and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetActive_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority (non-secure)
\details Sets the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every non-secure processor exception.
*/
__STATIC_INLINE void TZ_NVIC_SetPriority_NS(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority (non-secure)
\details Reads the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority. Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriority_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC_NS->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
#endif /* defined (__ARM_FEATURE_CMSE) &&(__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv8.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
uint32_t mvfr0;
mvfr0 = FPU->MVFR0;
if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x220U)
{
return 2U; /* Double + Single precision FPU */
}
else if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x020U)
{
return 1U; /* Single precision FPU */
}
else
{
return 0U; /* No FPU */
}
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ########################## SAU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SAUFunctions SAU Functions
\brief Functions that configure the SAU.
@{
*/
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable SAU
\details Enables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Enable(void)
{
SAU->CTRL |= (SAU_CTRL_ENABLE_Msk);
}
/**
\brief Disable SAU
\details Disables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Disable(void)
{
SAU->CTRL &= ~(SAU_CTRL_ENABLE_Msk);
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_SAUFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief System Tick Configuration (non-secure)
\details Initializes the non-secure System Timer and its interrupt when in secure state, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>TZ_SysTick_Config_NS</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t TZ_SysTick_Config_NS(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick_NS->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
TZ_NVIC_SetPriority_NS (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick_NS->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick_NS->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_ARMV8MML_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 158,497 | C | 54.88787 | 178 | 0.529947 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/cmsis_armclang.h | /**************************************************************************//**
* @file cmsis_armclang.h
* @brief CMSIS compiler armclang (Arm Compiler 6) header file
* @version V5.2.0
* @date 08. May 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*lint -esym(9058, IRQn)*/ /* disable MISRA 2012 Rule 2.4 for IRQn */
#ifndef __CMSIS_ARMCLANG_H
#define __CMSIS_ARMCLANG_H
#pragma clang system_header /* treat file as system include file */
#ifndef __ARM_COMPAT_H
#include <arm_compat.h> /* Compatibility header for Arm Compiler 5 intrinsics */
#endif
/* CMSIS compiler specific defines */
#ifndef __ASM
#define __ASM __asm
#endif
#ifndef __INLINE
#define __INLINE __inline
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static __inline
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE __attribute__((always_inline)) static __inline
#endif
#ifndef __NO_RETURN
#define __NO_RETURN __attribute__((__noreturn__))
#endif
#ifndef __USED
#define __USED __attribute__((used))
#endif
#ifndef __WEAK
#define __WEAK __attribute__((weak))
#endif
#ifndef __PACKED
#define __PACKED __attribute__((packed, aligned(1)))
#endif
#ifndef __PACKED_STRUCT
#define __PACKED_STRUCT struct __attribute__((packed, aligned(1)))
#endif
#ifndef __PACKED_UNION
#define __PACKED_UNION union __attribute__((packed, aligned(1)))
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT32)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT32 */
struct __attribute__((packed)) T_UINT32 { uint32_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT32(x) (((struct T_UINT32 *)(x))->v)
#endif
#ifndef __UNALIGNED_UINT16_WRITE
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT16_WRITE)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT16_WRITE */
__PACKED_STRUCT T_UINT16_WRITE { uint16_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT16_WRITE(addr, val) (void)((((struct T_UINT16_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT16_READ
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT16_READ)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT16_READ */
__PACKED_STRUCT T_UINT16_READ { uint16_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT16_READ(addr) (((const struct T_UINT16_READ *)(const void *)(addr))->v)
#endif
#ifndef __UNALIGNED_UINT32_WRITE
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT32_WRITE)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT32_WRITE */
__PACKED_STRUCT T_UINT32_WRITE { uint32_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT32_WRITE(addr, val) (void)((((struct T_UINT32_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT32_READ
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT32_READ)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT32_READ */
__PACKED_STRUCT T_UINT32_READ { uint32_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT32_READ(addr) (((const struct T_UINT32_READ *)(const void *)(addr))->v)
#endif
#ifndef __ALIGNED
#define __ALIGNED(x) __attribute__((aligned(x)))
#endif
#ifndef __RESTRICT
#define __RESTRICT __restrict
#endif
#ifndef __COMPILER_BARRIER
#define __COMPILER_BARRIER() __ASM volatile("":::"memory")
#endif
/* ######################### Startup and Lowlevel Init ######################## */
#ifndef __PROGRAM_START
#define __PROGRAM_START __main
#endif
#ifndef __INITIAL_SP
#define __INITIAL_SP Image$$ARM_LIB_STACK$$ZI$$Limit
#endif
#ifndef __STACK_LIMIT
#define __STACK_LIMIT Image$$ARM_LIB_STACK$$ZI$$Base
#endif
#ifndef __VECTOR_TABLE
#define __VECTOR_TABLE __Vectors
#endif
#ifndef __VECTOR_TABLE_ATTRIBUTE
#define __VECTOR_TABLE_ATTRIBUTE __attribute((used, section("RESET")))
#endif
/* ########################### Core Function Access ########################### */
/** \ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_RegAccFunctions CMSIS Core Register Access Functions
@{
*/
/**
\brief Enable IRQ Interrupts
\details Enables IRQ interrupts by clearing the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
/* intrinsic void __enable_irq(); see arm_compat.h */
/**
\brief Disable IRQ Interrupts
\details Disables IRQ interrupts by setting the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
/* intrinsic void __disable_irq(); see arm_compat.h */
/**
\brief Get Control Register
\details Returns the content of the Control Register.
\return Control Register value
*/
__STATIC_FORCEINLINE uint32_t __get_CONTROL(void)
{
uint32_t result;
__ASM volatile ("MRS %0, control" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Control Register (non-secure)
\details Returns the content of the non-secure Control Register when in secure mode.
\return non-secure Control Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_CONTROL_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, control_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Control Register
\details Writes the given value to the Control Register.
\param [in] control Control Register value to set
*/
__STATIC_FORCEINLINE void __set_CONTROL(uint32_t control)
{
__ASM volatile ("MSR control, %0" : : "r" (control) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Control Register (non-secure)
\details Writes the given value to the non-secure Control Register when in secure state.
\param [in] control Control Register value to set
*/
__STATIC_FORCEINLINE void __TZ_set_CONTROL_NS(uint32_t control)
{
__ASM volatile ("MSR control_ns, %0" : : "r" (control) : "memory");
}
#endif
/**
\brief Get IPSR Register
\details Returns the content of the IPSR Register.
\return IPSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_IPSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, ipsr" : "=r" (result) );
return(result);
}
/**
\brief Get APSR Register
\details Returns the content of the APSR Register.
\return APSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_APSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, apsr" : "=r" (result) );
return(result);
}
/**
\brief Get xPSR Register
\details Returns the content of the xPSR Register.
\return xPSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_xPSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, xpsr" : "=r" (result) );
return(result);
}
/**
\brief Get Process Stack Pointer
\details Returns the current value of the Process Stack Pointer (PSP).
\return PSP Register value
*/
__STATIC_FORCEINLINE uint32_t __get_PSP(void)
{
uint32_t result;
__ASM volatile ("MRS %0, psp" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Process Stack Pointer (non-secure)
\details Returns the current value of the non-secure Process Stack Pointer (PSP) when in secure state.
\return PSP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PSP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, psp_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Process Stack Pointer
\details Assigns the given value to the Process Stack Pointer (PSP).
\param [in] topOfProcStack Process Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __set_PSP(uint32_t topOfProcStack)
{
__ASM volatile ("MSR psp, %0" : : "r" (topOfProcStack) : );
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Process Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Process Stack Pointer (PSP) when in secure state.
\param [in] topOfProcStack Process Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_PSP_NS(uint32_t topOfProcStack)
{
__ASM volatile ("MSR psp_ns, %0" : : "r" (topOfProcStack) : );
}
#endif
/**
\brief Get Main Stack Pointer
\details Returns the current value of the Main Stack Pointer (MSP).
\return MSP Register value
*/
__STATIC_FORCEINLINE uint32_t __get_MSP(void)
{
uint32_t result;
__ASM volatile ("MRS %0, msp" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Main Stack Pointer (non-secure)
\details Returns the current value of the non-secure Main Stack Pointer (MSP) when in secure state.
\return MSP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_MSP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, msp_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Main Stack Pointer
\details Assigns the given value to the Main Stack Pointer (MSP).
\param [in] topOfMainStack Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __set_MSP(uint32_t topOfMainStack)
{
__ASM volatile ("MSR msp, %0" : : "r" (topOfMainStack) : );
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Main Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Main Stack Pointer (MSP) when in secure state.
\param [in] topOfMainStack Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_MSP_NS(uint32_t topOfMainStack)
{
__ASM volatile ("MSR msp_ns, %0" : : "r" (topOfMainStack) : );
}
#endif
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Stack Pointer (non-secure)
\details Returns the current value of the non-secure Stack Pointer (SP) when in secure state.
\return SP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_SP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, sp_ns" : "=r" (result) );
return(result);
}
/**
\brief Set Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Stack Pointer (SP) when in secure state.
\param [in] topOfStack Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_SP_NS(uint32_t topOfStack)
{
__ASM volatile ("MSR sp_ns, %0" : : "r" (topOfStack) : );
}
#endif
/**
\brief Get Priority Mask
\details Returns the current state of the priority mask bit from the Priority Mask Register.
\return Priority Mask value
*/
__STATIC_FORCEINLINE uint32_t __get_PRIMASK(void)
{
uint32_t result;
__ASM volatile ("MRS %0, primask" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Priority Mask (non-secure)
\details Returns the current state of the non-secure priority mask bit from the Priority Mask Register when in secure state.
\return Priority Mask value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PRIMASK_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, primask_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Priority Mask
\details Assigns the given value to the Priority Mask Register.
\param [in] priMask Priority Mask
*/
__STATIC_FORCEINLINE void __set_PRIMASK(uint32_t priMask)
{
__ASM volatile ("MSR primask, %0" : : "r" (priMask) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Priority Mask (non-secure)
\details Assigns the given value to the non-secure Priority Mask Register when in secure state.
\param [in] priMask Priority Mask
*/
__STATIC_FORCEINLINE void __TZ_set_PRIMASK_NS(uint32_t priMask)
{
__ASM volatile ("MSR primask_ns, %0" : : "r" (priMask) : "memory");
}
#endif
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) )
/**
\brief Enable FIQ
\details Enables FIQ interrupts by clearing the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
#define __enable_fault_irq __enable_fiq /* see arm_compat.h */
/**
\brief Disable FIQ
\details Disables FIQ interrupts by setting the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
#define __disable_fault_irq __disable_fiq /* see arm_compat.h */
/**
\brief Get Base Priority
\details Returns the current value of the Base Priority register.
\return Base Priority register value
*/
__STATIC_FORCEINLINE uint32_t __get_BASEPRI(void)
{
uint32_t result;
__ASM volatile ("MRS %0, basepri" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Base Priority (non-secure)
\details Returns the current value of the non-secure Base Priority register when in secure state.
\return Base Priority register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_BASEPRI_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, basepri_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Base Priority
\details Assigns the given value to the Base Priority register.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __set_BASEPRI(uint32_t basePri)
{
__ASM volatile ("MSR basepri, %0" : : "r" (basePri) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Base Priority (non-secure)
\details Assigns the given value to the non-secure Base Priority register when in secure state.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __TZ_set_BASEPRI_NS(uint32_t basePri)
{
__ASM volatile ("MSR basepri_ns, %0" : : "r" (basePri) : "memory");
}
#endif
/**
\brief Set Base Priority with condition
\details Assigns the given value to the Base Priority register only if BASEPRI masking is disabled,
or the new value increases the BASEPRI priority level.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __set_BASEPRI_MAX(uint32_t basePri)
{
__ASM volatile ("MSR basepri_max, %0" : : "r" (basePri) : "memory");
}
/**
\brief Get Fault Mask
\details Returns the current value of the Fault Mask register.
\return Fault Mask register value
*/
__STATIC_FORCEINLINE uint32_t __get_FAULTMASK(void)
{
uint32_t result;
__ASM volatile ("MRS %0, faultmask" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Fault Mask (non-secure)
\details Returns the current value of the non-secure Fault Mask register when in secure state.
\return Fault Mask register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_FAULTMASK_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, faultmask_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Fault Mask
\details Assigns the given value to the Fault Mask register.
\param [in] faultMask Fault Mask value to set
*/
__STATIC_FORCEINLINE void __set_FAULTMASK(uint32_t faultMask)
{
__ASM volatile ("MSR faultmask, %0" : : "r" (faultMask) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Fault Mask (non-secure)
\details Assigns the given value to the non-secure Fault Mask register when in secure state.
\param [in] faultMask Fault Mask value to set
*/
__STATIC_FORCEINLINE void __TZ_set_FAULTMASK_NS(uint32_t faultMask)
{
__ASM volatile ("MSR faultmask_ns, %0" : : "r" (faultMask) : "memory");
}
#endif
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief Get Process Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always in non-secure
mode.
\details Returns the current value of the Process Stack Pointer Limit (PSPLIM).
\return PSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __get_PSPLIM(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, psplim" : "=r" (result) );
return result;
#endif
}
#if (defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Process Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always in non-secure
mode.
\details Returns the current value of the non-secure Process Stack Pointer Limit (PSPLIM) when in secure state.
\return PSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PSPLIM_NS(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, psplim_ns" : "=r" (result) );
return result;
#endif
}
#endif
/**
\brief Set Process Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored in non-secure
mode.
\details Assigns the given value to the Process Stack Pointer Limit (PSPLIM).
\param [in] ProcStackPtrLimit Process Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __set_PSPLIM(uint32_t ProcStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)ProcStackPtrLimit;
#else
__ASM volatile ("MSR psplim, %0" : : "r" (ProcStackPtrLimit));
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Process Stack Pointer (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored in non-secure
mode.
\details Assigns the given value to the non-secure Process Stack Pointer Limit (PSPLIM) when in secure state.
\param [in] ProcStackPtrLimit Process Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __TZ_set_PSPLIM_NS(uint32_t ProcStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)ProcStackPtrLimit;
#else
__ASM volatile ("MSR psplim_ns, %0\n" : : "r" (ProcStackPtrLimit));
#endif
}
#endif
/**
\brief Get Main Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always.
\details Returns the current value of the Main Stack Pointer Limit (MSPLIM).
\return MSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __get_MSPLIM(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, msplim" : "=r" (result) );
return result;
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Main Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always.
\details Returns the current value of the non-secure Main Stack Pointer Limit(MSPLIM) when in secure state.
\return MSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_MSPLIM_NS(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, msplim_ns" : "=r" (result) );
return result;
#endif
}
#endif
/**
\brief Set Main Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored.
\details Assigns the given value to the Main Stack Pointer Limit (MSPLIM).
\param [in] MainStackPtrLimit Main Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __set_MSPLIM(uint32_t MainStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
(void)MainStackPtrLimit;
#else
__ASM volatile ("MSR msplim, %0" : : "r" (MainStackPtrLimit));
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Main Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored.
\details Assigns the given value to the non-secure Main Stack Pointer Limit (MSPLIM) when in secure state.
\param [in] MainStackPtrLimit Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_MSPLIM_NS(uint32_t MainStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
(void)MainStackPtrLimit;
#else
__ASM volatile ("MSR msplim_ns, %0" : : "r" (MainStackPtrLimit));
#endif
}
#endif
#endif /* ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
/**
\brief Get FPSCR
\details Returns the current value of the Floating Point Status/Control register.
\return Floating Point Status/Control register value
*/
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
#define __get_FPSCR (uint32_t)__builtin_arm_get_fpscr
#else
#define __get_FPSCR() ((uint32_t)0U)
#endif
/**
\brief Set FPSCR
\details Assigns the given value to the Floating Point Status/Control register.
\param [in] fpscr Floating Point Status/Control value to set
*/
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
#define __set_FPSCR __builtin_arm_set_fpscr
#else
#define __set_FPSCR(x) ((void)(x))
#endif
/*@} end of CMSIS_Core_RegAccFunctions */
/* ########################## Core Instruction Access ######################### */
/** \defgroup CMSIS_Core_InstructionInterface CMSIS Core Instruction Interface
Access to dedicated instructions
@{
*/
/* Define macros for porting to both thumb1 and thumb2.
* For thumb1, use low register (r0-r7), specified by constraint "l"
* Otherwise, use general registers, specified by constraint "r" */
#if defined (__thumb__) && !defined (__thumb2__)
#define __CMSIS_GCC_OUT_REG(r) "=l" (r)
#define __CMSIS_GCC_RW_REG(r) "+l" (r)
#define __CMSIS_GCC_USE_REG(r) "l" (r)
#else
#define __CMSIS_GCC_OUT_REG(r) "=r" (r)
#define __CMSIS_GCC_RW_REG(r) "+r" (r)
#define __CMSIS_GCC_USE_REG(r) "r" (r)
#endif
/**
\brief No Operation
\details No Operation does nothing. This instruction can be used for code alignment purposes.
*/
#define __NOP __builtin_arm_nop
/**
\brief Wait For Interrupt
\details Wait For Interrupt is a hint instruction that suspends execution until one of a number of events occurs.
*/
#define __WFI __builtin_arm_wfi
/**
\brief Wait For Event
\details Wait For Event is a hint instruction that permits the processor to enter
a low-power state until one of a number of events occurs.
*/
#define __WFE __builtin_arm_wfe
/**
\brief Send Event
\details Send Event is a hint instruction. It causes an event to be signaled to the CPU.
*/
#define __SEV __builtin_arm_sev
/**
\brief Instruction Synchronization Barrier
\details Instruction Synchronization Barrier flushes the pipeline in the processor,
so that all instructions following the ISB are fetched from cache or memory,
after the instruction has been completed.
*/
#define __ISB() __builtin_arm_isb(0xF)
/**
\brief Data Synchronization Barrier
\details Acts as a special kind of Data Memory Barrier.
It completes when all explicit memory accesses before this instruction complete.
*/
#define __DSB() __builtin_arm_dsb(0xF)
/**
\brief Data Memory Barrier
\details Ensures the apparent order of the explicit memory operations before
and after the instruction, without ensuring their completion.
*/
#define __DMB() __builtin_arm_dmb(0xF)
/**
\brief Reverse byte order (32 bit)
\details Reverses the byte order in unsigned integer value. For example, 0x12345678 becomes 0x78563412.
\param [in] value Value to reverse
\return Reversed value
*/
#define __REV(value) __builtin_bswap32(value)
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order within each halfword of a word. For example, 0x12345678 becomes 0x34127856.
\param [in] value Value to reverse
\return Reversed value
*/
#define __REV16(value) __ROR(__REV(value), 16)
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order in a 16-bit value and returns the signed 16-bit result. For example, 0x0080 becomes 0x8000.
\param [in] value Value to reverse
\return Reversed value
*/
#define __REVSH(value) (int16_t)__builtin_bswap16(value)
/**
\brief Rotate Right in unsigned value (32 bit)
\details Rotate Right (immediate) provides the value of the contents of a register rotated by a variable number of bits.
\param [in] op1 Value to rotate
\param [in] op2 Number of Bits to rotate
\return Rotated value
*/
__STATIC_FORCEINLINE uint32_t __ROR(uint32_t op1, uint32_t op2)
{
op2 %= 32U;
if (op2 == 0U)
{
return op1;
}
return (op1 >> op2) | (op1 << (32U - op2));
}
/**
\brief Breakpoint
\details Causes the processor to enter Debug state.
Debug tools can use this to investigate system state when the instruction at a particular address is reached.
\param [in] value is ignored by the processor.
If required, a debugger can use it to store additional information about the breakpoint.
*/
#define __BKPT(value) __ASM volatile ("bkpt "#value)
/**
\brief Reverse bit order of value
\details Reverses the bit order of the given value.
\param [in] value Value to reverse
\return Reversed value
*/
#define __RBIT __builtin_arm_rbit
/**
\brief Count leading zeros
\details Counts the number of leading zeros of a data value.
\param [in] value Value to count the leading zeros
\return number of leading zeros in value
*/
__STATIC_FORCEINLINE uint8_t __CLZ(uint32_t value)
{
/* Even though __builtin_clz produces a CLZ instruction on ARM, formally
__builtin_clz(0) is undefined behaviour, so handle this case specially.
This guarantees ARM-compatible results if happening to compile on a non-ARM
target, and ensures the compiler doesn't decide to activate any
optimisations using the logic "value was passed to __builtin_clz, so it
is non-zero".
ARM Compiler 6.10 and possibly earlier will optimise this test away, leaving a
single CLZ instruction.
*/
if (value == 0U)
{
return 32U;
}
return __builtin_clz(value);
}
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief LDR Exclusive (8 bit)
\details Executes a exclusive LDR instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
#define __LDREXB (uint8_t)__builtin_arm_ldrex
/**
\brief LDR Exclusive (16 bit)
\details Executes a exclusive LDR instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
#define __LDREXH (uint16_t)__builtin_arm_ldrex
/**
\brief LDR Exclusive (32 bit)
\details Executes a exclusive LDR instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
#define __LDREXW (uint32_t)__builtin_arm_ldrex
/**
\brief STR Exclusive (8 bit)
\details Executes a exclusive STR instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STREXB (uint32_t)__builtin_arm_strex
/**
\brief STR Exclusive (16 bit)
\details Executes a exclusive STR instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STREXH (uint32_t)__builtin_arm_strex
/**
\brief STR Exclusive (32 bit)
\details Executes a exclusive STR instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STREXW (uint32_t)__builtin_arm_strex
/**
\brief Remove the exclusive lock
\details Removes the exclusive lock which is created by LDREX.
*/
#define __CLREX __builtin_arm_clrex
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) )
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (1..32)
\return Saturated value
*/
#define __SSAT __builtin_arm_ssat
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (0..31)
\return Saturated value
*/
#define __USAT __builtin_arm_usat
/**
\brief Rotate Right with Extend (32 bit)
\details Moves each bit of a bitstring right by one bit.
The carry input is shifted in at the left end of the bitstring.
\param [in] value Value to rotate
\return Rotated value
*/
__STATIC_FORCEINLINE uint32_t __RRX(uint32_t value)
{
uint32_t result;
__ASM volatile ("rrx %0, %1" : __CMSIS_GCC_OUT_REG (result) : __CMSIS_GCC_USE_REG (value) );
return(result);
}
/**
\brief LDRT Unprivileged (8 bit)
\details Executes a Unprivileged LDRT instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDRBT(volatile uint8_t *ptr)
{
uint32_t result;
__ASM volatile ("ldrbt %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint8_t) result); /* Add explicit type cast here */
}
/**
\brief LDRT Unprivileged (16 bit)
\details Executes a Unprivileged LDRT instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDRHT(volatile uint16_t *ptr)
{
uint32_t result;
__ASM volatile ("ldrht %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint16_t) result); /* Add explicit type cast here */
}
/**
\brief LDRT Unprivileged (32 bit)
\details Executes a Unprivileged LDRT instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDRT(volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("ldrt %0, %1" : "=r" (result) : "Q" (*ptr) );
return(result);
}
/**
\brief STRT Unprivileged (8 bit)
\details Executes a Unprivileged STRT instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRBT(uint8_t value, volatile uint8_t *ptr)
{
__ASM volatile ("strbt %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief STRT Unprivileged (16 bit)
\details Executes a Unprivileged STRT instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRHT(uint16_t value, volatile uint16_t *ptr)
{
__ASM volatile ("strht %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief STRT Unprivileged (32 bit)
\details Executes a Unprivileged STRT instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRT(uint32_t value, volatile uint32_t *ptr)
{
__ASM volatile ("strt %1, %0" : "=Q" (*ptr) : "r" (value) );
}
#else /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (1..32)
\return Saturated value
*/
__STATIC_FORCEINLINE int32_t __SSAT(int32_t val, uint32_t sat)
{
if ((sat >= 1U) && (sat <= 32U))
{
const int32_t max = (int32_t)((1U << (sat - 1U)) - 1U);
const int32_t min = -1 - max ;
if (val > max)
{
return max;
}
else if (val < min)
{
return min;
}
}
return val;
}
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (0..31)
\return Saturated value
*/
__STATIC_FORCEINLINE uint32_t __USAT(int32_t val, uint32_t sat)
{
if (sat <= 31U)
{
const uint32_t max = ((1U << sat) - 1U);
if (val > (int32_t)max)
{
return max;
}
else if (val < 0)
{
return 0U;
}
}
return (uint32_t)val;
}
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief Load-Acquire (8 bit)
\details Executes a LDAB instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDAB(volatile uint8_t *ptr)
{
uint32_t result;
__ASM volatile ("ldab %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint8_t) result);
}
/**
\brief Load-Acquire (16 bit)
\details Executes a LDAH instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDAH(volatile uint16_t *ptr)
{
uint32_t result;
__ASM volatile ("ldah %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint16_t) result);
}
/**
\brief Load-Acquire (32 bit)
\details Executes a LDA instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDA(volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("lda %0, %1" : "=r" (result) : "Q" (*ptr) );
return(result);
}
/**
\brief Store-Release (8 bit)
\details Executes a STLB instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STLB(uint8_t value, volatile uint8_t *ptr)
{
__ASM volatile ("stlb %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Store-Release (16 bit)
\details Executes a STLH instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STLH(uint16_t value, volatile uint16_t *ptr)
{
__ASM volatile ("stlh %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Store-Release (32 bit)
\details Executes a STL instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STL(uint32_t value, volatile uint32_t *ptr)
{
__ASM volatile ("stl %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Load-Acquire Exclusive (8 bit)
\details Executes a LDAB exclusive instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
#define __LDAEXB (uint8_t)__builtin_arm_ldaex
/**
\brief Load-Acquire Exclusive (16 bit)
\details Executes a LDAH exclusive instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
#define __LDAEXH (uint16_t)__builtin_arm_ldaex
/**
\brief Load-Acquire Exclusive (32 bit)
\details Executes a LDA exclusive instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
#define __LDAEX (uint32_t)__builtin_arm_ldaex
/**
\brief Store-Release Exclusive (8 bit)
\details Executes a STLB exclusive instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STLEXB (uint32_t)__builtin_arm_stlex
/**
\brief Store-Release Exclusive (16 bit)
\details Executes a STLH exclusive instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STLEXH (uint32_t)__builtin_arm_stlex
/**
\brief Store-Release Exclusive (32 bit)
\details Executes a STL exclusive instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STLEX (uint32_t)__builtin_arm_stlex
#endif /* ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
/*@}*/ /* end of group CMSIS_Core_InstructionInterface */
/* ################### Compiler specific Intrinsics ########################### */
/** \defgroup CMSIS_SIMD_intrinsics CMSIS SIMD Intrinsics
Access to dedicated SIMD instructions
@{
*/
#if (defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1))
#define __SADD8 __builtin_arm_sadd8
#define __QADD8 __builtin_arm_qadd8
#define __SHADD8 __builtin_arm_shadd8
#define __UADD8 __builtin_arm_uadd8
#define __UQADD8 __builtin_arm_uqadd8
#define __UHADD8 __builtin_arm_uhadd8
#define __SSUB8 __builtin_arm_ssub8
#define __QSUB8 __builtin_arm_qsub8
#define __SHSUB8 __builtin_arm_shsub8
#define __USUB8 __builtin_arm_usub8
#define __UQSUB8 __builtin_arm_uqsub8
#define __UHSUB8 __builtin_arm_uhsub8
#define __SADD16 __builtin_arm_sadd16
#define __QADD16 __builtin_arm_qadd16
#define __SHADD16 __builtin_arm_shadd16
#define __UADD16 __builtin_arm_uadd16
#define __UQADD16 __builtin_arm_uqadd16
#define __UHADD16 __builtin_arm_uhadd16
#define __SSUB16 __builtin_arm_ssub16
#define __QSUB16 __builtin_arm_qsub16
#define __SHSUB16 __builtin_arm_shsub16
#define __USUB16 __builtin_arm_usub16
#define __UQSUB16 __builtin_arm_uqsub16
#define __UHSUB16 __builtin_arm_uhsub16
#define __SASX __builtin_arm_sasx
#define __QASX __builtin_arm_qasx
#define __SHASX __builtin_arm_shasx
#define __UASX __builtin_arm_uasx
#define __UQASX __builtin_arm_uqasx
#define __UHASX __builtin_arm_uhasx
#define __SSAX __builtin_arm_ssax
#define __QSAX __builtin_arm_qsax
#define __SHSAX __builtin_arm_shsax
#define __USAX __builtin_arm_usax
#define __UQSAX __builtin_arm_uqsax
#define __UHSAX __builtin_arm_uhsax
#define __USAD8 __builtin_arm_usad8
#define __USADA8 __builtin_arm_usada8
#define __SSAT16 __builtin_arm_ssat16
#define __USAT16 __builtin_arm_usat16
#define __UXTB16 __builtin_arm_uxtb16
#define __UXTAB16 __builtin_arm_uxtab16
#define __SXTB16 __builtin_arm_sxtb16
#define __SXTAB16 __builtin_arm_sxtab16
#define __SMUAD __builtin_arm_smuad
#define __SMUADX __builtin_arm_smuadx
#define __SMLAD __builtin_arm_smlad
#define __SMLADX __builtin_arm_smladx
#define __SMLALD __builtin_arm_smlald
#define __SMLALDX __builtin_arm_smlaldx
#define __SMUSD __builtin_arm_smusd
#define __SMUSDX __builtin_arm_smusdx
#define __SMLSD __builtin_arm_smlsd
#define __SMLSDX __builtin_arm_smlsdx
#define __SMLSLD __builtin_arm_smlsld
#define __SMLSLDX __builtin_arm_smlsldx
#define __SEL __builtin_arm_sel
#define __QADD __builtin_arm_qadd
#define __QSUB __builtin_arm_qsub
#define __PKHBT(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0x0000FFFFUL) | \
((((uint32_t)(ARG2)) << (ARG3)) & 0xFFFF0000UL) )
#define __PKHTB(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0xFFFF0000UL) | \
((((uint32_t)(ARG2)) >> (ARG3)) & 0x0000FFFFUL) )
__STATIC_FORCEINLINE int32_t __SMMLA (int32_t op1, int32_t op2, int32_t op3)
{
int32_t result;
__ASM volatile ("smmla %0, %1, %2, %3" : "=r" (result): "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
#endif /* (__ARM_FEATURE_DSP == 1) */
/*@} end of group CMSIS_SIMD_intrinsics */
#endif /* __CMSIS_ARMCLANG_H */
| 45,899 | C | 30.764706 | 126 | 0.611299 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_armv81mml.h | /**************************************************************************//**
* @file core_armv81mml.h
* @brief CMSIS Armv8.1-M Mainline Core Peripheral Access Layer Header File
* @version V1.0.0
* @date 15. March 2019
******************************************************************************/
/*
* Copyright (c) 2018-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_ARMV81MML_H_GENERIC
#define __CORE_ARMV81MML_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_ARMV81MML
@{
*/
#include "cmsis_version.h"
#define __ARM_ARCH_8M_MAIN__ 1 // patching for now
/* CMSIS ARMV81MML definitions */
#define __ARMv81MML_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __ARMv81MML_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __ARMv81MML_CMSIS_VERSION ((__ARMv81MML_CMSIS_VERSION_MAIN << 16U) | \
__ARMv81MML_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (81U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
For this, __FPU_PRESENT has to be checked prior to making use of FPU specific registers and functions.
*/
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#warning "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#if defined(__ARM_FEATURE_DSP)
#if defined(__DSP_PRESENT) && (__DSP_PRESENT == 1U)
#define __DSP_USED 1U
#else
#error "Compiler generates DSP (SIMD) instructions for a devices without DSP extensions (check __DSP_PRESENT)"
#define __DSP_USED 0U
#endif
#else
#define __DSP_USED 0U
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)
#define __FPU_USED 1U
#else
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#define __FPU_USED 0U
#endif
#else
#define __FPU_USED 0U
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_ARMV81MML_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_ARMV81MML_H_DEPENDANT
#define __CORE_ARMV81MML_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __ARMv81MML_REV
#define __ARMv81MML_REV 0x0000U
#warning "__ARMv81MML_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __SAUREGION_PRESENT
#define __SAUREGION_PRESENT 0U
#warning "__SAUREGION_PRESENT not defined in device header file; using default!"
#endif
#ifndef __DSP_PRESENT
#define __DSP_PRESENT 0U
#warning "__DSP_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group ARMv81MML */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core SAU Register
- Core FPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:16; /*!< bit: 0..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:7; /*!< bit: 20..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
#define APSR_GE_Pos 16U /*!< APSR: GE Position */
#define APSR_GE_Msk (0xFUL << APSR_GE_Pos) /*!< APSR: GE Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:7; /*!< bit: 9..15 Reserved */
uint32_t GE:4; /*!< bit: 16..19 Greater than or Equal flags */
uint32_t _reserved1:4; /*!< bit: 20..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t IT:2; /*!< bit: 25..26 saved IT state (read 0) */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_IT_Pos 25U /*!< xPSR: IT Position */
#define xPSR_IT_Msk (3UL << xPSR_IT_Pos) /*!< xPSR: IT Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_GE_Pos 16U /*!< xPSR: GE Position */
#define xPSR_GE_Msk (0xFUL << xPSR_GE_Pos) /*!< xPSR: GE Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack-pointer select */
uint32_t FPCA:1; /*!< bit: 2 Floating-point context active */
uint32_t SFPA:1; /*!< bit: 3 Secure floating-point active */
uint32_t _reserved1:28; /*!< bit: 4..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SFPA_Pos 3U /*!< CONTROL: SFPA Position */
#define CONTROL_SFPA_Msk (1UL << CONTROL_SFPA_Pos) /*!< CONTROL: SFPA Mask */
#define CONTROL_FPCA_Pos 2U /*!< CONTROL: FPCA Position */
#define CONTROL_FPCA_Msk (1UL << CONTROL_FPCA_Pos) /*!< CONTROL: FPCA Mask */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[16U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[16U];
__IOM uint32_t ICER[16U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[16U];
__IOM uint32_t ISPR[16U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[16U];
__IOM uint32_t ICPR[16U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[16U];
__IOM uint32_t IABR[16U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[16U];
__IOM uint32_t ITNS[16U]; /*!< Offset: 0x280 (R/W) Interrupt Non-Secure State Register */
uint32_t RESERVED5[16U];
__IOM uint8_t IPR[496U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED6[580U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHPR[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t ID_PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t ID_DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ID_ADR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t ID_MMFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ID_ISAR[6U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
__IM uint32_t CLIDR; /*!< Offset: 0x078 (R/ ) Cache Level ID register */
__IM uint32_t CTR; /*!< Offset: 0x07C (R/ ) Cache Type register */
__IM uint32_t CCSIDR; /*!< Offset: 0x080 (R/ ) Cache Size ID Register */
__IOM uint32_t CSSELR; /*!< Offset: 0x084 (R/W) Cache Size Selection Register */
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
__IOM uint32_t NSACR; /*!< Offset: 0x08C (R/W) Non-Secure Access Control Register */
uint32_t RESERVED3[92U];
__OM uint32_t STIR; /*!< Offset: 0x200 ( /W) Software Triggered Interrupt Register */
uint32_t RESERVED4[15U];
__IM uint32_t MVFR0; /*!< Offset: 0x240 (R/ ) Media and VFP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x244 (R/ ) Media and VFP Feature Register 1 */
__IM uint32_t MVFR2; /*!< Offset: 0x248 (R/ ) Media and VFP Feature Register 2 */
uint32_t RESERVED5[1U];
__OM uint32_t ICIALLU; /*!< Offset: 0x250 ( /W) I-Cache Invalidate All to PoU */
uint32_t RESERVED6[1U];
__OM uint32_t ICIMVAU; /*!< Offset: 0x258 ( /W) I-Cache Invalidate by MVA to PoU */
__OM uint32_t DCIMVAC; /*!< Offset: 0x25C ( /W) D-Cache Invalidate by MVA to PoC */
__OM uint32_t DCISW; /*!< Offset: 0x260 ( /W) D-Cache Invalidate by Set-way */
__OM uint32_t DCCMVAU; /*!< Offset: 0x264 ( /W) D-Cache Clean by MVA to PoU */
__OM uint32_t DCCMVAC; /*!< Offset: 0x268 ( /W) D-Cache Clean by MVA to PoC */
__OM uint32_t DCCSW; /*!< Offset: 0x26C ( /W) D-Cache Clean by Set-way */
__OM uint32_t DCCIMVAC; /*!< Offset: 0x270 ( /W) D-Cache Clean and Invalidate by MVA to PoC */
__OM uint32_t DCCISW; /*!< Offset: 0x274 ( /W) D-Cache Clean and Invalidate by Set-way */
uint32_t RESERVED7[6U];
__IOM uint32_t ITCMCR; /*!< Offset: 0x290 (R/W) Instruction Tightly-Coupled Memory Control Register */
__IOM uint32_t DTCMCR; /*!< Offset: 0x294 (R/W) Data Tightly-Coupled Memory Control Registers */
__IOM uint32_t AHBPCR; /*!< Offset: 0x298 (R/W) AHBP Control Register */
__IOM uint32_t CACR; /*!< Offset: 0x29C (R/W) L1 Cache Control Register */
__IOM uint32_t AHBSCR; /*!< Offset: 0x2A0 (R/W) AHB Slave Control Register */
uint32_t RESERVED8[1U];
__IOM uint32_t ABFSR; /*!< Offset: 0x2A8 (R/W) Auxiliary Bus Fault Status Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_PENDNMISET_Pos 31U /*!< SCB ICSR: PENDNMISET Position */
#define SCB_ICSR_PENDNMISET_Msk (1UL << SCB_ICSR_PENDNMISET_Pos) /*!< SCB ICSR: PENDNMISET Mask */
#define SCB_ICSR_NMIPENDSET_Pos SCB_ICSR_PENDNMISET_Pos /*!< SCB ICSR: NMIPENDSET Position, backward compatibility */
#define SCB_ICSR_NMIPENDSET_Msk SCB_ICSR_PENDNMISET_Msk /*!< SCB ICSR: NMIPENDSET Mask, backward compatibility */
#define SCB_ICSR_PENDNMICLR_Pos 30U /*!< SCB ICSR: PENDNMICLR Position */
#define SCB_ICSR_PENDNMICLR_Msk (1UL << SCB_ICSR_PENDNMICLR_Pos) /*!< SCB ICSR: PENDNMICLR Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_STTNS_Pos 24U /*!< SCB ICSR: STTNS Position (Security Extension) */
#define SCB_ICSR_STTNS_Msk (1UL << SCB_ICSR_STTNS_Pos) /*!< SCB ICSR: STTNS Mask (Security Extension) */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIS_Pos 14U /*!< SCB AIRCR: PRIS Position */
#define SCB_AIRCR_PRIS_Msk (1UL << SCB_AIRCR_PRIS_Pos) /*!< SCB AIRCR: PRIS Mask */
#define SCB_AIRCR_BFHFNMINS_Pos 13U /*!< SCB AIRCR: BFHFNMINS Position */
#define SCB_AIRCR_BFHFNMINS_Msk (1UL << SCB_AIRCR_BFHFNMINS_Pos) /*!< SCB AIRCR: BFHFNMINS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQS_Pos 3U /*!< SCB AIRCR: SYSRESETREQS Position */
#define SCB_AIRCR_SYSRESETREQS_Msk (1UL << SCB_AIRCR_SYSRESETREQS_Pos) /*!< SCB AIRCR: SYSRESETREQS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEPS_Pos 3U /*!< SCB SCR: SLEEPDEEPS Position */
#define SCB_SCR_SLEEPDEEPS_Msk (1UL << SCB_SCR_SLEEPDEEPS_Pos) /*!< SCB SCR: SLEEPDEEPS Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_BP_Pos 18U /*!< SCB CCR: BP Position */
#define SCB_CCR_BP_Msk (1UL << SCB_CCR_BP_Pos) /*!< SCB CCR: BP Mask */
#define SCB_CCR_IC_Pos 17U /*!< SCB CCR: IC Position */
#define SCB_CCR_IC_Msk (1UL << SCB_CCR_IC_Pos) /*!< SCB CCR: IC Mask */
#define SCB_CCR_DC_Pos 16U /*!< SCB CCR: DC Position */
#define SCB_CCR_DC_Msk (1UL << SCB_CCR_DC_Pos) /*!< SCB CCR: DC Mask */
#define SCB_CCR_STKOFHFNMIGN_Pos 10U /*!< SCB CCR: STKOFHFNMIGN Position */
#define SCB_CCR_STKOFHFNMIGN_Msk (1UL << SCB_CCR_STKOFHFNMIGN_Pos) /*!< SCB CCR: STKOFHFNMIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_HARDFAULTPENDED_Pos 21U /*!< SCB SHCSR: HARDFAULTPENDED Position */
#define SCB_SHCSR_HARDFAULTPENDED_Msk (1UL << SCB_SHCSR_HARDFAULTPENDED_Pos) /*!< SCB SHCSR: HARDFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTPENDED_Pos 20U /*!< SCB SHCSR: SECUREFAULTPENDED Position */
#define SCB_SHCSR_SECUREFAULTPENDED_Msk (1UL << SCB_SHCSR_SECUREFAULTPENDED_Pos) /*!< SCB SHCSR: SECUREFAULTPENDED Mask */
#define SCB_SHCSR_SECUREFAULTENA_Pos 19U /*!< SCB SHCSR: SECUREFAULTENA Position */
#define SCB_SHCSR_SECUREFAULTENA_Msk (1UL << SCB_SHCSR_SECUREFAULTENA_Pos) /*!< SCB SHCSR: SECUREFAULTENA Mask */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_NMIACT_Pos 5U /*!< SCB SHCSR: NMIACT Position */
#define SCB_SHCSR_NMIACT_Msk (1UL << SCB_SHCSR_NMIACT_Pos) /*!< SCB SHCSR: NMIACT Mask */
#define SCB_SHCSR_SECUREFAULTACT_Pos 4U /*!< SCB SHCSR: SECUREFAULTACT Position */
#define SCB_SHCSR_SECUREFAULTACT_Msk (1UL << SCB_SHCSR_SECUREFAULTACT_Pos) /*!< SCB SHCSR: SECUREFAULTACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_HARDFAULTACT_Pos 2U /*!< SCB SHCSR: HARDFAULTACT Position */
#define SCB_SHCSR_HARDFAULTACT_Msk (1UL << SCB_SHCSR_HARDFAULTACT_Pos) /*!< SCB SHCSR: HARDFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MLSPERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 5U) /*!< SCB CFSR (MMFSR): MLSPERR Position */
#define SCB_CFSR_MLSPERR_Msk (1UL << SCB_CFSR_MLSPERR_Pos) /*!< SCB CFSR (MMFSR): MLSPERR Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_LSPERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 5U) /*!< SCB CFSR (BFSR): LSPERR Position */
#define SCB_CFSR_LSPERR_Msk (1UL << SCB_CFSR_LSPERR_Pos) /*!< SCB CFSR (BFSR): LSPERR Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_STKOF_Pos (SCB_CFSR_USGFAULTSR_Pos + 4U) /*!< SCB CFSR (UFSR): STKOF Position */
#define SCB_CFSR_STKOF_Msk (1UL << SCB_CFSR_STKOF_Pos) /*!< SCB CFSR (UFSR): STKOF Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/* SCB Non-Secure Access Control Register Definitions */
#define SCB_NSACR_CP11_Pos 11U /*!< SCB NSACR: CP11 Position */
#define SCB_NSACR_CP11_Msk (1UL << SCB_NSACR_CP11_Pos) /*!< SCB NSACR: CP11 Mask */
#define SCB_NSACR_CP10_Pos 10U /*!< SCB NSACR: CP10 Position */
#define SCB_NSACR_CP10_Msk (1UL << SCB_NSACR_CP10_Pos) /*!< SCB NSACR: CP10 Mask */
#define SCB_NSACR_CPn_Pos 0U /*!< SCB NSACR: CPn Position */
#define SCB_NSACR_CPn_Msk (1UL /*<< SCB_NSACR_CPn_Pos*/) /*!< SCB NSACR: CPn Mask */
/* SCB Cache Level ID Register Definitions */
#define SCB_CLIDR_LOUU_Pos 27U /*!< SCB CLIDR: LoUU Position */
#define SCB_CLIDR_LOUU_Msk (7UL << SCB_CLIDR_LOUU_Pos) /*!< SCB CLIDR: LoUU Mask */
#define SCB_CLIDR_LOC_Pos 24U /*!< SCB CLIDR: LoC Position */
#define SCB_CLIDR_LOC_Msk (7UL << SCB_CLIDR_LOC_Pos) /*!< SCB CLIDR: LoC Mask */
/* SCB Cache Type Register Definitions */
#define SCB_CTR_FORMAT_Pos 29U /*!< SCB CTR: Format Position */
#define SCB_CTR_FORMAT_Msk (7UL << SCB_CTR_FORMAT_Pos) /*!< SCB CTR: Format Mask */
#define SCB_CTR_CWG_Pos 24U /*!< SCB CTR: CWG Position */
#define SCB_CTR_CWG_Msk (0xFUL << SCB_CTR_CWG_Pos) /*!< SCB CTR: CWG Mask */
#define SCB_CTR_ERG_Pos 20U /*!< SCB CTR: ERG Position */
#define SCB_CTR_ERG_Msk (0xFUL << SCB_CTR_ERG_Pos) /*!< SCB CTR: ERG Mask */
#define SCB_CTR_DMINLINE_Pos 16U /*!< SCB CTR: DminLine Position */
#define SCB_CTR_DMINLINE_Msk (0xFUL << SCB_CTR_DMINLINE_Pos) /*!< SCB CTR: DminLine Mask */
#define SCB_CTR_IMINLINE_Pos 0U /*!< SCB CTR: ImInLine Position */
#define SCB_CTR_IMINLINE_Msk (0xFUL /*<< SCB_CTR_IMINLINE_Pos*/) /*!< SCB CTR: ImInLine Mask */
/* SCB Cache Size ID Register Definitions */
#define SCB_CCSIDR_WT_Pos 31U /*!< SCB CCSIDR: WT Position */
#define SCB_CCSIDR_WT_Msk (1UL << SCB_CCSIDR_WT_Pos) /*!< SCB CCSIDR: WT Mask */
#define SCB_CCSIDR_WB_Pos 30U /*!< SCB CCSIDR: WB Position */
#define SCB_CCSIDR_WB_Msk (1UL << SCB_CCSIDR_WB_Pos) /*!< SCB CCSIDR: WB Mask */
#define SCB_CCSIDR_RA_Pos 29U /*!< SCB CCSIDR: RA Position */
#define SCB_CCSIDR_RA_Msk (1UL << SCB_CCSIDR_RA_Pos) /*!< SCB CCSIDR: RA Mask */
#define SCB_CCSIDR_WA_Pos 28U /*!< SCB CCSIDR: WA Position */
#define SCB_CCSIDR_WA_Msk (1UL << SCB_CCSIDR_WA_Pos) /*!< SCB CCSIDR: WA Mask */
#define SCB_CCSIDR_NUMSETS_Pos 13U /*!< SCB CCSIDR: NumSets Position */
#define SCB_CCSIDR_NUMSETS_Msk (0x7FFFUL << SCB_CCSIDR_NUMSETS_Pos) /*!< SCB CCSIDR: NumSets Mask */
#define SCB_CCSIDR_ASSOCIATIVITY_Pos 3U /*!< SCB CCSIDR: Associativity Position */
#define SCB_CCSIDR_ASSOCIATIVITY_Msk (0x3FFUL << SCB_CCSIDR_ASSOCIATIVITY_Pos) /*!< SCB CCSIDR: Associativity Mask */
#define SCB_CCSIDR_LINESIZE_Pos 0U /*!< SCB CCSIDR: LineSize Position */
#define SCB_CCSIDR_LINESIZE_Msk (7UL /*<< SCB_CCSIDR_LINESIZE_Pos*/) /*!< SCB CCSIDR: LineSize Mask */
/* SCB Cache Size Selection Register Definitions */
#define SCB_CSSELR_LEVEL_Pos 1U /*!< SCB CSSELR: Level Position */
#define SCB_CSSELR_LEVEL_Msk (7UL << SCB_CSSELR_LEVEL_Pos) /*!< SCB CSSELR: Level Mask */
#define SCB_CSSELR_IND_Pos 0U /*!< SCB CSSELR: InD Position */
#define SCB_CSSELR_IND_Msk (1UL /*<< SCB_CSSELR_IND_Pos*/) /*!< SCB CSSELR: InD Mask */
/* SCB Software Triggered Interrupt Register Definitions */
#define SCB_STIR_INTID_Pos 0U /*!< SCB STIR: INTID Position */
#define SCB_STIR_INTID_Msk (0x1FFUL /*<< SCB_STIR_INTID_Pos*/) /*!< SCB STIR: INTID Mask */
/* SCB D-Cache Invalidate by Set-way Register Definitions */
#define SCB_DCISW_WAY_Pos 30U /*!< SCB DCISW: Way Position */
#define SCB_DCISW_WAY_Msk (3UL << SCB_DCISW_WAY_Pos) /*!< SCB DCISW: Way Mask */
#define SCB_DCISW_SET_Pos 5U /*!< SCB DCISW: Set Position */
#define SCB_DCISW_SET_Msk (0x1FFUL << SCB_DCISW_SET_Pos) /*!< SCB DCISW: Set Mask */
/* SCB D-Cache Clean by Set-way Register Definitions */
#define SCB_DCCSW_WAY_Pos 30U /*!< SCB DCCSW: Way Position */
#define SCB_DCCSW_WAY_Msk (3UL << SCB_DCCSW_WAY_Pos) /*!< SCB DCCSW: Way Mask */
#define SCB_DCCSW_SET_Pos 5U /*!< SCB DCCSW: Set Position */
#define SCB_DCCSW_SET_Msk (0x1FFUL << SCB_DCCSW_SET_Pos) /*!< SCB DCCSW: Set Mask */
/* SCB D-Cache Clean and Invalidate by Set-way Register Definitions */
#define SCB_DCCISW_WAY_Pos 30U /*!< SCB DCCISW: Way Position */
#define SCB_DCCISW_WAY_Msk (3UL << SCB_DCCISW_WAY_Pos) /*!< SCB DCCISW: Way Mask */
#define SCB_DCCISW_SET_Pos 5U /*!< SCB DCCISW: Set Position */
#define SCB_DCCISW_SET_Msk (0x1FFUL << SCB_DCCISW_SET_Pos) /*!< SCB DCCISW: Set Mask */
/* Instruction Tightly-Coupled Memory Control Register Definitions */
#define SCB_ITCMCR_SZ_Pos 3U /*!< SCB ITCMCR: SZ Position */
#define SCB_ITCMCR_SZ_Msk (0xFUL << SCB_ITCMCR_SZ_Pos) /*!< SCB ITCMCR: SZ Mask */
#define SCB_ITCMCR_RETEN_Pos 2U /*!< SCB ITCMCR: RETEN Position */
#define SCB_ITCMCR_RETEN_Msk (1UL << SCB_ITCMCR_RETEN_Pos) /*!< SCB ITCMCR: RETEN Mask */
#define SCB_ITCMCR_RMW_Pos 1U /*!< SCB ITCMCR: RMW Position */
#define SCB_ITCMCR_RMW_Msk (1UL << SCB_ITCMCR_RMW_Pos) /*!< SCB ITCMCR: RMW Mask */
#define SCB_ITCMCR_EN_Pos 0U /*!< SCB ITCMCR: EN Position */
#define SCB_ITCMCR_EN_Msk (1UL /*<< SCB_ITCMCR_EN_Pos*/) /*!< SCB ITCMCR: EN Mask */
/* Data Tightly-Coupled Memory Control Register Definitions */
#define SCB_DTCMCR_SZ_Pos 3U /*!< SCB DTCMCR: SZ Position */
#define SCB_DTCMCR_SZ_Msk (0xFUL << SCB_DTCMCR_SZ_Pos) /*!< SCB DTCMCR: SZ Mask */
#define SCB_DTCMCR_RETEN_Pos 2U /*!< SCB DTCMCR: RETEN Position */
#define SCB_DTCMCR_RETEN_Msk (1UL << SCB_DTCMCR_RETEN_Pos) /*!< SCB DTCMCR: RETEN Mask */
#define SCB_DTCMCR_RMW_Pos 1U /*!< SCB DTCMCR: RMW Position */
#define SCB_DTCMCR_RMW_Msk (1UL << SCB_DTCMCR_RMW_Pos) /*!< SCB DTCMCR: RMW Mask */
#define SCB_DTCMCR_EN_Pos 0U /*!< SCB DTCMCR: EN Position */
#define SCB_DTCMCR_EN_Msk (1UL /*<< SCB_DTCMCR_EN_Pos*/) /*!< SCB DTCMCR: EN Mask */
/* AHBP Control Register Definitions */
#define SCB_AHBPCR_SZ_Pos 1U /*!< SCB AHBPCR: SZ Position */
#define SCB_AHBPCR_SZ_Msk (7UL << SCB_AHBPCR_SZ_Pos) /*!< SCB AHBPCR: SZ Mask */
#define SCB_AHBPCR_EN_Pos 0U /*!< SCB AHBPCR: EN Position */
#define SCB_AHBPCR_EN_Msk (1UL /*<< SCB_AHBPCR_EN_Pos*/) /*!< SCB AHBPCR: EN Mask */
/* L1 Cache Control Register Definitions */
#define SCB_CACR_FORCEWT_Pos 2U /*!< SCB CACR: FORCEWT Position */
#define SCB_CACR_FORCEWT_Msk (1UL << SCB_CACR_FORCEWT_Pos) /*!< SCB CACR: FORCEWT Mask */
#define SCB_CACR_ECCEN_Pos 1U /*!< SCB CACR: ECCEN Position */
#define SCB_CACR_ECCEN_Msk (1UL << SCB_CACR_ECCEN_Pos) /*!< SCB CACR: ECCEN Mask */
#define SCB_CACR_SIWT_Pos 0U /*!< SCB CACR: SIWT Position */
#define SCB_CACR_SIWT_Msk (1UL /*<< SCB_CACR_SIWT_Pos*/) /*!< SCB CACR: SIWT Mask */
/* AHBS Control Register Definitions */
#define SCB_AHBSCR_INITCOUNT_Pos 11U /*!< SCB AHBSCR: INITCOUNT Position */
#define SCB_AHBSCR_INITCOUNT_Msk (0x1FUL << SCB_AHBPCR_INITCOUNT_Pos) /*!< SCB AHBSCR: INITCOUNT Mask */
#define SCB_AHBSCR_TPRI_Pos 2U /*!< SCB AHBSCR: TPRI Position */
#define SCB_AHBSCR_TPRI_Msk (0x1FFUL << SCB_AHBPCR_TPRI_Pos) /*!< SCB AHBSCR: TPRI Mask */
#define SCB_AHBSCR_CTL_Pos 0U /*!< SCB AHBSCR: CTL Position*/
#define SCB_AHBSCR_CTL_Msk (3UL /*<< SCB_AHBPCR_CTL_Pos*/) /*!< SCB AHBSCR: CTL Mask */
/* Auxiliary Bus Fault Status Register Definitions */
#define SCB_ABFSR_AXIMTYPE_Pos 8U /*!< SCB ABFSR: AXIMTYPE Position*/
#define SCB_ABFSR_AXIMTYPE_Msk (3UL << SCB_ABFSR_AXIMTYPE_Pos) /*!< SCB ABFSR: AXIMTYPE Mask */
#define SCB_ABFSR_EPPB_Pos 4U /*!< SCB ABFSR: EPPB Position*/
#define SCB_ABFSR_EPPB_Msk (1UL << SCB_ABFSR_EPPB_Pos) /*!< SCB ABFSR: EPPB Mask */
#define SCB_ABFSR_AXIM_Pos 3U /*!< SCB ABFSR: AXIM Position*/
#define SCB_ABFSR_AXIM_Msk (1UL << SCB_ABFSR_AXIM_Pos) /*!< SCB ABFSR: AXIM Mask */
#define SCB_ABFSR_AHBP_Pos 2U /*!< SCB ABFSR: AHBP Position*/
#define SCB_ABFSR_AHBP_Msk (1UL << SCB_ABFSR_AHBP_Pos) /*!< SCB ABFSR: AHBP Mask */
#define SCB_ABFSR_DTCM_Pos 1U /*!< SCB ABFSR: DTCM Position*/
#define SCB_ABFSR_DTCM_Msk (1UL << SCB_ABFSR_DTCM_Pos) /*!< SCB ABFSR: DTCM Mask */
#define SCB_ABFSR_ITCM_Pos 0U /*!< SCB ABFSR: ITCM Position*/
#define SCB_ABFSR_ITCM_Msk (1UL /*<< SCB_ABFSR_ITCM_Pos*/) /*!< SCB ABFSR: ITCM Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
__IOM uint32_t CPPWR; /*!< Offset: 0x00C (R/W) Coprocessor Power Control Register */
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[29U];
__OM uint32_t IWR; /*!< Offset: 0xEF8 ( /W) ITM Integration Write Register */
__IM uint32_t IRR; /*!< Offset: 0xEFC (R/ ) ITM Integration Read Register */
__IOM uint32_t IMCR; /*!< Offset: 0xF00 (R/W) ITM Integration Mode Control Register */
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) ITM Device Architecture Register */
uint32_t RESERVED6[4U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Stimulus Port Register Definitions */
#define ITM_STIM_DISABLED_Pos 1U /*!< ITM STIM: DISABLED Position */
#define ITM_STIM_DISABLED_Msk (0x1UL << ITM_STIM_DISABLED_Pos) /*!< ITM STIM: DISABLED Mask */
#define ITM_STIM_FIFOREADY_Pos 0U /*!< ITM STIM: FIFOREADY Position */
#define ITM_STIM_FIFOREADY_Msk (0x1UL /*<< ITM_STIM_FIFOREADY_Pos*/) /*!< ITM STIM: FIFOREADY Mask */
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TRACEBUSID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TRACEBUSID_Msk (0x7FUL << ITM_TCR_TRACEBUSID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPRESCALE_Pos 8U /*!< ITM TCR: TSPRESCALE Position */
#define ITM_TCR_TSPRESCALE_Msk (3UL << ITM_TCR_TSPRESCALE_Pos) /*!< ITM TCR: TSPRESCALE Mask */
#define ITM_TCR_STALLENA_Pos 5U /*!< ITM TCR: STALLENA Position */
#define ITM_TCR_STALLENA_Msk (1UL << ITM_TCR_STALLENA_Pos) /*!< ITM TCR: STALLENA Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Integration Write Register Definitions */
#define ITM_IWR_ATVALIDM_Pos 0U /*!< ITM IWR: ATVALIDM Position */
#define ITM_IWR_ATVALIDM_Msk (1UL /*<< ITM_IWR_ATVALIDM_Pos*/) /*!< ITM IWR: ATVALIDM Mask */
/* ITM Integration Read Register Definitions */
#define ITM_IRR_ATREADYM_Pos 0U /*!< ITM IRR: ATREADYM Position */
#define ITM_IRR_ATREADYM_Msk (1UL /*<< ITM_IRR_ATREADYM_Pos*/) /*!< ITM IRR: ATREADYM Mask */
/* ITM Integration Mode Control Register Definitions */
#define ITM_IMCR_INTEGRATION_Pos 0U /*!< ITM IMCR: INTEGRATION Position */
#define ITM_IMCR_INTEGRATION_Msk (1UL /*<< ITM_IMCR_INTEGRATION_Pos*/) /*!< ITM IMCR: INTEGRATION Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
uint32_t RESERVED1[1U];
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
uint32_t RESERVED3[1U];
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED4[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
uint32_t RESERVED5[1U];
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED6[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
uint32_t RESERVED7[1U];
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
uint32_t RESERVED8[1U];
__IOM uint32_t COMP4; /*!< Offset: 0x060 (R/W) Comparator Register 4 */
uint32_t RESERVED9[1U];
__IOM uint32_t FUNCTION4; /*!< Offset: 0x068 (R/W) Function Register 4 */
uint32_t RESERVED10[1U];
__IOM uint32_t COMP5; /*!< Offset: 0x070 (R/W) Comparator Register 5 */
uint32_t RESERVED11[1U];
__IOM uint32_t FUNCTION5; /*!< Offset: 0x078 (R/W) Function Register 5 */
uint32_t RESERVED12[1U];
__IOM uint32_t COMP6; /*!< Offset: 0x080 (R/W) Comparator Register 6 */
uint32_t RESERVED13[1U];
__IOM uint32_t FUNCTION6; /*!< Offset: 0x088 (R/W) Function Register 6 */
uint32_t RESERVED14[1U];
__IOM uint32_t COMP7; /*!< Offset: 0x090 (R/W) Comparator Register 7 */
uint32_t RESERVED15[1U];
__IOM uint32_t FUNCTION7; /*!< Offset: 0x098 (R/W) Function Register 7 */
uint32_t RESERVED16[1U];
__IOM uint32_t COMP8; /*!< Offset: 0x0A0 (R/W) Comparator Register 8 */
uint32_t RESERVED17[1U];
__IOM uint32_t FUNCTION8; /*!< Offset: 0x0A8 (R/W) Function Register 8 */
uint32_t RESERVED18[1U];
__IOM uint32_t COMP9; /*!< Offset: 0x0B0 (R/W) Comparator Register 9 */
uint32_t RESERVED19[1U];
__IOM uint32_t FUNCTION9; /*!< Offset: 0x0B8 (R/W) Function Register 9 */
uint32_t RESERVED20[1U];
__IOM uint32_t COMP10; /*!< Offset: 0x0C0 (R/W) Comparator Register 10 */
uint32_t RESERVED21[1U];
__IOM uint32_t FUNCTION10; /*!< Offset: 0x0C8 (R/W) Function Register 10 */
uint32_t RESERVED22[1U];
__IOM uint32_t COMP11; /*!< Offset: 0x0D0 (R/W) Comparator Register 11 */
uint32_t RESERVED23[1U];
__IOM uint32_t FUNCTION11; /*!< Offset: 0x0D8 (R/W) Function Register 11 */
uint32_t RESERVED24[1U];
__IOM uint32_t COMP12; /*!< Offset: 0x0E0 (R/W) Comparator Register 12 */
uint32_t RESERVED25[1U];
__IOM uint32_t FUNCTION12; /*!< Offset: 0x0E8 (R/W) Function Register 12 */
uint32_t RESERVED26[1U];
__IOM uint32_t COMP13; /*!< Offset: 0x0F0 (R/W) Comparator Register 13 */
uint32_t RESERVED27[1U];
__IOM uint32_t FUNCTION13; /*!< Offset: 0x0F8 (R/W) Function Register 13 */
uint32_t RESERVED28[1U];
__IOM uint32_t COMP14; /*!< Offset: 0x100 (R/W) Comparator Register 14 */
uint32_t RESERVED29[1U];
__IOM uint32_t FUNCTION14; /*!< Offset: 0x108 (R/W) Function Register 14 */
uint32_t RESERVED30[1U];
__IOM uint32_t COMP15; /*!< Offset: 0x110 (R/W) Comparator Register 15 */
uint32_t RESERVED31[1U];
__IOM uint32_t FUNCTION15; /*!< Offset: 0x118 (R/W) Function Register 15 */
uint32_t RESERVED32[934U];
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R ) Lock Status Register */
uint32_t RESERVED33[1U];
__IM uint32_t DEVARCH; /*!< Offset: 0xFBC (R/ ) Device Architecture Register */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCDISS_Pos 23U /*!< DWT CTRL: CYCDISS Position */
#define DWT_CTRL_CYCDISS_Msk (0x1UL << DWT_CTRL_CYCDISS_Pos) /*!< DWT CTRL: CYCDISS Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_ID_Pos 27U /*!< DWT FUNCTION: ID Position */
#define DWT_FUNCTION_ID_Msk (0x1FUL << DWT_FUNCTION_ID_Pos) /*!< DWT FUNCTION: ID Mask */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_ACTION_Pos 4U /*!< DWT FUNCTION: ACTION Position */
#define DWT_FUNCTION_ACTION_Msk (0x1UL << DWT_FUNCTION_ACTION_Pos) /*!< DWT FUNCTION: ACTION Mask */
#define DWT_FUNCTION_MATCH_Pos 0U /*!< DWT FUNCTION: MATCH Position */
#define DWT_FUNCTION_MATCH_Msk (0xFUL /*<< DWT_FUNCTION_MATCH_Pos*/) /*!< DWT FUNCTION: MATCH Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Sizes Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Sizes Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IM uint32_t FSCR; /*!< Offset: 0x308 (R/ ) Formatter Synchronization Counter Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER */
__IM uint32_t FIFO0; /*!< Offset: 0xEEC (R/ ) Integration ETM Data */
__IM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/ ) ITATBCTR2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) ITATBCTR0 */
__IM uint32_t FIFO1; /*!< Offset: 0xEFC (R/ ) Integration ITM Data */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) TPIU_DEVID */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) TPIU_DEVTYPE */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration ETM Data Register Definitions (FIFO0) */
#define TPI_FIFO0_ITM_ATVALID_Pos 29U /*!< TPI FIFO0: ITM_ATVALID Position */
#define TPI_FIFO0_ITM_ATVALID_Msk (0x3UL << TPI_FIFO0_ITM_ATVALID_Pos) /*!< TPI FIFO0: ITM_ATVALID Mask */
#define TPI_FIFO0_ITM_bytecount_Pos 27U /*!< TPI FIFO0: ITM_bytecount Position */
#define TPI_FIFO0_ITM_bytecount_Msk (0x3UL << TPI_FIFO0_ITM_bytecount_Pos) /*!< TPI FIFO0: ITM_bytecount Mask */
#define TPI_FIFO0_ETM_ATVALID_Pos 26U /*!< TPI FIFO0: ETM_ATVALID Position */
#define TPI_FIFO0_ETM_ATVALID_Msk (0x3UL << TPI_FIFO0_ETM_ATVALID_Pos) /*!< TPI FIFO0: ETM_ATVALID Mask */
#define TPI_FIFO0_ETM_bytecount_Pos 24U /*!< TPI FIFO0: ETM_bytecount Position */
#define TPI_FIFO0_ETM_bytecount_Msk (0x3UL << TPI_FIFO0_ETM_bytecount_Pos) /*!< TPI FIFO0: ETM_bytecount Mask */
#define TPI_FIFO0_ETM2_Pos 16U /*!< TPI FIFO0: ETM2 Position */
#define TPI_FIFO0_ETM2_Msk (0xFFUL << TPI_FIFO0_ETM2_Pos) /*!< TPI FIFO0: ETM2 Mask */
#define TPI_FIFO0_ETM1_Pos 8U /*!< TPI FIFO0: ETM1 Position */
#define TPI_FIFO0_ETM1_Msk (0xFFUL << TPI_FIFO0_ETM1_Pos) /*!< TPI FIFO0: ETM1 Mask */
#define TPI_FIFO0_ETM0_Pos 0U /*!< TPI FIFO0: ETM0 Position */
#define TPI_FIFO0_ETM0_Msk (0xFFUL /*<< TPI_FIFO0_ETM0_Pos*/) /*!< TPI FIFO0: ETM0 Mask */
/* TPI ITATBCTR2 Register Definitions */
#define TPI_ITATBCTR2_ATREADY_Pos 0U /*!< TPI ITATBCTR2: ATREADY Position */
#define TPI_ITATBCTR2_ATREADY_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY_Pos*/) /*!< TPI ITATBCTR2: ATREADY Mask */
/* TPI Integration ITM Data Register Definitions (FIFO1) */
#define TPI_FIFO1_ITM_ATVALID_Pos 29U /*!< TPI FIFO1: ITM_ATVALID Position */
#define TPI_FIFO1_ITM_ATVALID_Msk (0x3UL << TPI_FIFO1_ITM_ATVALID_Pos) /*!< TPI FIFO1: ITM_ATVALID Mask */
#define TPI_FIFO1_ITM_bytecount_Pos 27U /*!< TPI FIFO1: ITM_bytecount Position */
#define TPI_FIFO1_ITM_bytecount_Msk (0x3UL << TPI_FIFO1_ITM_bytecount_Pos) /*!< TPI FIFO1: ITM_bytecount Mask */
#define TPI_FIFO1_ETM_ATVALID_Pos 26U /*!< TPI FIFO1: ETM_ATVALID Position */
#define TPI_FIFO1_ETM_ATVALID_Msk (0x3UL << TPI_FIFO1_ETM_ATVALID_Pos) /*!< TPI FIFO1: ETM_ATVALID Mask */
#define TPI_FIFO1_ETM_bytecount_Pos 24U /*!< TPI FIFO1: ETM_bytecount Position */
#define TPI_FIFO1_ETM_bytecount_Msk (0x3UL << TPI_FIFO1_ETM_bytecount_Pos) /*!< TPI FIFO1: ETM_bytecount Mask */
#define TPI_FIFO1_ITM2_Pos 16U /*!< TPI FIFO1: ITM2 Position */
#define TPI_FIFO1_ITM2_Msk (0xFFUL << TPI_FIFO1_ITM2_Pos) /*!< TPI FIFO1: ITM2 Mask */
#define TPI_FIFO1_ITM1_Pos 8U /*!< TPI FIFO1: ITM1 Position */
#define TPI_FIFO1_ITM1_Msk (0xFFUL << TPI_FIFO1_ITM1_Pos) /*!< TPI FIFO1: ITM1 Mask */
#define TPI_FIFO1_ITM0_Pos 0U /*!< TPI FIFO1: ITM0 Position */
#define TPI_FIFO1_ITM0_Msk (0xFFUL /*<< TPI_FIFO1_ITM0_Pos*/) /*!< TPI FIFO1: ITM0 Mask */
/* TPI ITATBCTR0 Register Definitions */
#define TPI_ITATBCTR0_ATREADY_Pos 0U /*!< TPI ITATBCTR0: ATREADY Position */
#define TPI_ITATBCTR0_ATREADY_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY_Pos*/) /*!< TPI ITATBCTR0: ATREADY Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x1UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_MinBufSz_Pos 6U /*!< TPI DEVID: MinBufSz Position */
#define TPI_DEVID_MinBufSz_Msk (0x7UL << TPI_DEVID_MinBufSz_Pos) /*!< TPI DEVID: MinBufSz Mask */
#define TPI_DEVID_AsynClkIn_Pos 5U /*!< TPI DEVID: AsynClkIn Position */
#define TPI_DEVID_AsynClkIn_Msk (0x1UL << TPI_DEVID_AsynClkIn_Pos) /*!< TPI DEVID: AsynClkIn Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x1FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_MajorType_Pos 4U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
#define TPI_DEVTYPE_SubType_Pos 0U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) MPU Region Limit Address Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Region Base Address Register Alias 1 */
__IOM uint32_t RLAR_A1; /*!< Offset: 0x018 (R/W) MPU Region Limit Address Register Alias 1 */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Region Base Address Register Alias 2 */
__IOM uint32_t RLAR_A2; /*!< Offset: 0x020 (R/W) MPU Region Limit Address Register Alias 2 */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Region Base Address Register Alias 3 */
__IOM uint32_t RLAR_A3; /*!< Offset: 0x028 (R/W) MPU Region Limit Address Register Alias 3 */
uint32_t RESERVED0[1];
union {
__IOM uint32_t MAIR[2];
struct {
__IOM uint32_t MAIR0; /*!< Offset: 0x030 (R/W) MPU Memory Attribute Indirection Register 0 */
__IOM uint32_t MAIR1; /*!< Offset: 0x034 (R/W) MPU Memory Attribute Indirection Register 1 */
};
};
} MPU_Type;
#define MPU_TYPE_RALIASES 4U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_ADDR_Pos 5U /*!< MPU RBAR: ADDR Position */
#define MPU_RBAR_ADDR_Msk (0x7FFFFFFUL << MPU_RBAR_ADDR_Pos) /*!< MPU RBAR: ADDR Mask */
#define MPU_RBAR_SH_Pos 3U /*!< MPU RBAR: SH Position */
#define MPU_RBAR_SH_Msk (0x3UL << MPU_RBAR_SH_Pos) /*!< MPU RBAR: SH Mask */
#define MPU_RBAR_AP_Pos 1U /*!< MPU RBAR: AP Position */
#define MPU_RBAR_AP_Msk (0x3UL << MPU_RBAR_AP_Pos) /*!< MPU RBAR: AP Mask */
#define MPU_RBAR_XN_Pos 0U /*!< MPU RBAR: XN Position */
#define MPU_RBAR_XN_Msk (01UL /*<< MPU_RBAR_XN_Pos*/) /*!< MPU RBAR: XN Mask */
/* MPU Region Limit Address Register Definitions */
#define MPU_RLAR_LIMIT_Pos 5U /*!< MPU RLAR: LIMIT Position */
#define MPU_RLAR_LIMIT_Msk (0x7FFFFFFUL << MPU_RLAR_LIMIT_Pos) /*!< MPU RLAR: LIMIT Mask */
#define MPU_RLAR_PXN_Pos 4U /*!< MPU RLAR: PXN Position */
#define MPU_RLAR_PXN_Msk (0x1UL << MPU_RLAR_PXN_Pos) /*!< MPU RLAR: PXN Mask */
#define MPU_RLAR_AttrIndx_Pos 1U /*!< MPU RLAR: AttrIndx Position */
#define MPU_RLAR_AttrIndx_Msk (0x7UL << MPU_RLAR_AttrIndx_Pos) /*!< MPU RLAR: AttrIndx Mask */
#define MPU_RLAR_EN_Pos 0U /*!< MPU RLAR: Region enable bit Position */
#define MPU_RLAR_EN_Msk (1UL /*<< MPU_RLAR_EN_Pos*/) /*!< MPU RLAR: Region enable bit Disable Mask */
/* MPU Memory Attribute Indirection Register 0 Definitions */
#define MPU_MAIR0_Attr3_Pos 24U /*!< MPU MAIR0: Attr3 Position */
#define MPU_MAIR0_Attr3_Msk (0xFFUL << MPU_MAIR0_Attr3_Pos) /*!< MPU MAIR0: Attr3 Mask */
#define MPU_MAIR0_Attr2_Pos 16U /*!< MPU MAIR0: Attr2 Position */
#define MPU_MAIR0_Attr2_Msk (0xFFUL << MPU_MAIR0_Attr2_Pos) /*!< MPU MAIR0: Attr2 Mask */
#define MPU_MAIR0_Attr1_Pos 8U /*!< MPU MAIR0: Attr1 Position */
#define MPU_MAIR0_Attr1_Msk (0xFFUL << MPU_MAIR0_Attr1_Pos) /*!< MPU MAIR0: Attr1 Mask */
#define MPU_MAIR0_Attr0_Pos 0U /*!< MPU MAIR0: Attr0 Position */
#define MPU_MAIR0_Attr0_Msk (0xFFUL /*<< MPU_MAIR0_Attr0_Pos*/) /*!< MPU MAIR0: Attr0 Mask */
/* MPU Memory Attribute Indirection Register 1 Definitions */
#define MPU_MAIR1_Attr7_Pos 24U /*!< MPU MAIR1: Attr7 Position */
#define MPU_MAIR1_Attr7_Msk (0xFFUL << MPU_MAIR1_Attr7_Pos) /*!< MPU MAIR1: Attr7 Mask */
#define MPU_MAIR1_Attr6_Pos 16U /*!< MPU MAIR1: Attr6 Position */
#define MPU_MAIR1_Attr6_Msk (0xFFUL << MPU_MAIR1_Attr6_Pos) /*!< MPU MAIR1: Attr6 Mask */
#define MPU_MAIR1_Attr5_Pos 8U /*!< MPU MAIR1: Attr5 Position */
#define MPU_MAIR1_Attr5_Msk (0xFFUL << MPU_MAIR1_Attr5_Pos) /*!< MPU MAIR1: Attr5 Mask */
#define MPU_MAIR1_Attr4_Pos 0U /*!< MPU MAIR1: Attr4 Position */
#define MPU_MAIR1_Attr4_Msk (0xFFUL /*<< MPU_MAIR1_Attr4_Pos*/) /*!< MPU MAIR1: Attr4 Mask */
/*@} end of group CMSIS_MPU */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SAU Security Attribution Unit (SAU)
\brief Type definitions for the Security Attribution Unit (SAU)
@{
*/
/**
\brief Structure type to access the Security Attribution Unit (SAU).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SAU Control Register */
__IM uint32_t TYPE; /*!< Offset: 0x004 (R/ ) SAU Type Register */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) SAU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) SAU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) SAU Region Limit Address Register */
#else
uint32_t RESERVED0[3];
#endif
__IOM uint32_t SFSR; /*!< Offset: 0x014 (R/W) Secure Fault Status Register */
__IOM uint32_t SFAR; /*!< Offset: 0x018 (R/W) Secure Fault Address Register */
} SAU_Type;
/* SAU Control Register Definitions */
#define SAU_CTRL_ALLNS_Pos 1U /*!< SAU CTRL: ALLNS Position */
#define SAU_CTRL_ALLNS_Msk (1UL << SAU_CTRL_ALLNS_Pos) /*!< SAU CTRL: ALLNS Mask */
#define SAU_CTRL_ENABLE_Pos 0U /*!< SAU CTRL: ENABLE Position */
#define SAU_CTRL_ENABLE_Msk (1UL /*<< SAU_CTRL_ENABLE_Pos*/) /*!< SAU CTRL: ENABLE Mask */
/* SAU Type Register Definitions */
#define SAU_TYPE_SREGION_Pos 0U /*!< SAU TYPE: SREGION Position */
#define SAU_TYPE_SREGION_Msk (0xFFUL /*<< SAU_TYPE_SREGION_Pos*/) /*!< SAU TYPE: SREGION Mask */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
/* SAU Region Number Register Definitions */
#define SAU_RNR_REGION_Pos 0U /*!< SAU RNR: REGION Position */
#define SAU_RNR_REGION_Msk (0xFFUL /*<< SAU_RNR_REGION_Pos*/) /*!< SAU RNR: REGION Mask */
/* SAU Region Base Address Register Definitions */
#define SAU_RBAR_BADDR_Pos 5U /*!< SAU RBAR: BADDR Position */
#define SAU_RBAR_BADDR_Msk (0x7FFFFFFUL << SAU_RBAR_BADDR_Pos) /*!< SAU RBAR: BADDR Mask */
/* SAU Region Limit Address Register Definitions */
#define SAU_RLAR_LADDR_Pos 5U /*!< SAU RLAR: LADDR Position */
#define SAU_RLAR_LADDR_Msk (0x7FFFFFFUL << SAU_RLAR_LADDR_Pos) /*!< SAU RLAR: LADDR Mask */
#define SAU_RLAR_NSC_Pos 1U /*!< SAU RLAR: NSC Position */
#define SAU_RLAR_NSC_Msk (1UL << SAU_RLAR_NSC_Pos) /*!< SAU RLAR: NSC Mask */
#define SAU_RLAR_ENABLE_Pos 0U /*!< SAU RLAR: ENABLE Position */
#define SAU_RLAR_ENABLE_Msk (1UL /*<< SAU_RLAR_ENABLE_Pos*/) /*!< SAU RLAR: ENABLE Mask */
#endif /* defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U) */
/* Secure Fault Status Register Definitions */
#define SAU_SFSR_LSERR_Pos 7U /*!< SAU SFSR: LSERR Position */
#define SAU_SFSR_LSERR_Msk (1UL << SAU_SFSR_LSERR_Pos) /*!< SAU SFSR: LSERR Mask */
#define SAU_SFSR_SFARVALID_Pos 6U /*!< SAU SFSR: SFARVALID Position */
#define SAU_SFSR_SFARVALID_Msk (1UL << SAU_SFSR_SFARVALID_Pos) /*!< SAU SFSR: SFARVALID Mask */
#define SAU_SFSR_LSPERR_Pos 5U /*!< SAU SFSR: LSPERR Position */
#define SAU_SFSR_LSPERR_Msk (1UL << SAU_SFSR_LSPERR_Pos) /*!< SAU SFSR: LSPERR Mask */
#define SAU_SFSR_INVTRAN_Pos 4U /*!< SAU SFSR: INVTRAN Position */
#define SAU_SFSR_INVTRAN_Msk (1UL << SAU_SFSR_INVTRAN_Pos) /*!< SAU SFSR: INVTRAN Mask */
#define SAU_SFSR_AUVIOL_Pos 3U /*!< SAU SFSR: AUVIOL Position */
#define SAU_SFSR_AUVIOL_Msk (1UL << SAU_SFSR_AUVIOL_Pos) /*!< SAU SFSR: AUVIOL Mask */
#define SAU_SFSR_INVER_Pos 2U /*!< SAU SFSR: INVER Position */
#define SAU_SFSR_INVER_Msk (1UL << SAU_SFSR_INVER_Pos) /*!< SAU SFSR: INVER Mask */
#define SAU_SFSR_INVIS_Pos 1U /*!< SAU SFSR: INVIS Position */
#define SAU_SFSR_INVIS_Msk (1UL << SAU_SFSR_INVIS_Pos) /*!< SAU SFSR: INVIS Mask */
#define SAU_SFSR_INVEP_Pos 0U /*!< SAU SFSR: INVEP Position */
#define SAU_SFSR_INVEP_Msk (1UL /*<< SAU_SFSR_INVEP_Pos*/) /*!< SAU SFSR: INVEP Mask */
/*@} end of group CMSIS_SAU */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_FPU Floating Point Unit (FPU)
\brief Type definitions for the Floating Point Unit (FPU)
@{
*/
/**
\brief Structure type to access the Floating Point Unit (FPU).
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IOM uint32_t FPCCR; /*!< Offset: 0x004 (R/W) Floating-Point Context Control Register */
__IOM uint32_t FPCAR; /*!< Offset: 0x008 (R/W) Floating-Point Context Address Register */
__IOM uint32_t FPDSCR; /*!< Offset: 0x00C (R/W) Floating-Point Default Status Control Register */
__IM uint32_t MVFR0; /*!< Offset: 0x010 (R/ ) Media and FP Feature Register 0 */
__IM uint32_t MVFR1; /*!< Offset: 0x014 (R/ ) Media and FP Feature Register 1 */
} FPU_Type;
/* Floating-Point Context Control Register Definitions */
#define FPU_FPCCR_ASPEN_Pos 31U /*!< FPCCR: ASPEN bit Position */
#define FPU_FPCCR_ASPEN_Msk (1UL << FPU_FPCCR_ASPEN_Pos) /*!< FPCCR: ASPEN bit Mask */
#define FPU_FPCCR_LSPEN_Pos 30U /*!< FPCCR: LSPEN Position */
#define FPU_FPCCR_LSPEN_Msk (1UL << FPU_FPCCR_LSPEN_Pos) /*!< FPCCR: LSPEN bit Mask */
#define FPU_FPCCR_LSPENS_Pos 29U /*!< FPCCR: LSPENS Position */
#define FPU_FPCCR_LSPENS_Msk (1UL << FPU_FPCCR_LSPENS_Pos) /*!< FPCCR: LSPENS bit Mask */
#define FPU_FPCCR_CLRONRET_Pos 28U /*!< FPCCR: CLRONRET Position */
#define FPU_FPCCR_CLRONRET_Msk (1UL << FPU_FPCCR_CLRONRET_Pos) /*!< FPCCR: CLRONRET bit Mask */
#define FPU_FPCCR_CLRONRETS_Pos 27U /*!< FPCCR: CLRONRETS Position */
#define FPU_FPCCR_CLRONRETS_Msk (1UL << FPU_FPCCR_CLRONRETS_Pos) /*!< FPCCR: CLRONRETS bit Mask */
#define FPU_FPCCR_TS_Pos 26U /*!< FPCCR: TS Position */
#define FPU_FPCCR_TS_Msk (1UL << FPU_FPCCR_TS_Pos) /*!< FPCCR: TS bit Mask */
#define FPU_FPCCR_UFRDY_Pos 10U /*!< FPCCR: UFRDY Position */
#define FPU_FPCCR_UFRDY_Msk (1UL << FPU_FPCCR_UFRDY_Pos) /*!< FPCCR: UFRDY bit Mask */
#define FPU_FPCCR_SPLIMVIOL_Pos 9U /*!< FPCCR: SPLIMVIOL Position */
#define FPU_FPCCR_SPLIMVIOL_Msk (1UL << FPU_FPCCR_SPLIMVIOL_Pos) /*!< FPCCR: SPLIMVIOL bit Mask */
#define FPU_FPCCR_MONRDY_Pos 8U /*!< FPCCR: MONRDY Position */
#define FPU_FPCCR_MONRDY_Msk (1UL << FPU_FPCCR_MONRDY_Pos) /*!< FPCCR: MONRDY bit Mask */
#define FPU_FPCCR_SFRDY_Pos 7U /*!< FPCCR: SFRDY Position */
#define FPU_FPCCR_SFRDY_Msk (1UL << FPU_FPCCR_SFRDY_Pos) /*!< FPCCR: SFRDY bit Mask */
#define FPU_FPCCR_BFRDY_Pos 6U /*!< FPCCR: BFRDY Position */
#define FPU_FPCCR_BFRDY_Msk (1UL << FPU_FPCCR_BFRDY_Pos) /*!< FPCCR: BFRDY bit Mask */
#define FPU_FPCCR_MMRDY_Pos 5U /*!< FPCCR: MMRDY Position */
#define FPU_FPCCR_MMRDY_Msk (1UL << FPU_FPCCR_MMRDY_Pos) /*!< FPCCR: MMRDY bit Mask */
#define FPU_FPCCR_HFRDY_Pos 4U /*!< FPCCR: HFRDY Position */
#define FPU_FPCCR_HFRDY_Msk (1UL << FPU_FPCCR_HFRDY_Pos) /*!< FPCCR: HFRDY bit Mask */
#define FPU_FPCCR_THREAD_Pos 3U /*!< FPCCR: processor mode bit Position */
#define FPU_FPCCR_THREAD_Msk (1UL << FPU_FPCCR_THREAD_Pos) /*!< FPCCR: processor mode active bit Mask */
#define FPU_FPCCR_S_Pos 2U /*!< FPCCR: Security status of the FP context bit Position */
#define FPU_FPCCR_S_Msk (1UL << FPU_FPCCR_S_Pos) /*!< FPCCR: Security status of the FP context bit Mask */
#define FPU_FPCCR_USER_Pos 1U /*!< FPCCR: privilege level bit Position */
#define FPU_FPCCR_USER_Msk (1UL << FPU_FPCCR_USER_Pos) /*!< FPCCR: privilege level bit Mask */
#define FPU_FPCCR_LSPACT_Pos 0U /*!< FPCCR: Lazy state preservation active bit Position */
#define FPU_FPCCR_LSPACT_Msk (1UL /*<< FPU_FPCCR_LSPACT_Pos*/) /*!< FPCCR: Lazy state preservation active bit Mask */
/* Floating-Point Context Address Register Definitions */
#define FPU_FPCAR_ADDRESS_Pos 3U /*!< FPCAR: ADDRESS bit Position */
#define FPU_FPCAR_ADDRESS_Msk (0x1FFFFFFFUL << FPU_FPCAR_ADDRESS_Pos) /*!< FPCAR: ADDRESS bit Mask */
/* Floating-Point Default Status Control Register Definitions */
#define FPU_FPDSCR_AHP_Pos 26U /*!< FPDSCR: AHP bit Position */
#define FPU_FPDSCR_AHP_Msk (1UL << FPU_FPDSCR_AHP_Pos) /*!< FPDSCR: AHP bit Mask */
#define FPU_FPDSCR_DN_Pos 25U /*!< FPDSCR: DN bit Position */
#define FPU_FPDSCR_DN_Msk (1UL << FPU_FPDSCR_DN_Pos) /*!< FPDSCR: DN bit Mask */
#define FPU_FPDSCR_FZ_Pos 24U /*!< FPDSCR: FZ bit Position */
#define FPU_FPDSCR_FZ_Msk (1UL << FPU_FPDSCR_FZ_Pos) /*!< FPDSCR: FZ bit Mask */
#define FPU_FPDSCR_RMode_Pos 22U /*!< FPDSCR: RMode bit Position */
#define FPU_FPDSCR_RMode_Msk (3UL << FPU_FPDSCR_RMode_Pos) /*!< FPDSCR: RMode bit Mask */
/* Media and FP Feature Register 0 Definitions */
#define FPU_MVFR0_FP_rounding_modes_Pos 28U /*!< MVFR0: FP rounding modes bits Position */
#define FPU_MVFR0_FP_rounding_modes_Msk (0xFUL << FPU_MVFR0_FP_rounding_modes_Pos) /*!< MVFR0: FP rounding modes bits Mask */
#define FPU_MVFR0_Short_vectors_Pos 24U /*!< MVFR0: Short vectors bits Position */
#define FPU_MVFR0_Short_vectors_Msk (0xFUL << FPU_MVFR0_Short_vectors_Pos) /*!< MVFR0: Short vectors bits Mask */
#define FPU_MVFR0_Square_root_Pos 20U /*!< MVFR0: Square root bits Position */
#define FPU_MVFR0_Square_root_Msk (0xFUL << FPU_MVFR0_Square_root_Pos) /*!< MVFR0: Square root bits Mask */
#define FPU_MVFR0_Divide_Pos 16U /*!< MVFR0: Divide bits Position */
#define FPU_MVFR0_Divide_Msk (0xFUL << FPU_MVFR0_Divide_Pos) /*!< MVFR0: Divide bits Mask */
#define FPU_MVFR0_FP_excep_trapping_Pos 12U /*!< MVFR0: FP exception trapping bits Position */
#define FPU_MVFR0_FP_excep_trapping_Msk (0xFUL << FPU_MVFR0_FP_excep_trapping_Pos) /*!< MVFR0: FP exception trapping bits Mask */
#define FPU_MVFR0_Double_precision_Pos 8U /*!< MVFR0: Double-precision bits Position */
#define FPU_MVFR0_Double_precision_Msk (0xFUL << FPU_MVFR0_Double_precision_Pos) /*!< MVFR0: Double-precision bits Mask */
#define FPU_MVFR0_Single_precision_Pos 4U /*!< MVFR0: Single-precision bits Position */
#define FPU_MVFR0_Single_precision_Msk (0xFUL << FPU_MVFR0_Single_precision_Pos) /*!< MVFR0: Single-precision bits Mask */
#define FPU_MVFR0_A_SIMD_registers_Pos 0U /*!< MVFR0: A_SIMD registers bits Position */
#define FPU_MVFR0_A_SIMD_registers_Msk (0xFUL /*<< FPU_MVFR0_A_SIMD_registers_Pos*/) /*!< MVFR0: A_SIMD registers bits Mask */
/* Media and FP Feature Register 1 Definitions */
#define FPU_MVFR1_FP_fused_MAC_Pos 28U /*!< MVFR1: FP fused MAC bits Position */
#define FPU_MVFR1_FP_fused_MAC_Msk (0xFUL << FPU_MVFR1_FP_fused_MAC_Pos) /*!< MVFR1: FP fused MAC bits Mask */
#define FPU_MVFR1_FP_HPFP_Pos 24U /*!< MVFR1: FP HPFP bits Position */
#define FPU_MVFR1_FP_HPFP_Msk (0xFUL << FPU_MVFR1_FP_HPFP_Pos) /*!< MVFR1: FP HPFP bits Mask */
#define FPU_MVFR1_D_NaN_mode_Pos 4U /*!< MVFR1: D_NaN mode bits Position */
#define FPU_MVFR1_D_NaN_mode_Msk (0xFUL << FPU_MVFR1_D_NaN_mode_Pos) /*!< MVFR1: D_NaN mode bits Mask */
#define FPU_MVFR1_FtZ_mode_Pos 0U /*!< MVFR1: FtZ mode bits Position */
#define FPU_MVFR1_FtZ_mode_Msk (0xFUL /*<< FPU_MVFR1_FtZ_mode_Pos*/) /*!< MVFR1: FtZ mode bits Mask */
/*@} end of group CMSIS_FPU */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
uint32_t RESERVED4[1U];
__IOM uint32_t DAUTHCTRL; /*!< Offset: 0x014 (R/W) Debug Authentication Control Register */
__IOM uint32_t DSCSR; /*!< Offset: 0x018 (R/W) Debug Security Control and Status Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESTART_ST_Pos 26U /*!< CoreDebug DHCSR: S_RESTART_ST Position */
#define CoreDebug_DHCSR_S_RESTART_ST_Msk (1UL << CoreDebug_DHCSR_S_RESTART_ST_Pos) /*!< CoreDebug DHCSR: S_RESTART_ST Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/* Debug Authentication Control Register Definitions */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos 3U /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Position */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Mask */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos 2U /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Msk (1UL << CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos) /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Mask */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Pos 1U /*!< CoreDebug DAUTHCTRL: INTSPIDEN Position */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPIDEN Mask */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Pos 0U /*!< CoreDebug DAUTHCTRL: SPIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Msk (1UL /*<< CoreDebug_DAUTHCTRL_SPIDENSEL_Pos*/) /*!< CoreDebug DAUTHCTRL: SPIDENSEL Mask */
/* Debug Security Control and Status Register Definitions */
#define CoreDebug_DSCSR_CDS_Pos 16U /*!< CoreDebug DSCSR: CDS Position */
#define CoreDebug_DSCSR_CDS_Msk (1UL << CoreDebug_DSCSR_CDS_Pos) /*!< CoreDebug DSCSR: CDS Mask */
#define CoreDebug_DSCSR_SBRSEL_Pos 1U /*!< CoreDebug DSCSR: SBRSEL Position */
#define CoreDebug_DSCSR_SBRSEL_Msk (1UL << CoreDebug_DSCSR_SBRSEL_Pos) /*!< CoreDebug DSCSR: SBRSEL Mask */
#define CoreDebug_DSCSR_SBRSELEN_Pos 0U /*!< CoreDebug DSCSR: SBRSELEN Position */
#define CoreDebug_DSCSR_SBRSELEN_Msk (1UL /*<< CoreDebug_DSCSR_SBRSELEN_Pos*/) /*!< CoreDebug DSCSR: SBRSELEN Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE ) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SAU_BASE (SCS_BASE + 0x0DD0UL) /*!< Security Attribution Unit */
#define SAU ((SAU_Type *) SAU_BASE ) /*!< Security Attribution Unit */
#endif
#define FPU_BASE (SCS_BASE + 0x0F30UL) /*!< Floating Point Unit */
#define FPU ((FPU_Type *) FPU_BASE ) /*!< Floating Point Unit */
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SCS_BASE_NS (0xE002E000UL) /*!< System Control Space Base Address (non-secure address space) */
#define CoreDebug_BASE_NS (0xE002EDF0UL) /*!< Core Debug Base Address (non-secure address space) */
#define SysTick_BASE_NS (SCS_BASE_NS + 0x0010UL) /*!< SysTick Base Address (non-secure address space) */
#define NVIC_BASE_NS (SCS_BASE_NS + 0x0100UL) /*!< NVIC Base Address (non-secure address space) */
#define SCB_BASE_NS (SCS_BASE_NS + 0x0D00UL) /*!< System Control Block Base Address (non-secure address space) */
#define SCnSCB_NS ((SCnSCB_Type *) SCS_BASE_NS ) /*!< System control Register not in SCB(non-secure address space) */
#define SCB_NS ((SCB_Type *) SCB_BASE_NS ) /*!< SCB configuration struct (non-secure address space) */
#define SysTick_NS ((SysTick_Type *) SysTick_BASE_NS ) /*!< SysTick configuration struct (non-secure address space) */
#define NVIC_NS ((NVIC_Type *) NVIC_BASE_NS ) /*!< NVIC configuration struct (non-secure address space) */
#define CoreDebug_NS ((CoreDebug_Type *) CoreDebug_BASE_NS) /*!< Core Debug configuration struct (non-secure address space) */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE_NS (SCS_BASE_NS + 0x0D90UL) /*!< Memory Protection Unit (non-secure address space) */
#define MPU_NS ((MPU_Type *) MPU_BASE_NS ) /*!< Memory Protection Unit (non-secure address space) */
#endif
#define FPU_BASE_NS (SCS_BASE_NS + 0x0F30UL) /*!< Floating Point Unit (non-secure address space) */
#define FPU_NS ((FPU_Type *) FPU_BASE_NS ) /*!< Floating Point Unit (non-secure address space) */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << 8U) ); /* Insert write key and priorty group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Get Interrupt Target State
\details Reads the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
\return 1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_GetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Target State
\details Sets the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_SetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] |= ((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Clear Interrupt Target State
\details Clears the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_ClearTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] &= ~((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
__DSB();
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Set Priority Grouping (non-secure)
\details Sets the non-secure priority grouping field when in secure state using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void TZ_NVIC_SetPriorityGrouping_NS(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB_NS->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << 8U) ); /* Insert write key and priorty group */
SCB_NS->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping (non-secure)
\details Reads the priority grouping field from the non-secure NVIC when in secure state.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriorityGrouping_NS(void)
{
return ((uint32_t)((SCB_NS->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt (non-secure)
\details Enables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_EnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Interrupt Enable status (non-secure)
\details Returns a device specific interrupt enable status from the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetEnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt (non-secure)
\details Disables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_DisableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Pending Interrupt (non-secure)
\details Reads the NVIC pending register in the non-secure NVIC when in secure state and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt (non-secure)
\details Sets the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_SetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt (non-secure)
\details Clears the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_ClearPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt (non-secure)
\details Reads the active register in non-secure NVIC when in secure state and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetActive_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority (non-secure)
\details Sets the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every non-secure processor exception.
*/
__STATIC_INLINE void TZ_NVIC_SetPriority_NS(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->IPR[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority (non-secure)
\details Reads the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority. Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriority_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC_NS->IPR[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB_NS->SHPR[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
#endif /* defined (__ARM_FEATURE_CMSE) &&(__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv8.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
uint32_t mvfr0;
mvfr0 = FPU->MVFR0;
if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x220U)
{
return 2U; /* Double + Single precision FPU */
}
else if ((mvfr0 & (FPU_MVFR0_Single_precision_Msk | FPU_MVFR0_Double_precision_Msk)) == 0x020U)
{
return 1U; /* Single precision FPU */
}
else
{
return 0U; /* No FPU */
}
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ########################## SAU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SAUFunctions SAU Functions
\brief Functions that configure the SAU.
@{
*/
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable SAU
\details Enables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Enable(void)
{
SAU->CTRL |= (SAU_CTRL_ENABLE_Msk);
}
/**
\brief Disable SAU
\details Disables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Disable(void)
{
SAU->CTRL &= ~(SAU_CTRL_ENABLE_Msk);
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_SAUFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief System Tick Configuration (non-secure)
\details Initializes the non-secure System Timer and its interrupt when in secure state, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>TZ_SysTick_Config_NS</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t TZ_SysTick_Config_NS(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick_NS->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
TZ_NVIC_SetPriority_NS (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick_NS->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick_NS->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_ARMV81MML_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 168,772 | C | 55.845066 | 178 | 0.525395 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm0plus.h | /**************************************************************************//**
* @file core_cm0plus.h
* @brief CMSIS Cortex-M0+ Core Peripheral Access Layer Header File
* @version V5.0.7
* @date 13. March 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM0PLUS_H_GENERIC
#define __CORE_CM0PLUS_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex-M0+
@{
*/
#include "cmsis_version.h"
/* CMSIS CM0+ definitions */
#define __CM0PLUS_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM0PLUS_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM0PLUS_CMSIS_VERSION ((__CM0PLUS_CMSIS_VERSION_MAIN << 16U) | \
__CM0PLUS_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (0U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM0PLUS_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM0PLUS_H_DEPENDANT
#define __CORE_CM0PLUS_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM0PLUS_REV
#define __CM0PLUS_REV 0x0000U
#warning "__CM0PLUS_REV not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __VTOR_PRESENT
#define __VTOR_PRESENT 0U
#warning "__VTOR_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 2U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex-M0+ */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core MPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:28; /*!< bit: 0..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:15; /*!< bit: 9..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t _reserved1:3; /*!< bit: 25..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[1U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[31U];
__IOM uint32_t ICER[1U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RESERVED1[31U];
__IOM uint32_t ISPR[1U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[31U];
__IOM uint32_t ICPR[1U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[31U];
uint32_t RESERVED4[64U];
__IOM uint32_t IP[8U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register */
} NVIC_Type;
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
#else
uint32_t RESERVED0;
#endif
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
uint32_t RESERVED1;
__IOM uint32_t SHP[2U]; /*!< Offset: 0x01C (R/W) System Handlers Priority Registers. [0] is RESERVED */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
/* SCB Interrupt Control State Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 8U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0xFFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
#endif
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region RNRber Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RASR; /*!< Offset: 0x010 (R/W) MPU Region Attribute and Size Register */
} MPU_Type;
#define MPU_TYPE_RALIASES 1U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_ADDR_Pos 8U /*!< MPU RBAR: ADDR Position */
#define MPU_RBAR_ADDR_Msk (0xFFFFFFUL << MPU_RBAR_ADDR_Pos) /*!< MPU RBAR: ADDR Mask */
#define MPU_RBAR_VALID_Pos 4U /*!< MPU RBAR: VALID Position */
#define MPU_RBAR_VALID_Msk (1UL << MPU_RBAR_VALID_Pos) /*!< MPU RBAR: VALID Mask */
#define MPU_RBAR_REGION_Pos 0U /*!< MPU RBAR: REGION Position */
#define MPU_RBAR_REGION_Msk (0xFUL /*<< MPU_RBAR_REGION_Pos*/) /*!< MPU RBAR: REGION Mask */
/* MPU Region Attribute and Size Register Definitions */
#define MPU_RASR_ATTRS_Pos 16U /*!< MPU RASR: MPU Region Attribute field Position */
#define MPU_RASR_ATTRS_Msk (0xFFFFUL << MPU_RASR_ATTRS_Pos) /*!< MPU RASR: MPU Region Attribute field Mask */
#define MPU_RASR_XN_Pos 28U /*!< MPU RASR: ATTRS.XN Position */
#define MPU_RASR_XN_Msk (1UL << MPU_RASR_XN_Pos) /*!< MPU RASR: ATTRS.XN Mask */
#define MPU_RASR_AP_Pos 24U /*!< MPU RASR: ATTRS.AP Position */
#define MPU_RASR_AP_Msk (0x7UL << MPU_RASR_AP_Pos) /*!< MPU RASR: ATTRS.AP Mask */
#define MPU_RASR_TEX_Pos 19U /*!< MPU RASR: ATTRS.TEX Position */
#define MPU_RASR_TEX_Msk (0x7UL << MPU_RASR_TEX_Pos) /*!< MPU RASR: ATTRS.TEX Mask */
#define MPU_RASR_S_Pos 18U /*!< MPU RASR: ATTRS.S Position */
#define MPU_RASR_S_Msk (1UL << MPU_RASR_S_Pos) /*!< MPU RASR: ATTRS.S Mask */
#define MPU_RASR_C_Pos 17U /*!< MPU RASR: ATTRS.C Position */
#define MPU_RASR_C_Msk (1UL << MPU_RASR_C_Pos) /*!< MPU RASR: ATTRS.C Mask */
#define MPU_RASR_B_Pos 16U /*!< MPU RASR: ATTRS.B Position */
#define MPU_RASR_B_Msk (1UL << MPU_RASR_B_Pos) /*!< MPU RASR: ATTRS.B Mask */
#define MPU_RASR_SRD_Pos 8U /*!< MPU RASR: Sub-Region Disable Position */
#define MPU_RASR_SRD_Msk (0xFFUL << MPU_RASR_SRD_Pos) /*!< MPU RASR: Sub-Region Disable Mask */
#define MPU_RASR_SIZE_Pos 1U /*!< MPU RASR: Region Size Field Position */
#define MPU_RASR_SIZE_Msk (0x1FUL << MPU_RASR_SIZE_Pos) /*!< MPU RASR: Region Size Field Mask */
#define MPU_RASR_ENABLE_Pos 0U /*!< MPU RASR: Region enable bit Position */
#define MPU_RASR_ENABLE_Msk (1UL /*<< MPU_RASR_ENABLE_Pos*/) /*!< MPU RASR: Region enable bit Disable Mask */
/*@} end of group CMSIS_MPU */
#endif
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Cortex-M0+ Core Debug Registers (DCB registers, SHCSR, and DFSR) are only accessible over DAP and not via processor.
Therefore they are not covered by the Cortex-M0+ header file.
@{
*/
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
/*#define NVIC_GetActive __NVIC_GetActive not available for Cortex-M0+ */
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
/* Interrupt Priorities are WORD accessible only under Armv6-M */
/* The following MACROS handle generation of the register offset and byte masks */
#define _BIT_SHIFT(IRQn) ( ((((uint32_t)(int32_t)(IRQn)) ) & 0x03UL) * 8UL)
#define _SHP_IDX(IRQn) ( (((((uint32_t)(int32_t)(IRQn)) & 0x0FUL)-8UL) >> 2UL) )
#define _IP_IDX(IRQn) ( (((uint32_t)(int32_t)(IRQn)) >> 2UL) )
#define __NVIC_SetPriorityGrouping(X) (void)(X)
#define __NVIC_GetPriorityGrouping() (0U)
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[_IP_IDX(IRQn)] = ((uint32_t)(NVIC->IP[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB->SHP[_SHP_IDX(IRQn)] = ((uint32_t)(SCB->SHP[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IP[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB->SHP[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
If VTOR is not present address 0 must be mapped to SRAM.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
uint32_t vectors = SCB->VTOR;
#else
uint32_t vectors = 0x0U;
#endif
(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4)) = vector;
/* ARM Application Note 321 states that the M0+ does not require the architectural barrier */
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
uint32_t vectors = SCB->VTOR;
#else
uint32_t vectors = 0x0U;
#endif
return (uint32_t)(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4));
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = ((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
SCB_AIRCR_SYSRESETREQ_Msk);
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv7.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM0PLUS_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 49,524 | C | 44.603131 | 178 | 0.543413 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/mpu_armv7.h | /******************************************************************************
* @file mpu_armv7.h
* @brief CMSIS MPU API for Armv7-M MPU
* @version V5.1.0
* @date 08. March 2019
******************************************************************************/
/*
* Copyright (c) 2017-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef ARM_MPU_ARMV7_H
#define ARM_MPU_ARMV7_H
#define ARM_MPU_REGION_SIZE_32B ((uint8_t)0x04U) ///!< MPU Region Size 32 Bytes
#define ARM_MPU_REGION_SIZE_64B ((uint8_t)0x05U) ///!< MPU Region Size 64 Bytes
#define ARM_MPU_REGION_SIZE_128B ((uint8_t)0x06U) ///!< MPU Region Size 128 Bytes
#define ARM_MPU_REGION_SIZE_256B ((uint8_t)0x07U) ///!< MPU Region Size 256 Bytes
#define ARM_MPU_REGION_SIZE_512B ((uint8_t)0x08U) ///!< MPU Region Size 512 Bytes
#define ARM_MPU_REGION_SIZE_1KB ((uint8_t)0x09U) ///!< MPU Region Size 1 KByte
#define ARM_MPU_REGION_SIZE_2KB ((uint8_t)0x0AU) ///!< MPU Region Size 2 KBytes
#define ARM_MPU_REGION_SIZE_4KB ((uint8_t)0x0BU) ///!< MPU Region Size 4 KBytes
#define ARM_MPU_REGION_SIZE_8KB ((uint8_t)0x0CU) ///!< MPU Region Size 8 KBytes
#define ARM_MPU_REGION_SIZE_16KB ((uint8_t)0x0DU) ///!< MPU Region Size 16 KBytes
#define ARM_MPU_REGION_SIZE_32KB ((uint8_t)0x0EU) ///!< MPU Region Size 32 KBytes
#define ARM_MPU_REGION_SIZE_64KB ((uint8_t)0x0FU) ///!< MPU Region Size 64 KBytes
#define ARM_MPU_REGION_SIZE_128KB ((uint8_t)0x10U) ///!< MPU Region Size 128 KBytes
#define ARM_MPU_REGION_SIZE_256KB ((uint8_t)0x11U) ///!< MPU Region Size 256 KBytes
#define ARM_MPU_REGION_SIZE_512KB ((uint8_t)0x12U) ///!< MPU Region Size 512 KBytes
#define ARM_MPU_REGION_SIZE_1MB ((uint8_t)0x13U) ///!< MPU Region Size 1 MByte
#define ARM_MPU_REGION_SIZE_2MB ((uint8_t)0x14U) ///!< MPU Region Size 2 MBytes
#define ARM_MPU_REGION_SIZE_4MB ((uint8_t)0x15U) ///!< MPU Region Size 4 MBytes
#define ARM_MPU_REGION_SIZE_8MB ((uint8_t)0x16U) ///!< MPU Region Size 8 MBytes
#define ARM_MPU_REGION_SIZE_16MB ((uint8_t)0x17U) ///!< MPU Region Size 16 MBytes
#define ARM_MPU_REGION_SIZE_32MB ((uint8_t)0x18U) ///!< MPU Region Size 32 MBytes
#define ARM_MPU_REGION_SIZE_64MB ((uint8_t)0x19U) ///!< MPU Region Size 64 MBytes
#define ARM_MPU_REGION_SIZE_128MB ((uint8_t)0x1AU) ///!< MPU Region Size 128 MBytes
#define ARM_MPU_REGION_SIZE_256MB ((uint8_t)0x1BU) ///!< MPU Region Size 256 MBytes
#define ARM_MPU_REGION_SIZE_512MB ((uint8_t)0x1CU) ///!< MPU Region Size 512 MBytes
#define ARM_MPU_REGION_SIZE_1GB ((uint8_t)0x1DU) ///!< MPU Region Size 1 GByte
#define ARM_MPU_REGION_SIZE_2GB ((uint8_t)0x1EU) ///!< MPU Region Size 2 GBytes
#define ARM_MPU_REGION_SIZE_4GB ((uint8_t)0x1FU) ///!< MPU Region Size 4 GBytes
#define ARM_MPU_AP_NONE 0U ///!< MPU Access Permission no access
#define ARM_MPU_AP_PRIV 1U ///!< MPU Access Permission privileged access only
#define ARM_MPU_AP_URO 2U ///!< MPU Access Permission unprivileged access read-only
#define ARM_MPU_AP_FULL 3U ///!< MPU Access Permission full access
#define ARM_MPU_AP_PRO 5U ///!< MPU Access Permission privileged access read-only
#define ARM_MPU_AP_RO 6U ///!< MPU Access Permission read-only access
/** MPU Region Base Address Register Value
*
* \param Region The region to be configured, number 0 to 15.
* \param BaseAddress The base address for the region.
*/
#define ARM_MPU_RBAR(Region, BaseAddress) \
(((BaseAddress) & MPU_RBAR_ADDR_Msk) | \
((Region) & MPU_RBAR_REGION_Msk) | \
(MPU_RBAR_VALID_Msk))
/**
* MPU Memory Access Attributes
*
* \param TypeExtField Type extension field, allows you to configure memory access type, for example strongly ordered, peripheral.
* \param IsShareable Region is shareable between multiple bus masters.
* \param IsCacheable Region is cacheable, i.e. its value may be kept in cache.
* \param IsBufferable Region is bufferable, i.e. using write-back caching. Cacheable but non-bufferable regions use write-through policy.
*/
#define ARM_MPU_ACCESS_(TypeExtField, IsShareable, IsCacheable, IsBufferable) \
((((TypeExtField) << MPU_RASR_TEX_Pos) & MPU_RASR_TEX_Msk) | \
(((IsShareable) << MPU_RASR_S_Pos) & MPU_RASR_S_Msk) | \
(((IsCacheable) << MPU_RASR_C_Pos) & MPU_RASR_C_Msk) | \
(((IsBufferable) << MPU_RASR_B_Pos) & MPU_RASR_B_Msk))
/**
* MPU Region Attribute and Size Register Value
*
* \param DisableExec Instruction access disable bit, 1= disable instruction fetches.
* \param AccessPermission Data access permissions, allows you to configure read/write access for User and Privileged mode.
* \param AccessAttributes Memory access attribution, see \ref ARM_MPU_ACCESS_.
* \param SubRegionDisable Sub-region disable field.
* \param Size Region size of the region to be configured, for example 4K, 8K.
*/
#define ARM_MPU_RASR_EX(DisableExec, AccessPermission, AccessAttributes, SubRegionDisable, Size) \
((((DisableExec) << MPU_RASR_XN_Pos) & MPU_RASR_XN_Msk) | \
(((AccessPermission) << MPU_RASR_AP_Pos) & MPU_RASR_AP_Msk) | \
(((AccessAttributes) & (MPU_RASR_TEX_Msk | MPU_RASR_S_Msk | MPU_RASR_C_Msk | MPU_RASR_B_Msk))) | \
(((SubRegionDisable) << MPU_RASR_SRD_Pos) & MPU_RASR_SRD_Msk) | \
(((Size) << MPU_RASR_SIZE_Pos) & MPU_RASR_SIZE_Msk) | \
(((MPU_RASR_ENABLE_Msk))))
/**
* MPU Region Attribute and Size Register Value
*
* \param DisableExec Instruction access disable bit, 1= disable instruction fetches.
* \param AccessPermission Data access permissions, allows you to configure read/write access for User and Privileged mode.
* \param TypeExtField Type extension field, allows you to configure memory access type, for example strongly ordered, peripheral.
* \param IsShareable Region is shareable between multiple bus masters.
* \param IsCacheable Region is cacheable, i.e. its value may be kept in cache.
* \param IsBufferable Region is bufferable, i.e. using write-back caching. Cacheable but non-bufferable regions use write-through policy.
* \param SubRegionDisable Sub-region disable field.
* \param Size Region size of the region to be configured, for example 4K, 8K.
*/
#define ARM_MPU_RASR(DisableExec, AccessPermission, TypeExtField, IsShareable, IsCacheable, IsBufferable, SubRegionDisable, Size) \
ARM_MPU_RASR_EX(DisableExec, AccessPermission, ARM_MPU_ACCESS_(TypeExtField, IsShareable, IsCacheable, IsBufferable), SubRegionDisable, Size)
/**
* MPU Memory Access Attribute for strongly ordered memory.
* - TEX: 000b
* - Shareable
* - Non-cacheable
* - Non-bufferable
*/
#define ARM_MPU_ACCESS_ORDERED ARM_MPU_ACCESS_(0U, 1U, 0U, 0U)
/**
* MPU Memory Access Attribute for device memory.
* - TEX: 000b (if shareable) or 010b (if non-shareable)
* - Shareable or non-shareable
* - Non-cacheable
* - Bufferable (if shareable) or non-bufferable (if non-shareable)
*
* \param IsShareable Configures the device memory as shareable or non-shareable.
*/
#define ARM_MPU_ACCESS_DEVICE(IsShareable) ((IsShareable) ? ARM_MPU_ACCESS_(0U, 1U, 0U, 1U) : ARM_MPU_ACCESS_(2U, 0U, 0U, 0U))
/**
* MPU Memory Access Attribute for normal memory.
* - TEX: 1BBb (reflecting outer cacheability rules)
* - Shareable or non-shareable
* - Cacheable or non-cacheable (reflecting inner cacheability rules)
* - Bufferable or non-bufferable (reflecting inner cacheability rules)
*
* \param OuterCp Configures the outer cache policy.
* \param InnerCp Configures the inner cache policy.
* \param IsShareable Configures the memory as shareable or non-shareable.
*/
#define ARM_MPU_ACCESS_NORMAL(OuterCp, InnerCp, IsShareable) ARM_MPU_ACCESS_((4U | (OuterCp)), IsShareable, ((InnerCp) & 2U), ((InnerCp) & 1U))
/**
* MPU Memory Access Attribute non-cacheable policy.
*/
#define ARM_MPU_CACHEP_NOCACHE 0U
/**
* MPU Memory Access Attribute write-back, write and read allocate policy.
*/
#define ARM_MPU_CACHEP_WB_WRA 1U
/**
* MPU Memory Access Attribute write-through, no write allocate policy.
*/
#define ARM_MPU_CACHEP_WT_NWA 2U
/**
* MPU Memory Access Attribute write-back, no write allocate policy.
*/
#define ARM_MPU_CACHEP_WB_NWA 3U
/**
* Struct for a single MPU Region
*/
typedef struct {
uint32_t RBAR; //!< The region base address register value (RBAR)
uint32_t RASR; //!< The region attribute and size register value (RASR) \ref MPU_RASR
} ARM_MPU_Region_t;
/** Enable the MPU.
* \param MPU_Control Default access permissions for unconfigured regions.
*/
__STATIC_INLINE void ARM_MPU_Enable(uint32_t MPU_Control)
{
MPU->CTRL = MPU_Control | MPU_CTRL_ENABLE_Msk;
#ifdef SCB_SHCSR_MEMFAULTENA_Msk
SCB->SHCSR |= SCB_SHCSR_MEMFAULTENA_Msk;
#endif
__DSB();
__ISB();
}
/** Disable the MPU.
*/
__STATIC_INLINE void ARM_MPU_Disable(void)
{
__DMB();
#ifdef SCB_SHCSR_MEMFAULTENA_Msk
SCB->SHCSR &= ~SCB_SHCSR_MEMFAULTENA_Msk;
#endif
MPU->CTRL &= ~MPU_CTRL_ENABLE_Msk;
}
/** Clear and disable the given MPU region.
* \param rnr Region number to be cleared.
*/
__STATIC_INLINE void ARM_MPU_ClrRegion(uint32_t rnr)
{
MPU->RNR = rnr;
MPU->RASR = 0U;
}
/** Configure an MPU region.
* \param rbar Value for RBAR register.
* \param rsar Value for RSAR register.
*/
__STATIC_INLINE void ARM_MPU_SetRegion(uint32_t rbar, uint32_t rasr)
{
MPU->RBAR = rbar;
MPU->RASR = rasr;
}
/** Configure the given MPU region.
* \param rnr Region number to be configured.
* \param rbar Value for RBAR register.
* \param rsar Value for RSAR register.
*/
__STATIC_INLINE void ARM_MPU_SetRegionEx(uint32_t rnr, uint32_t rbar, uint32_t rasr)
{
MPU->RNR = rnr;
MPU->RBAR = rbar;
MPU->RASR = rasr;
}
/** Memcopy with strictly ordered memory access, e.g. for register targets.
* \param dst Destination data is copied to.
* \param src Source data is copied from.
* \param len Amount of data words to be copied.
*/
__STATIC_INLINE void ARM_MPU_OrderedMemcpy(volatile uint32_t* dst, const uint32_t* __RESTRICT src, uint32_t len)
{
uint32_t i;
for (i = 0U; i < len; ++i)
{
dst[i] = src[i];
}
}
/** Load the given number of MPU regions from a table.
* \param table Pointer to the MPU configuration table.
* \param cnt Amount of regions to be configured.
*/
__STATIC_INLINE void ARM_MPU_Load(ARM_MPU_Region_t const* table, uint32_t cnt)
{
const uint32_t rowWordSize = sizeof(ARM_MPU_Region_t)/4U;
while (cnt > MPU_TYPE_RALIASES) {
ARM_MPU_OrderedMemcpy(&(MPU->RBAR), &(table->RBAR), MPU_TYPE_RALIASES*rowWordSize);
table += MPU_TYPE_RALIASES;
cnt -= MPU_TYPE_RALIASES;
}
ARM_MPU_OrderedMemcpy(&(MPU->RBAR), &(table->RBAR), cnt*rowWordSize);
}
#endif
| 11,690 | C | 41.824176 | 143 | 0.674508 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/cmsis_gcc.h | /**************************************************************************//**
* @file cmsis_gcc.h
* @brief CMSIS compiler GCC header file
* @version V5.2.0
* @date 08. May 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef __CMSIS_GCC_H
#define __CMSIS_GCC_H
/* ignore some GCC warnings */
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wsign-conversion"
#pragma GCC diagnostic ignored "-Wconversion"
#pragma GCC diagnostic ignored "-Wunused-parameter"
/* Fallback for __has_builtin */
#ifndef __has_builtin
#define __has_builtin(x) (0)
#endif
/* CMSIS compiler specific defines */
#ifndef __ASM
#define __ASM __asm
#endif
#ifndef __INLINE
#define __INLINE inline
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static inline
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE __attribute__((always_inline)) static inline
#endif
#ifndef __NO_RETURN
#define __NO_RETURN __attribute__((__noreturn__))
#endif
#ifndef __USED
#define __USED __attribute__((used))
#endif
#ifndef __WEAK
#define __WEAK __attribute__((weak))
#endif
#ifndef __PACKED
#define __PACKED __attribute__((packed, aligned(1)))
#endif
#ifndef __PACKED_STRUCT
#define __PACKED_STRUCT struct __attribute__((packed, aligned(1)))
#endif
#ifndef __PACKED_UNION
#define __PACKED_UNION union __attribute__((packed, aligned(1)))
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpacked"
#pragma GCC diagnostic ignored "-Wattributes"
struct __attribute__((packed)) T_UINT32 { uint32_t v; };
#pragma GCC diagnostic pop
#define __UNALIGNED_UINT32(x) (((struct T_UINT32 *)(x))->v)
#endif
#ifndef __UNALIGNED_UINT16_WRITE
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpacked"
#pragma GCC diagnostic ignored "-Wattributes"
__PACKED_STRUCT T_UINT16_WRITE { uint16_t v; };
#pragma GCC diagnostic pop
#define __UNALIGNED_UINT16_WRITE(addr, val) (void)((((struct T_UINT16_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT16_READ
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpacked"
#pragma GCC diagnostic ignored "-Wattributes"
__PACKED_STRUCT T_UINT16_READ { uint16_t v; };
#pragma GCC diagnostic pop
#define __UNALIGNED_UINT16_READ(addr) (((const struct T_UINT16_READ *)(const void *)(addr))->v)
#endif
#ifndef __UNALIGNED_UINT32_WRITE
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpacked"
#pragma GCC diagnostic ignored "-Wattributes"
__PACKED_STRUCT T_UINT32_WRITE { uint32_t v; };
#pragma GCC diagnostic pop
#define __UNALIGNED_UINT32_WRITE(addr, val) (void)((((struct T_UINT32_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT32_READ
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wpacked"
#pragma GCC diagnostic ignored "-Wattributes"
__PACKED_STRUCT T_UINT32_READ { uint32_t v; };
#pragma GCC diagnostic pop
#define __UNALIGNED_UINT32_READ(addr) (((const struct T_UINT32_READ *)(const void *)(addr))->v)
#endif
#ifndef __ALIGNED
#define __ALIGNED(x) __attribute__((aligned(x)))
#endif
#ifndef __RESTRICT
#define __RESTRICT __restrict
#endif
#ifndef __COMPILER_BARRIER
#define __COMPILER_BARRIER() __ASM volatile("":::"memory")
#endif
/* ######################### Startup and Lowlevel Init ######################## */
#ifndef __PROGRAM_START
/**
\brief Initializes data and bss sections
\details This default implementations initialized all data and additional bss
sections relying on .copy.table and .zero.table specified properly
in the used linker script.
*/
__STATIC_FORCEINLINE __NO_RETURN void __cmsis_start(void)
{
extern void _start(void) __NO_RETURN;
typedef struct {
uint32_t const* src;
uint32_t* dest;
uint32_t wlen;
} __copy_table_t;
typedef struct {
uint32_t* dest;
uint32_t wlen;
} __zero_table_t;
extern const __copy_table_t __copy_table_start__;
extern const __copy_table_t __copy_table_end__;
extern const __zero_table_t __zero_table_start__;
extern const __zero_table_t __zero_table_end__;
for (__copy_table_t const* pTable = &__copy_table_start__; pTable < &__copy_table_end__; ++pTable) {
for(uint32_t i=0u; i<pTable->wlen; ++i) {
pTable->dest[i] = pTable->src[i];
}
}
for (__zero_table_t const* pTable = &__zero_table_start__; pTable < &__zero_table_end__; ++pTable) {
for(uint32_t i=0u; i<pTable->wlen; ++i) {
pTable->dest[i] = 0u;
}
}
_start();
}
#define __PROGRAM_START __cmsis_start
#endif
#ifndef __INITIAL_SP
#define __INITIAL_SP __StackTop
#endif
#ifndef __STACK_LIMIT
#define __STACK_LIMIT __StackLimit
#endif
#ifndef __VECTOR_TABLE
#define __VECTOR_TABLE __Vectors
#endif
#ifndef __VECTOR_TABLE_ATTRIBUTE
#define __VECTOR_TABLE_ATTRIBUTE __attribute((used, section(".vectors")))
#endif
/* ########################### Core Function Access ########################### */
/** \ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_RegAccFunctions CMSIS Core Register Access Functions
@{
*/
/**
\brief Enable IRQ Interrupts
\details Enables IRQ interrupts by clearing the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
__STATIC_FORCEINLINE void __enable_irq(void)
{
__ASM volatile ("cpsie i" : : : "memory");
}
/**
\brief Disable IRQ Interrupts
\details Disables IRQ interrupts by setting the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
__STATIC_FORCEINLINE void __disable_irq(void)
{
__ASM volatile ("cpsid i" : : : "memory");
}
/**
\brief Get Control Register
\details Returns the content of the Control Register.
\return Control Register value
*/
__STATIC_FORCEINLINE uint32_t __get_CONTROL(void)
{
uint32_t result;
__ASM volatile ("MRS %0, control" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Control Register (non-secure)
\details Returns the content of the non-secure Control Register when in secure mode.
\return non-secure Control Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_CONTROL_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, control_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Control Register
\details Writes the given value to the Control Register.
\param [in] control Control Register value to set
*/
__STATIC_FORCEINLINE void __set_CONTROL(uint32_t control)
{
__ASM volatile ("MSR control, %0" : : "r" (control) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Control Register (non-secure)
\details Writes the given value to the non-secure Control Register when in secure state.
\param [in] control Control Register value to set
*/
__STATIC_FORCEINLINE void __TZ_set_CONTROL_NS(uint32_t control)
{
__ASM volatile ("MSR control_ns, %0" : : "r" (control) : "memory");
}
#endif
/**
\brief Get IPSR Register
\details Returns the content of the IPSR Register.
\return IPSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_IPSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, ipsr" : "=r" (result) );
return(result);
}
/**
\brief Get APSR Register
\details Returns the content of the APSR Register.
\return APSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_APSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, apsr" : "=r" (result) );
return(result);
}
/**
\brief Get xPSR Register
\details Returns the content of the xPSR Register.
\return xPSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_xPSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, xpsr" : "=r" (result) );
return(result);
}
/**
\brief Get Process Stack Pointer
\details Returns the current value of the Process Stack Pointer (PSP).
\return PSP Register value
*/
__STATIC_FORCEINLINE uint32_t __get_PSP(void)
{
uint32_t result;
__ASM volatile ("MRS %0, psp" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Process Stack Pointer (non-secure)
\details Returns the current value of the non-secure Process Stack Pointer (PSP) when in secure state.
\return PSP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PSP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, psp_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Process Stack Pointer
\details Assigns the given value to the Process Stack Pointer (PSP).
\param [in] topOfProcStack Process Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __set_PSP(uint32_t topOfProcStack)
{
__ASM volatile ("MSR psp, %0" : : "r" (topOfProcStack) : );
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Process Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Process Stack Pointer (PSP) when in secure state.
\param [in] topOfProcStack Process Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_PSP_NS(uint32_t topOfProcStack)
{
__ASM volatile ("MSR psp_ns, %0" : : "r" (topOfProcStack) : );
}
#endif
/**
\brief Get Main Stack Pointer
\details Returns the current value of the Main Stack Pointer (MSP).
\return MSP Register value
*/
__STATIC_FORCEINLINE uint32_t __get_MSP(void)
{
uint32_t result;
__ASM volatile ("MRS %0, msp" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Main Stack Pointer (non-secure)
\details Returns the current value of the non-secure Main Stack Pointer (MSP) when in secure state.
\return MSP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_MSP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, msp_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Main Stack Pointer
\details Assigns the given value to the Main Stack Pointer (MSP).
\param [in] topOfMainStack Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __set_MSP(uint32_t topOfMainStack)
{
__ASM volatile ("MSR msp, %0" : : "r" (topOfMainStack) : );
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Main Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Main Stack Pointer (MSP) when in secure state.
\param [in] topOfMainStack Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_MSP_NS(uint32_t topOfMainStack)
{
__ASM volatile ("MSR msp_ns, %0" : : "r" (topOfMainStack) : );
}
#endif
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Stack Pointer (non-secure)
\details Returns the current value of the non-secure Stack Pointer (SP) when in secure state.
\return SP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_SP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, sp_ns" : "=r" (result) );
return(result);
}
/**
\brief Set Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Stack Pointer (SP) when in secure state.
\param [in] topOfStack Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_SP_NS(uint32_t topOfStack)
{
__ASM volatile ("MSR sp_ns, %0" : : "r" (topOfStack) : );
}
#endif
/**
\brief Get Priority Mask
\details Returns the current state of the priority mask bit from the Priority Mask Register.
\return Priority Mask value
*/
__STATIC_FORCEINLINE uint32_t __get_PRIMASK(void)
{
uint32_t result;
__ASM volatile ("MRS %0, primask" : "=r" (result) :: "memory");
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Priority Mask (non-secure)
\details Returns the current state of the non-secure priority mask bit from the Priority Mask Register when in secure state.
\return Priority Mask value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PRIMASK_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, primask_ns" : "=r" (result) :: "memory");
return(result);
}
#endif
/**
\brief Set Priority Mask
\details Assigns the given value to the Priority Mask Register.
\param [in] priMask Priority Mask
*/
__STATIC_FORCEINLINE void __set_PRIMASK(uint32_t priMask)
{
__ASM volatile ("MSR primask, %0" : : "r" (priMask) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Priority Mask (non-secure)
\details Assigns the given value to the non-secure Priority Mask Register when in secure state.
\param [in] priMask Priority Mask
*/
__STATIC_FORCEINLINE void __TZ_set_PRIMASK_NS(uint32_t priMask)
{
__ASM volatile ("MSR primask_ns, %0" : : "r" (priMask) : "memory");
}
#endif
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) )
/**
\brief Enable FIQ
\details Enables FIQ interrupts by clearing the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
__STATIC_FORCEINLINE void __enable_fault_irq(void)
{
__ASM volatile ("cpsie f" : : : "memory");
}
/**
\brief Disable FIQ
\details Disables FIQ interrupts by setting the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
__STATIC_FORCEINLINE void __disable_fault_irq(void)
{
__ASM volatile ("cpsid f" : : : "memory");
}
/**
\brief Get Base Priority
\details Returns the current value of the Base Priority register.
\return Base Priority register value
*/
__STATIC_FORCEINLINE uint32_t __get_BASEPRI(void)
{
uint32_t result;
__ASM volatile ("MRS %0, basepri" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Base Priority (non-secure)
\details Returns the current value of the non-secure Base Priority register when in secure state.
\return Base Priority register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_BASEPRI_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, basepri_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Base Priority
\details Assigns the given value to the Base Priority register.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __set_BASEPRI(uint32_t basePri)
{
__ASM volatile ("MSR basepri, %0" : : "r" (basePri) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Base Priority (non-secure)
\details Assigns the given value to the non-secure Base Priority register when in secure state.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __TZ_set_BASEPRI_NS(uint32_t basePri)
{
__ASM volatile ("MSR basepri_ns, %0" : : "r" (basePri) : "memory");
}
#endif
/**
\brief Set Base Priority with condition
\details Assigns the given value to the Base Priority register only if BASEPRI masking is disabled,
or the new value increases the BASEPRI priority level.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __set_BASEPRI_MAX(uint32_t basePri)
{
__ASM volatile ("MSR basepri_max, %0" : : "r" (basePri) : "memory");
}
/**
\brief Get Fault Mask
\details Returns the current value of the Fault Mask register.
\return Fault Mask register value
*/
__STATIC_FORCEINLINE uint32_t __get_FAULTMASK(void)
{
uint32_t result;
__ASM volatile ("MRS %0, faultmask" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Fault Mask (non-secure)
\details Returns the current value of the non-secure Fault Mask register when in secure state.
\return Fault Mask register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_FAULTMASK_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, faultmask_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Fault Mask
\details Assigns the given value to the Fault Mask register.
\param [in] faultMask Fault Mask value to set
*/
__STATIC_FORCEINLINE void __set_FAULTMASK(uint32_t faultMask)
{
__ASM volatile ("MSR faultmask, %0" : : "r" (faultMask) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Fault Mask (non-secure)
\details Assigns the given value to the non-secure Fault Mask register when in secure state.
\param [in] faultMask Fault Mask value to set
*/
__STATIC_FORCEINLINE void __TZ_set_FAULTMASK_NS(uint32_t faultMask)
{
__ASM volatile ("MSR faultmask_ns, %0" : : "r" (faultMask) : "memory");
}
#endif
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief Get Process Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always in non-secure
mode.
\details Returns the current value of the Process Stack Pointer Limit (PSPLIM).
\return PSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __get_PSPLIM(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, psplim" : "=r" (result) );
return result;
#endif
}
#if (defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Process Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always.
\details Returns the current value of the non-secure Process Stack Pointer Limit (PSPLIM) when in secure state.
\return PSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PSPLIM_NS(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, psplim_ns" : "=r" (result) );
return result;
#endif
}
#endif
/**
\brief Set Process Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored in non-secure
mode.
\details Assigns the given value to the Process Stack Pointer Limit (PSPLIM).
\param [in] ProcStackPtrLimit Process Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __set_PSPLIM(uint32_t ProcStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)ProcStackPtrLimit;
#else
__ASM volatile ("MSR psplim, %0" : : "r" (ProcStackPtrLimit));
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Process Stack Pointer (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored.
\details Assigns the given value to the non-secure Process Stack Pointer Limit (PSPLIM) when in secure state.
\param [in] ProcStackPtrLimit Process Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __TZ_set_PSPLIM_NS(uint32_t ProcStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)ProcStackPtrLimit;
#else
__ASM volatile ("MSR psplim_ns, %0\n" : : "r" (ProcStackPtrLimit));
#endif
}
#endif
/**
\brief Get Main Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always in non-secure
mode.
\details Returns the current value of the Main Stack Pointer Limit (MSPLIM).
\return MSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __get_MSPLIM(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, msplim" : "=r" (result) );
return result;
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Main Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always.
\details Returns the current value of the non-secure Main Stack Pointer Limit(MSPLIM) when in secure state.
\return MSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_MSPLIM_NS(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, msplim_ns" : "=r" (result) );
return result;
#endif
}
#endif
/**
\brief Set Main Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored in non-secure
mode.
\details Assigns the given value to the Main Stack Pointer Limit (MSPLIM).
\param [in] MainStackPtrLimit Main Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __set_MSPLIM(uint32_t MainStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
(void)MainStackPtrLimit;
#else
__ASM volatile ("MSR msplim, %0" : : "r" (MainStackPtrLimit));
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Main Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored.
\details Assigns the given value to the non-secure Main Stack Pointer Limit (MSPLIM) when in secure state.
\param [in] MainStackPtrLimit Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_MSPLIM_NS(uint32_t MainStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
(void)MainStackPtrLimit;
#else
__ASM volatile ("MSR msplim_ns, %0" : : "r" (MainStackPtrLimit));
#endif
}
#endif
#endif /* ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
/**
\brief Get FPSCR
\details Returns the current value of the Floating Point Status/Control register.
\return Floating Point Status/Control register value
*/
__STATIC_FORCEINLINE uint32_t __get_FPSCR(void)
{
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
#if __has_builtin(__builtin_arm_get_fpscr)
// Re-enable using built-in when GCC has been fixed
// || (__GNUC__ > 7) || (__GNUC__ == 7 && __GNUC_MINOR__ >= 2)
/* see https://gcc.gnu.org/ml/gcc-patches/2017-04/msg00443.html */
return __builtin_arm_get_fpscr();
#else
uint32_t result;
__ASM volatile ("VMRS %0, fpscr" : "=r" (result) );
return(result);
#endif
#else
return(0U);
#endif
}
/**
\brief Set FPSCR
\details Assigns the given value to the Floating Point Status/Control register.
\param [in] fpscr Floating Point Status/Control value to set
*/
__STATIC_FORCEINLINE void __set_FPSCR(uint32_t fpscr)
{
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
#if __has_builtin(__builtin_arm_set_fpscr)
// Re-enable using built-in when GCC has been fixed
// || (__GNUC__ > 7) || (__GNUC__ == 7 && __GNUC_MINOR__ >= 2)
/* see https://gcc.gnu.org/ml/gcc-patches/2017-04/msg00443.html */
__builtin_arm_set_fpscr(fpscr);
#else
__ASM volatile ("VMSR fpscr, %0" : : "r" (fpscr) : "vfpcc", "memory");
#endif
#else
(void)fpscr;
#endif
}
/*@} end of CMSIS_Core_RegAccFunctions */
/* ########################## Core Instruction Access ######################### */
/** \defgroup CMSIS_Core_InstructionInterface CMSIS Core Instruction Interface
Access to dedicated instructions
@{
*/
/* Define macros for porting to both thumb1 and thumb2.
* For thumb1, use low register (r0-r7), specified by constraint "l"
* Otherwise, use general registers, specified by constraint "r" */
#if defined (__thumb__) && !defined (__thumb2__)
#define __CMSIS_GCC_OUT_REG(r) "=l" (r)
#define __CMSIS_GCC_RW_REG(r) "+l" (r)
#define __CMSIS_GCC_USE_REG(r) "l" (r)
#else
#define __CMSIS_GCC_OUT_REG(r) "=r" (r)
#define __CMSIS_GCC_RW_REG(r) "+r" (r)
#define __CMSIS_GCC_USE_REG(r) "r" (r)
#endif
/**
\brief No Operation
\details No Operation does nothing. This instruction can be used for code alignment purposes.
*/
#define __NOP() __ASM volatile ("nop")
/**
\brief Wait For Interrupt
\details Wait For Interrupt is a hint instruction that suspends execution until one of a number of events occurs.
*/
#define __WFI() __ASM volatile ("wfi")
/**
\brief Wait For Event
\details Wait For Event is a hint instruction that permits the processor to enter
a low-power state until one of a number of events occurs.
*/
#define __WFE() __ASM volatile ("wfe")
/**
\brief Send Event
\details Send Event is a hint instruction. It causes an event to be signaled to the CPU.
*/
#define __SEV() __ASM volatile ("sev")
/**
\brief Instruction Synchronization Barrier
\details Instruction Synchronization Barrier flushes the pipeline in the processor,
so that all instructions following the ISB are fetched from cache or memory,
after the instruction has been completed.
*/
__STATIC_FORCEINLINE void __ISB(void)
{
__ASM volatile ("isb 0xF":::"memory");
}
/**
\brief Data Synchronization Barrier
\details Acts as a special kind of Data Memory Barrier.
It completes when all explicit memory accesses before this instruction complete.
*/
__STATIC_FORCEINLINE void __DSB(void)
{
__ASM volatile ("dsb 0xF":::"memory");
}
/**
\brief Data Memory Barrier
\details Ensures the apparent order of the explicit memory operations before
and after the instruction, without ensuring their completion.
*/
__STATIC_FORCEINLINE void __DMB(void)
{
__ASM volatile ("dmb 0xF":::"memory");
}
/**
\brief Reverse byte order (32 bit)
\details Reverses the byte order in unsigned integer value. For example, 0x12345678 becomes 0x78563412.
\param [in] value Value to reverse
\return Reversed value
*/
__STATIC_FORCEINLINE uint32_t __REV(uint32_t value)
{
#if (__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 5)
return __builtin_bswap32(value);
#else
uint32_t result;
__ASM volatile ("rev %0, %1" : __CMSIS_GCC_OUT_REG (result) : __CMSIS_GCC_USE_REG (value) );
return result;
#endif
}
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order within each halfword of a word. For example, 0x12345678 becomes 0x34127856.
\param [in] value Value to reverse
\return Reversed value
*/
__STATIC_FORCEINLINE uint32_t __REV16(uint32_t value)
{
uint32_t result;
__ASM volatile ("rev16 %0, %1" : __CMSIS_GCC_OUT_REG (result) : __CMSIS_GCC_USE_REG (value) );
return result;
}
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order in a 16-bit value and returns the signed 16-bit result. For example, 0x0080 becomes 0x8000.
\param [in] value Value to reverse
\return Reversed value
*/
__STATIC_FORCEINLINE int16_t __REVSH(int16_t value)
{
#if (__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)
return (int16_t)__builtin_bswap16(value);
#else
int16_t result;
__ASM volatile ("revsh %0, %1" : __CMSIS_GCC_OUT_REG (result) : __CMSIS_GCC_USE_REG (value) );
return result;
#endif
}
/**
\brief Rotate Right in unsigned value (32 bit)
\details Rotate Right (immediate) provides the value of the contents of a register rotated by a variable number of bits.
\param [in] op1 Value to rotate
\param [in] op2 Number of Bits to rotate
\return Rotated value
*/
__STATIC_FORCEINLINE uint32_t __ROR(uint32_t op1, uint32_t op2)
{
op2 %= 32U;
if (op2 == 0U)
{
return op1;
}
return (op1 >> op2) | (op1 << (32U - op2));
}
/**
\brief Breakpoint
\details Causes the processor to enter Debug state.
Debug tools can use this to investigate system state when the instruction at a particular address is reached.
\param [in] value is ignored by the processor.
If required, a debugger can use it to store additional information about the breakpoint.
*/
#define __BKPT(value) __ASM volatile ("bkpt "#value)
/**
\brief Reverse bit order of value
\details Reverses the bit order of the given value.
\param [in] value Value to reverse
\return Reversed value
*/
__STATIC_FORCEINLINE uint32_t __RBIT(uint32_t value)
{
uint32_t result;
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) )
__ASM volatile ("rbit %0, %1" : "=r" (result) : "r" (value) );
#else
uint32_t s = (4U /*sizeof(v)*/ * 8U) - 1U; /* extra shift needed at end */
result = value; /* r will be reversed bits of v; first get LSB of v */
for (value >>= 1U; value != 0U; value >>= 1U)
{
result <<= 1U;
result |= value & 1U;
s--;
}
result <<= s; /* shift when v's highest bits are zero */
#endif
return result;
}
/**
\brief Count leading zeros
\details Counts the number of leading zeros of a data value.
\param [in] value Value to count the leading zeros
\return number of leading zeros in value
*/
__STATIC_FORCEINLINE uint8_t __CLZ(uint32_t value)
{
/* Even though __builtin_clz produces a CLZ instruction on ARM, formally
__builtin_clz(0) is undefined behaviour, so handle this case specially.
This guarantees ARM-compatible results if happening to compile on a non-ARM
target, and ensures the compiler doesn't decide to activate any
optimisations using the logic "value was passed to __builtin_clz, so it
is non-zero".
ARM GCC 7.3 and possibly earlier will optimise this test away, leaving a
single CLZ instruction.
*/
if (value == 0U)
{
return 32U;
}
return __builtin_clz(value);
}
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief LDR Exclusive (8 bit)
\details Executes a exclusive LDR instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDREXB(volatile uint8_t *addr)
{
uint32_t result;
#if (__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)
__ASM volatile ("ldrexb %0, %1" : "=r" (result) : "Q" (*addr) );
#else
/* Prior to GCC 4.8, "Q" will be expanded to [rx, #0] which is not
accepted by assembler. So has to use following less efficient pattern.
*/
__ASM volatile ("ldrexb %0, [%1]" : "=r" (result) : "r" (addr) : "memory" );
#endif
return ((uint8_t) result); /* Add explicit type cast here */
}
/**
\brief LDR Exclusive (16 bit)
\details Executes a exclusive LDR instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDREXH(volatile uint16_t *addr)
{
uint32_t result;
#if (__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)
__ASM volatile ("ldrexh %0, %1" : "=r" (result) : "Q" (*addr) );
#else
/* Prior to GCC 4.8, "Q" will be expanded to [rx, #0] which is not
accepted by assembler. So has to use following less efficient pattern.
*/
__ASM volatile ("ldrexh %0, [%1]" : "=r" (result) : "r" (addr) : "memory" );
#endif
return ((uint16_t) result); /* Add explicit type cast here */
}
/**
\brief LDR Exclusive (32 bit)
\details Executes a exclusive LDR instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDREXW(volatile uint32_t *addr)
{
uint32_t result;
__ASM volatile ("ldrex %0, %1" : "=r" (result) : "Q" (*addr) );
return(result);
}
/**
\brief STR Exclusive (8 bit)
\details Executes a exclusive STR instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
__STATIC_FORCEINLINE uint32_t __STREXB(uint8_t value, volatile uint8_t *addr)
{
uint32_t result;
__ASM volatile ("strexb %0, %2, %1" : "=&r" (result), "=Q" (*addr) : "r" ((uint32_t)value) );
return(result);
}
/**
\brief STR Exclusive (16 bit)
\details Executes a exclusive STR instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
__STATIC_FORCEINLINE uint32_t __STREXH(uint16_t value, volatile uint16_t *addr)
{
uint32_t result;
__ASM volatile ("strexh %0, %2, %1" : "=&r" (result), "=Q" (*addr) : "r" ((uint32_t)value) );
return(result);
}
/**
\brief STR Exclusive (32 bit)
\details Executes a exclusive STR instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
__STATIC_FORCEINLINE uint32_t __STREXW(uint32_t value, volatile uint32_t *addr)
{
uint32_t result;
__ASM volatile ("strex %0, %2, %1" : "=&r" (result), "=Q" (*addr) : "r" (value) );
return(result);
}
/**
\brief Remove the exclusive lock
\details Removes the exclusive lock which is created by LDREX.
*/
__STATIC_FORCEINLINE void __CLREX(void)
{
__ASM volatile ("clrex" ::: "memory");
}
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) )
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] ARG1 Value to be saturated
\param [in] ARG2 Bit position to saturate to (1..32)
\return Saturated value
*/
#define __SSAT(ARG1,ARG2) \
__extension__ \
({ \
int32_t __RES, __ARG1 = (ARG1); \
__ASM ("ssat %0, %1, %2" : "=r" (__RES) : "I" (ARG2), "r" (__ARG1) ); \
__RES; \
})
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] ARG1 Value to be saturated
\param [in] ARG2 Bit position to saturate to (0..31)
\return Saturated value
*/
#define __USAT(ARG1,ARG2) \
__extension__ \
({ \
uint32_t __RES, __ARG1 = (ARG1); \
__ASM ("usat %0, %1, %2" : "=r" (__RES) : "I" (ARG2), "r" (__ARG1) ); \
__RES; \
})
/**
\brief Rotate Right with Extend (32 bit)
\details Moves each bit of a bitstring right by one bit.
The carry input is shifted in at the left end of the bitstring.
\param [in] value Value to rotate
\return Rotated value
*/
__STATIC_FORCEINLINE uint32_t __RRX(uint32_t value)
{
uint32_t result;
__ASM volatile ("rrx %0, %1" : __CMSIS_GCC_OUT_REG (result) : __CMSIS_GCC_USE_REG (value) );
return(result);
}
/**
\brief LDRT Unprivileged (8 bit)
\details Executes a Unprivileged LDRT instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDRBT(volatile uint8_t *ptr)
{
uint32_t result;
#if (__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)
__ASM volatile ("ldrbt %0, %1" : "=r" (result) : "Q" (*ptr) );
#else
/* Prior to GCC 4.8, "Q" will be expanded to [rx, #0] which is not
accepted by assembler. So has to use following less efficient pattern.
*/
__ASM volatile ("ldrbt %0, [%1]" : "=r" (result) : "r" (ptr) : "memory" );
#endif
return ((uint8_t) result); /* Add explicit type cast here */
}
/**
\brief LDRT Unprivileged (16 bit)
\details Executes a Unprivileged LDRT instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDRHT(volatile uint16_t *ptr)
{
uint32_t result;
#if (__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)
__ASM volatile ("ldrht %0, %1" : "=r" (result) : "Q" (*ptr) );
#else
/* Prior to GCC 4.8, "Q" will be expanded to [rx, #0] which is not
accepted by assembler. So has to use following less efficient pattern.
*/
__ASM volatile ("ldrht %0, [%1]" : "=r" (result) : "r" (ptr) : "memory" );
#endif
return ((uint16_t) result); /* Add explicit type cast here */
}
/**
\brief LDRT Unprivileged (32 bit)
\details Executes a Unprivileged LDRT instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDRT(volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("ldrt %0, %1" : "=r" (result) : "Q" (*ptr) );
return(result);
}
/**
\brief STRT Unprivileged (8 bit)
\details Executes a Unprivileged STRT instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRBT(uint8_t value, volatile uint8_t *ptr)
{
__ASM volatile ("strbt %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief STRT Unprivileged (16 bit)
\details Executes a Unprivileged STRT instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRHT(uint16_t value, volatile uint16_t *ptr)
{
__ASM volatile ("strht %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief STRT Unprivileged (32 bit)
\details Executes a Unprivileged STRT instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRT(uint32_t value, volatile uint32_t *ptr)
{
__ASM volatile ("strt %1, %0" : "=Q" (*ptr) : "r" (value) );
}
#else /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (1..32)
\return Saturated value
*/
__STATIC_FORCEINLINE int32_t __SSAT(int32_t val, uint32_t sat)
{
if ((sat >= 1U) && (sat <= 32U))
{
const int32_t max = (int32_t)((1U << (sat - 1U)) - 1U);
const int32_t min = -1 - max ;
if (val > max)
{
return max;
}
else if (val < min)
{
return min;
}
}
return val;
}
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (0..31)
\return Saturated value
*/
__STATIC_FORCEINLINE uint32_t __USAT(int32_t val, uint32_t sat)
{
if (sat <= 31U)
{
const uint32_t max = ((1U << sat) - 1U);
if (val > (int32_t)max)
{
return max;
}
else if (val < 0)
{
return 0U;
}
}
return (uint32_t)val;
}
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief Load-Acquire (8 bit)
\details Executes a LDAB instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDAB(volatile uint8_t *ptr)
{
uint32_t result;
__ASM volatile ("ldab %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint8_t) result);
}
/**
\brief Load-Acquire (16 bit)
\details Executes a LDAH instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDAH(volatile uint16_t *ptr)
{
uint32_t result;
__ASM volatile ("ldah %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint16_t) result);
}
/**
\brief Load-Acquire (32 bit)
\details Executes a LDA instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDA(volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("lda %0, %1" : "=r" (result) : "Q" (*ptr) );
return(result);
}
/**
\brief Store-Release (8 bit)
\details Executes a STLB instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STLB(uint8_t value, volatile uint8_t *ptr)
{
__ASM volatile ("stlb %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Store-Release (16 bit)
\details Executes a STLH instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STLH(uint16_t value, volatile uint16_t *ptr)
{
__ASM volatile ("stlh %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Store-Release (32 bit)
\details Executes a STL instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STL(uint32_t value, volatile uint32_t *ptr)
{
__ASM volatile ("stl %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Load-Acquire Exclusive (8 bit)
\details Executes a LDAB exclusive instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDAEXB(volatile uint8_t *ptr)
{
uint32_t result;
__ASM volatile ("ldaexb %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint8_t) result);
}
/**
\brief Load-Acquire Exclusive (16 bit)
\details Executes a LDAH exclusive instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDAEXH(volatile uint16_t *ptr)
{
uint32_t result;
__ASM volatile ("ldaexh %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint16_t) result);
}
/**
\brief Load-Acquire Exclusive (32 bit)
\details Executes a LDA exclusive instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDAEX(volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("ldaex %0, %1" : "=r" (result) : "Q" (*ptr) );
return(result);
}
/**
\brief Store-Release Exclusive (8 bit)
\details Executes a STLB exclusive instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
__STATIC_FORCEINLINE uint32_t __STLEXB(uint8_t value, volatile uint8_t *ptr)
{
uint32_t result;
__ASM volatile ("stlexb %0, %2, %1" : "=&r" (result), "=Q" (*ptr) : "r" ((uint32_t)value) );
return(result);
}
/**
\brief Store-Release Exclusive (16 bit)
\details Executes a STLH exclusive instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
__STATIC_FORCEINLINE uint32_t __STLEXH(uint16_t value, volatile uint16_t *ptr)
{
uint32_t result;
__ASM volatile ("stlexh %0, %2, %1" : "=&r" (result), "=Q" (*ptr) : "r" ((uint32_t)value) );
return(result);
}
/**
\brief Store-Release Exclusive (32 bit)
\details Executes a STL exclusive instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
__STATIC_FORCEINLINE uint32_t __STLEX(uint32_t value, volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("stlex %0, %2, %1" : "=&r" (result), "=Q" (*ptr) : "r" ((uint32_t)value) );
return(result);
}
#endif /* ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
/*@}*/ /* end of group CMSIS_Core_InstructionInterface */
/* ################### Compiler specific Intrinsics ########################### */
/** \defgroup CMSIS_SIMD_intrinsics CMSIS SIMD Intrinsics
Access to dedicated SIMD instructions
@{
*/
#if (defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1))
__STATIC_FORCEINLINE uint32_t __SADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("ssub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("ssub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("ssax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USAD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usad8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USADA8(uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("usada8 %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
#define __SSAT16(ARG1,ARG2) \
({ \
int32_t __RES, __ARG1 = (ARG1); \
__ASM ("ssat16 %0, %1, %2" : "=r" (__RES) : "I" (ARG2), "r" (__ARG1) ); \
__RES; \
})
#define __USAT16(ARG1,ARG2) \
({ \
uint32_t __RES, __ARG1 = (ARG1); \
__ASM ("usat16 %0, %1, %2" : "=r" (__RES) : "I" (ARG2), "r" (__ARG1) ); \
__RES; \
})
__STATIC_FORCEINLINE uint32_t __UXTB16(uint32_t op1)
{
uint32_t result;
__ASM volatile ("uxtb16 %0, %1" : "=r" (result) : "r" (op1));
return(result);
}
__STATIC_FORCEINLINE uint32_t __UXTAB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uxtab16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SXTB16(uint32_t op1)
{
uint32_t result;
__ASM volatile ("sxtb16 %0, %1" : "=r" (result) : "r" (op1));
return(result);
}
__STATIC_FORCEINLINE uint32_t __SXTAB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sxtab16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMUAD (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smuad %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMUADX (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smuadx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLAD (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smlad %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLADX (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smladx %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint64_t __SMLALD (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlald %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlald %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint64_t __SMLALDX (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlaldx %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlaldx %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint32_t __SMUSD (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smusd %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMUSDX (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smusdx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLSD (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smlsd %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLSDX (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smlsdx %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint64_t __SMLSLD (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlsld %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlsld %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint64_t __SMLSLDX (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlsldx %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlsldx %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint32_t __SEL (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sel %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE int32_t __QADD( int32_t op1, int32_t op2)
{
int32_t result;
__ASM volatile ("qadd %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE int32_t __QSUB( int32_t op1, int32_t op2)
{
int32_t result;
__ASM volatile ("qsub %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
#if 0
#define __PKHBT(ARG1,ARG2,ARG3) \
({ \
uint32_t __RES, __ARG1 = (ARG1), __ARG2 = (ARG2); \
__ASM ("pkhbt %0, %1, %2, lsl %3" : "=r" (__RES) : "r" (__ARG1), "r" (__ARG2), "I" (ARG3) ); \
__RES; \
})
#define __PKHTB(ARG1,ARG2,ARG3) \
({ \
uint32_t __RES, __ARG1 = (ARG1), __ARG2 = (ARG2); \
if (ARG3 == 0) \
__ASM ("pkhtb %0, %1, %2" : "=r" (__RES) : "r" (__ARG1), "r" (__ARG2) ); \
else \
__ASM ("pkhtb %0, %1, %2, asr %3" : "=r" (__RES) : "r" (__ARG1), "r" (__ARG2), "I" (ARG3) ); \
__RES; \
})
#endif
#define __PKHBT(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0x0000FFFFUL) | \
((((uint32_t)(ARG2)) << (ARG3)) & 0xFFFF0000UL) )
#define __PKHTB(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0xFFFF0000UL) | \
((((uint32_t)(ARG2)) >> (ARG3)) & 0x0000FFFFUL) )
__STATIC_FORCEINLINE int32_t __SMMLA (int32_t op1, int32_t op2, int32_t op3)
{
int32_t result;
__ASM volatile ("smmla %0, %1, %2, %3" : "=r" (result): "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
#endif /* (__ARM_FEATURE_DSP == 1) */
/*@} end of group CMSIS_SIMD_intrinsics */
#pragma GCC diagnostic pop
#endif /* __CMSIS_GCC_H */
| 62,627 | C | 27.874136 | 143 | 0.598049 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm23.h | /**************************************************************************//**
* @file core_cm23.h
* @brief CMSIS Cortex-M23 Core Peripheral Access Layer Header File
* @version V5.0.8
* @date 12. November 2018
******************************************************************************/
/*
* Copyright (c) 2009-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM23_H_GENERIC
#define __CORE_CM23_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M23
@{
*/
#include "cmsis_version.h"
/* CMSIS definitions */
#define __CM23_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM23_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM23_CMSIS_VERSION ((__CM23_CMSIS_VERSION_MAIN << 16U) | \
__CM23_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (23U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM23_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM23_H_DEPENDANT
#define __CORE_CM23_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM23_REV
#define __CM23_REV 0x0000U
#warning "__CM23_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __SAUREGION_PRESENT
#define __SAUREGION_PRESENT 0U
#warning "__SAUREGION_PRESENT not defined in device header file; using default!"
#endif
#ifndef __VTOR_PRESENT
#define __VTOR_PRESENT 0U
#warning "__VTOR_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 2U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#ifndef __ETM_PRESENT
#define __ETM_PRESENT 0U
#warning "__ETM_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MTB_PRESENT
#define __MTB_PRESENT 0U
#warning "__MTB_PRESENT not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M23 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core SAU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:28; /*!< bit: 0..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:15; /*!< bit: 9..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t _reserved1:3; /*!< bit: 25..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack-pointer select */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[16U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[16U];
__IOM uint32_t ICER[16U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[16U];
__IOM uint32_t ISPR[16U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[16U];
__IOM uint32_t ICPR[16U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[16U];
__IOM uint32_t IABR[16U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[16U];
__IOM uint32_t ITNS[16U]; /*!< Offset: 0x280 (R/W) Interrupt Non-Secure State Register */
uint32_t RESERVED5[16U];
__IOM uint32_t IPR[124U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register */
} NVIC_Type;
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
#else
uint32_t RESERVED0;
#endif
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
uint32_t RESERVED1;
__IOM uint32_t SHPR[2U]; /*!< Offset: 0x01C (R/W) System Handlers Priority Registers. [0] is RESERVED */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_PENDNMISET_Pos 31U /*!< SCB ICSR: PENDNMISET Position */
#define SCB_ICSR_PENDNMISET_Msk (1UL << SCB_ICSR_PENDNMISET_Pos) /*!< SCB ICSR: PENDNMISET Mask */
#define SCB_ICSR_NMIPENDSET_Pos SCB_ICSR_PENDNMISET_Pos /*!< SCB ICSR: NMIPENDSET Position, backward compatibility */
#define SCB_ICSR_NMIPENDSET_Msk SCB_ICSR_PENDNMISET_Msk /*!< SCB ICSR: NMIPENDSET Mask, backward compatibility */
#define SCB_ICSR_PENDNMICLR_Pos 30U /*!< SCB ICSR: PENDNMICLR Position */
#define SCB_ICSR_PENDNMICLR_Msk (1UL << SCB_ICSR_PENDNMICLR_Pos) /*!< SCB ICSR: PENDNMICLR Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_STTNS_Pos 24U /*!< SCB ICSR: STTNS Position (Security Extension) */
#define SCB_ICSR_STTNS_Msk (1UL << SCB_ICSR_STTNS_Pos) /*!< SCB ICSR: STTNS Mask (Security Extension) */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
#endif
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIS_Pos 14U /*!< SCB AIRCR: PRIS Position */
#define SCB_AIRCR_PRIS_Msk (1UL << SCB_AIRCR_PRIS_Pos) /*!< SCB AIRCR: PRIS Mask */
#define SCB_AIRCR_BFHFNMINS_Pos 13U /*!< SCB AIRCR: BFHFNMINS Position */
#define SCB_AIRCR_BFHFNMINS_Msk (1UL << SCB_AIRCR_BFHFNMINS_Pos) /*!< SCB AIRCR: BFHFNMINS Mask */
#define SCB_AIRCR_SYSRESETREQS_Pos 3U /*!< SCB AIRCR: SYSRESETREQS Position */
#define SCB_AIRCR_SYSRESETREQS_Msk (1UL << SCB_AIRCR_SYSRESETREQS_Pos) /*!< SCB AIRCR: SYSRESETREQS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEPS_Pos 3U /*!< SCB SCR: SLEEPDEEPS Position */
#define SCB_SCR_SLEEPDEEPS_Msk (1UL << SCB_SCR_SLEEPDEEPS_Pos) /*!< SCB SCR: SLEEPDEEPS Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_BP_Pos 18U /*!< SCB CCR: BP Position */
#define SCB_CCR_BP_Msk (1UL << SCB_CCR_BP_Pos) /*!< SCB CCR: BP Mask */
#define SCB_CCR_IC_Pos 17U /*!< SCB CCR: IC Position */
#define SCB_CCR_IC_Msk (1UL << SCB_CCR_IC_Pos) /*!< SCB CCR: IC Mask */
#define SCB_CCR_DC_Pos 16U /*!< SCB CCR: DC Position */
#define SCB_CCR_DC_Msk (1UL << SCB_CCR_DC_Pos) /*!< SCB CCR: DC Mask */
#define SCB_CCR_STKOFHFNMIGN_Pos 10U /*!< SCB CCR: STKOFHFNMIGN Position */
#define SCB_CCR_STKOFHFNMIGN_Msk (1UL << SCB_CCR_STKOFHFNMIGN_Pos) /*!< SCB CCR: STKOFHFNMIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_HARDFAULTPENDED_Pos 21U /*!< SCB SHCSR: HARDFAULTPENDED Position */
#define SCB_SHCSR_HARDFAULTPENDED_Msk (1UL << SCB_SHCSR_HARDFAULTPENDED_Pos) /*!< SCB SHCSR: HARDFAULTPENDED Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_NMIACT_Pos 5U /*!< SCB SHCSR: NMIACT Position */
#define SCB_SHCSR_NMIACT_Msk (1UL << SCB_SHCSR_NMIACT_Pos) /*!< SCB SHCSR: NMIACT Mask */
#define SCB_SHCSR_HARDFAULTACT_Pos 2U /*!< SCB SHCSR: HARDFAULTACT Position */
#define SCB_SHCSR_HARDFAULTACT_Msk (1UL << SCB_SHCSR_HARDFAULTACT_Pos) /*!< SCB SHCSR: HARDFAULTACT Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
uint32_t RESERVED0[6U];
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
uint32_t RESERVED1[1U];
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
uint32_t RESERVED3[1U];
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED4[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
uint32_t RESERVED5[1U];
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED6[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
uint32_t RESERVED7[1U];
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
uint32_t RESERVED8[1U];
__IOM uint32_t COMP4; /*!< Offset: 0x060 (R/W) Comparator Register 4 */
uint32_t RESERVED9[1U];
__IOM uint32_t FUNCTION4; /*!< Offset: 0x068 (R/W) Function Register 4 */
uint32_t RESERVED10[1U];
__IOM uint32_t COMP5; /*!< Offset: 0x070 (R/W) Comparator Register 5 */
uint32_t RESERVED11[1U];
__IOM uint32_t FUNCTION5; /*!< Offset: 0x078 (R/W) Function Register 5 */
uint32_t RESERVED12[1U];
__IOM uint32_t COMP6; /*!< Offset: 0x080 (R/W) Comparator Register 6 */
uint32_t RESERVED13[1U];
__IOM uint32_t FUNCTION6; /*!< Offset: 0x088 (R/W) Function Register 6 */
uint32_t RESERVED14[1U];
__IOM uint32_t COMP7; /*!< Offset: 0x090 (R/W) Comparator Register 7 */
uint32_t RESERVED15[1U];
__IOM uint32_t FUNCTION7; /*!< Offset: 0x098 (R/W) Function Register 7 */
uint32_t RESERVED16[1U];
__IOM uint32_t COMP8; /*!< Offset: 0x0A0 (R/W) Comparator Register 8 */
uint32_t RESERVED17[1U];
__IOM uint32_t FUNCTION8; /*!< Offset: 0x0A8 (R/W) Function Register 8 */
uint32_t RESERVED18[1U];
__IOM uint32_t COMP9; /*!< Offset: 0x0B0 (R/W) Comparator Register 9 */
uint32_t RESERVED19[1U];
__IOM uint32_t FUNCTION9; /*!< Offset: 0x0B8 (R/W) Function Register 9 */
uint32_t RESERVED20[1U];
__IOM uint32_t COMP10; /*!< Offset: 0x0C0 (R/W) Comparator Register 10 */
uint32_t RESERVED21[1U];
__IOM uint32_t FUNCTION10; /*!< Offset: 0x0C8 (R/W) Function Register 10 */
uint32_t RESERVED22[1U];
__IOM uint32_t COMP11; /*!< Offset: 0x0D0 (R/W) Comparator Register 11 */
uint32_t RESERVED23[1U];
__IOM uint32_t FUNCTION11; /*!< Offset: 0x0D8 (R/W) Function Register 11 */
uint32_t RESERVED24[1U];
__IOM uint32_t COMP12; /*!< Offset: 0x0E0 (R/W) Comparator Register 12 */
uint32_t RESERVED25[1U];
__IOM uint32_t FUNCTION12; /*!< Offset: 0x0E8 (R/W) Function Register 12 */
uint32_t RESERVED26[1U];
__IOM uint32_t COMP13; /*!< Offset: 0x0F0 (R/W) Comparator Register 13 */
uint32_t RESERVED27[1U];
__IOM uint32_t FUNCTION13; /*!< Offset: 0x0F8 (R/W) Function Register 13 */
uint32_t RESERVED28[1U];
__IOM uint32_t COMP14; /*!< Offset: 0x100 (R/W) Comparator Register 14 */
uint32_t RESERVED29[1U];
__IOM uint32_t FUNCTION14; /*!< Offset: 0x108 (R/W) Function Register 14 */
uint32_t RESERVED30[1U];
__IOM uint32_t COMP15; /*!< Offset: 0x110 (R/W) Comparator Register 15 */
uint32_t RESERVED31[1U];
__IOM uint32_t FUNCTION15; /*!< Offset: 0x118 (R/W) Function Register 15 */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_ID_Pos 27U /*!< DWT FUNCTION: ID Position */
#define DWT_FUNCTION_ID_Msk (0x1FUL << DWT_FUNCTION_ID_Pos) /*!< DWT FUNCTION: ID Mask */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_ACTION_Pos 4U /*!< DWT FUNCTION: ACTION Position */
#define DWT_FUNCTION_ACTION_Msk (0x3UL << DWT_FUNCTION_ACTION_Pos) /*!< DWT FUNCTION: ACTION Mask */
#define DWT_FUNCTION_MATCH_Pos 0U /*!< DWT FUNCTION: MATCH Position */
#define DWT_FUNCTION_MATCH_Msk (0xFUL /*<< DWT_FUNCTION_MATCH_Pos*/) /*!< DWT FUNCTION: MATCH Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Size Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Size Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IOM uint32_t PSCR; /*!< Offset: 0x308 (R/W) Periodic Synchronization Control Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER Register */
__IM uint32_t ITFTTD0; /*!< Offset: 0xEEC (R/ ) Integration Test FIFO Test Data 0 Register */
__IOM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/W) Integration Test ATB Control Register 2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) Integration Test ATB Control Register 0 */
__IM uint32_t ITFTTD1; /*!< Offset: 0xEFC (R/ ) Integration Test FIFO Test Data 1 Register */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) Device Configuration Register */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) Device Type Identifier Register */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_FOnMan_Pos 6U /*!< TPI FFCR: FOnMan Position */
#define TPI_FFCR_FOnMan_Msk (0x1UL << TPI_FFCR_FOnMan_Pos) /*!< TPI FFCR: FOnMan Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration Test FIFO Test Data 0 Register Definitions */
#define TPI_ITFTTD0_ATB_IF2_ATVALID_Pos 29U /*!< TPI ITFTTD0: ATB Interface 2 ATVALIDPosition */
#define TPI_ITFTTD0_ATB_IF2_ATVALID_Msk (0x3UL << TPI_ITFTTD0_ATB_IF2_ATVALID_Pos) /*!< TPI ITFTTD0: ATB Interface 2 ATVALID Mask */
#define TPI_ITFTTD0_ATB_IF2_bytecount_Pos 27U /*!< TPI ITFTTD0: ATB Interface 2 byte count Position */
#define TPI_ITFTTD0_ATB_IF2_bytecount_Msk (0x3UL << TPI_ITFTTD0_ATB_IF2_bytecount_Pos) /*!< TPI ITFTTD0: ATB Interface 2 byte count Mask */
#define TPI_ITFTTD0_ATB_IF1_ATVALID_Pos 26U /*!< TPI ITFTTD0: ATB Interface 1 ATVALID Position */
#define TPI_ITFTTD0_ATB_IF1_ATVALID_Msk (0x3UL << TPI_ITFTTD0_ATB_IF1_ATVALID_Pos) /*!< TPI ITFTTD0: ATB Interface 1 ATVALID Mask */
#define TPI_ITFTTD0_ATB_IF1_bytecount_Pos 24U /*!< TPI ITFTTD0: ATB Interface 1 byte count Position */
#define TPI_ITFTTD0_ATB_IF1_bytecount_Msk (0x3UL << TPI_ITFTTD0_ATB_IF1_bytecount_Pos) /*!< TPI ITFTTD0: ATB Interface 1 byte countt Mask */
#define TPI_ITFTTD0_ATB_IF1_data2_Pos 16U /*!< TPI ITFTTD0: ATB Interface 1 data2 Position */
#define TPI_ITFTTD0_ATB_IF1_data2_Msk (0xFFUL << TPI_ITFTTD0_ATB_IF1_data1_Pos) /*!< TPI ITFTTD0: ATB Interface 1 data2 Mask */
#define TPI_ITFTTD0_ATB_IF1_data1_Pos 8U /*!< TPI ITFTTD0: ATB Interface 1 data1 Position */
#define TPI_ITFTTD0_ATB_IF1_data1_Msk (0xFFUL << TPI_ITFTTD0_ATB_IF1_data1_Pos) /*!< TPI ITFTTD0: ATB Interface 1 data1 Mask */
#define TPI_ITFTTD0_ATB_IF1_data0_Pos 0U /*!< TPI ITFTTD0: ATB Interface 1 data0 Position */
#define TPI_ITFTTD0_ATB_IF1_data0_Msk (0xFFUL /*<< TPI_ITFTTD0_ATB_IF1_data0_Pos*/) /*!< TPI ITFTTD0: ATB Interface 1 data0 Mask */
/* TPI Integration Test ATB Control Register 2 Register Definitions */
#define TPI_ITATBCTR2_AFVALID2S_Pos 1U /*!< TPI ITATBCTR2: AFVALID2S Position */
#define TPI_ITATBCTR2_AFVALID2S_Msk (0x1UL << TPI_ITATBCTR2_AFVALID2S_Pos) /*!< TPI ITATBCTR2: AFVALID2SS Mask */
#define TPI_ITATBCTR2_AFVALID1S_Pos 1U /*!< TPI ITATBCTR2: AFVALID1S Position */
#define TPI_ITATBCTR2_AFVALID1S_Msk (0x1UL << TPI_ITATBCTR2_AFVALID1S_Pos) /*!< TPI ITATBCTR2: AFVALID1SS Mask */
#define TPI_ITATBCTR2_ATREADY2S_Pos 0U /*!< TPI ITATBCTR2: ATREADY2S Position */
#define TPI_ITATBCTR2_ATREADY2S_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY2S_Pos*/) /*!< TPI ITATBCTR2: ATREADY2S Mask */
#define TPI_ITATBCTR2_ATREADY1S_Pos 0U /*!< TPI ITATBCTR2: ATREADY1S Position */
#define TPI_ITATBCTR2_ATREADY1S_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY1S_Pos*/) /*!< TPI ITATBCTR2: ATREADY1S Mask */
/* TPI Integration Test FIFO Test Data 1 Register Definitions */
#define TPI_ITFTTD1_ATB_IF2_ATVALID_Pos 29U /*!< TPI ITFTTD1: ATB Interface 2 ATVALID Position */
#define TPI_ITFTTD1_ATB_IF2_ATVALID_Msk (0x3UL << TPI_ITFTTD1_ATB_IF2_ATVALID_Pos) /*!< TPI ITFTTD1: ATB Interface 2 ATVALID Mask */
#define TPI_ITFTTD1_ATB_IF2_bytecount_Pos 27U /*!< TPI ITFTTD1: ATB Interface 2 byte count Position */
#define TPI_ITFTTD1_ATB_IF2_bytecount_Msk (0x3UL << TPI_ITFTTD1_ATB_IF2_bytecount_Pos) /*!< TPI ITFTTD1: ATB Interface 2 byte count Mask */
#define TPI_ITFTTD1_ATB_IF1_ATVALID_Pos 26U /*!< TPI ITFTTD1: ATB Interface 1 ATVALID Position */
#define TPI_ITFTTD1_ATB_IF1_ATVALID_Msk (0x3UL << TPI_ITFTTD1_ATB_IF1_ATVALID_Pos) /*!< TPI ITFTTD1: ATB Interface 1 ATVALID Mask */
#define TPI_ITFTTD1_ATB_IF1_bytecount_Pos 24U /*!< TPI ITFTTD1: ATB Interface 1 byte count Position */
#define TPI_ITFTTD1_ATB_IF1_bytecount_Msk (0x3UL << TPI_ITFTTD1_ATB_IF1_bytecount_Pos) /*!< TPI ITFTTD1: ATB Interface 1 byte countt Mask */
#define TPI_ITFTTD1_ATB_IF2_data2_Pos 16U /*!< TPI ITFTTD1: ATB Interface 2 data2 Position */
#define TPI_ITFTTD1_ATB_IF2_data2_Msk (0xFFUL << TPI_ITFTTD1_ATB_IF2_data1_Pos) /*!< TPI ITFTTD1: ATB Interface 2 data2 Mask */
#define TPI_ITFTTD1_ATB_IF2_data1_Pos 8U /*!< TPI ITFTTD1: ATB Interface 2 data1 Position */
#define TPI_ITFTTD1_ATB_IF2_data1_Msk (0xFFUL << TPI_ITFTTD1_ATB_IF2_data1_Pos) /*!< TPI ITFTTD1: ATB Interface 2 data1 Mask */
#define TPI_ITFTTD1_ATB_IF2_data0_Pos 0U /*!< TPI ITFTTD1: ATB Interface 2 data0 Position */
#define TPI_ITFTTD1_ATB_IF2_data0_Msk (0xFFUL /*<< TPI_ITFTTD1_ATB_IF2_data0_Pos*/) /*!< TPI ITFTTD1: ATB Interface 2 data0 Mask */
/* TPI Integration Test ATB Control Register 0 Definitions */
#define TPI_ITATBCTR0_AFVALID2S_Pos 1U /*!< TPI ITATBCTR0: AFVALID2S Position */
#define TPI_ITATBCTR0_AFVALID2S_Msk (0x1UL << TPI_ITATBCTR0_AFVALID2S_Pos) /*!< TPI ITATBCTR0: AFVALID2SS Mask */
#define TPI_ITATBCTR0_AFVALID1S_Pos 1U /*!< TPI ITATBCTR0: AFVALID1S Position */
#define TPI_ITATBCTR0_AFVALID1S_Msk (0x1UL << TPI_ITATBCTR0_AFVALID1S_Pos) /*!< TPI ITATBCTR0: AFVALID1SS Mask */
#define TPI_ITATBCTR0_ATREADY2S_Pos 0U /*!< TPI ITATBCTR0: ATREADY2S Position */
#define TPI_ITATBCTR0_ATREADY2S_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY2S_Pos*/) /*!< TPI ITATBCTR0: ATREADY2S Mask */
#define TPI_ITATBCTR0_ATREADY1S_Pos 0U /*!< TPI ITATBCTR0: ATREADY1S Position */
#define TPI_ITATBCTR0_ATREADY1S_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY1S_Pos*/) /*!< TPI ITATBCTR0: ATREADY1S Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x3UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_FIFOSZ_Pos 6U /*!< TPI DEVID: FIFOSZ Position */
#define TPI_DEVID_FIFOSZ_Msk (0x7UL << TPI_DEVID_FIFOSZ_Pos) /*!< TPI DEVID: FIFOSZ Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x3FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) MPU Region Limit Address Register */
uint32_t RESERVED0[7U];
union {
__IOM uint32_t MAIR[2];
struct {
__IOM uint32_t MAIR0; /*!< Offset: 0x030 (R/W) MPU Memory Attribute Indirection Register 0 */
__IOM uint32_t MAIR1; /*!< Offset: 0x034 (R/W) MPU Memory Attribute Indirection Register 1 */
};
};
} MPU_Type;
#define MPU_TYPE_RALIASES 1U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_BASE_Pos 5U /*!< MPU RBAR: BASE Position */
#define MPU_RBAR_BASE_Msk (0x7FFFFFFUL << MPU_RBAR_BASE_Pos) /*!< MPU RBAR: BASE Mask */
#define MPU_RBAR_SH_Pos 3U /*!< MPU RBAR: SH Position */
#define MPU_RBAR_SH_Msk (0x3UL << MPU_RBAR_SH_Pos) /*!< MPU RBAR: SH Mask */
#define MPU_RBAR_AP_Pos 1U /*!< MPU RBAR: AP Position */
#define MPU_RBAR_AP_Msk (0x3UL << MPU_RBAR_AP_Pos) /*!< MPU RBAR: AP Mask */
#define MPU_RBAR_XN_Pos 0U /*!< MPU RBAR: XN Position */
#define MPU_RBAR_XN_Msk (01UL /*<< MPU_RBAR_XN_Pos*/) /*!< MPU RBAR: XN Mask */
/* MPU Region Limit Address Register Definitions */
#define MPU_RLAR_LIMIT_Pos 5U /*!< MPU RLAR: LIMIT Position */
#define MPU_RLAR_LIMIT_Msk (0x7FFFFFFUL << MPU_RLAR_LIMIT_Pos) /*!< MPU RLAR: LIMIT Mask */
#define MPU_RLAR_AttrIndx_Pos 1U /*!< MPU RLAR: AttrIndx Position */
#define MPU_RLAR_AttrIndx_Msk (0x7UL << MPU_RLAR_AttrIndx_Pos) /*!< MPU RLAR: AttrIndx Mask */
#define MPU_RLAR_EN_Pos 0U /*!< MPU RLAR: EN Position */
#define MPU_RLAR_EN_Msk (1UL /*<< MPU_RLAR_EN_Pos*/) /*!< MPU RLAR: EN Mask */
/* MPU Memory Attribute Indirection Register 0 Definitions */
#define MPU_MAIR0_Attr3_Pos 24U /*!< MPU MAIR0: Attr3 Position */
#define MPU_MAIR0_Attr3_Msk (0xFFUL << MPU_MAIR0_Attr3_Pos) /*!< MPU MAIR0: Attr3 Mask */
#define MPU_MAIR0_Attr2_Pos 16U /*!< MPU MAIR0: Attr2 Position */
#define MPU_MAIR0_Attr2_Msk (0xFFUL << MPU_MAIR0_Attr2_Pos) /*!< MPU MAIR0: Attr2 Mask */
#define MPU_MAIR0_Attr1_Pos 8U /*!< MPU MAIR0: Attr1 Position */
#define MPU_MAIR0_Attr1_Msk (0xFFUL << MPU_MAIR0_Attr1_Pos) /*!< MPU MAIR0: Attr1 Mask */
#define MPU_MAIR0_Attr0_Pos 0U /*!< MPU MAIR0: Attr0 Position */
#define MPU_MAIR0_Attr0_Msk (0xFFUL /*<< MPU_MAIR0_Attr0_Pos*/) /*!< MPU MAIR0: Attr0 Mask */
/* MPU Memory Attribute Indirection Register 1 Definitions */
#define MPU_MAIR1_Attr7_Pos 24U /*!< MPU MAIR1: Attr7 Position */
#define MPU_MAIR1_Attr7_Msk (0xFFUL << MPU_MAIR1_Attr7_Pos) /*!< MPU MAIR1: Attr7 Mask */
#define MPU_MAIR1_Attr6_Pos 16U /*!< MPU MAIR1: Attr6 Position */
#define MPU_MAIR1_Attr6_Msk (0xFFUL << MPU_MAIR1_Attr6_Pos) /*!< MPU MAIR1: Attr6 Mask */
#define MPU_MAIR1_Attr5_Pos 8U /*!< MPU MAIR1: Attr5 Position */
#define MPU_MAIR1_Attr5_Msk (0xFFUL << MPU_MAIR1_Attr5_Pos) /*!< MPU MAIR1: Attr5 Mask */
#define MPU_MAIR1_Attr4_Pos 0U /*!< MPU MAIR1: Attr4 Position */
#define MPU_MAIR1_Attr4_Msk (0xFFUL /*<< MPU_MAIR1_Attr4_Pos*/) /*!< MPU MAIR1: Attr4 Mask */
/*@} end of group CMSIS_MPU */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SAU Security Attribution Unit (SAU)
\brief Type definitions for the Security Attribution Unit (SAU)
@{
*/
/**
\brief Structure type to access the Security Attribution Unit (SAU).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SAU Control Register */
__IM uint32_t TYPE; /*!< Offset: 0x004 (R/ ) SAU Type Register */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) SAU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) SAU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) SAU Region Limit Address Register */
#endif
} SAU_Type;
/* SAU Control Register Definitions */
#define SAU_CTRL_ALLNS_Pos 1U /*!< SAU CTRL: ALLNS Position */
#define SAU_CTRL_ALLNS_Msk (1UL << SAU_CTRL_ALLNS_Pos) /*!< SAU CTRL: ALLNS Mask */
#define SAU_CTRL_ENABLE_Pos 0U /*!< SAU CTRL: ENABLE Position */
#define SAU_CTRL_ENABLE_Msk (1UL /*<< SAU_CTRL_ENABLE_Pos*/) /*!< SAU CTRL: ENABLE Mask */
/* SAU Type Register Definitions */
#define SAU_TYPE_SREGION_Pos 0U /*!< SAU TYPE: SREGION Position */
#define SAU_TYPE_SREGION_Msk (0xFFUL /*<< SAU_TYPE_SREGION_Pos*/) /*!< SAU TYPE: SREGION Mask */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
/* SAU Region Number Register Definitions */
#define SAU_RNR_REGION_Pos 0U /*!< SAU RNR: REGION Position */
#define SAU_RNR_REGION_Msk (0xFFUL /*<< SAU_RNR_REGION_Pos*/) /*!< SAU RNR: REGION Mask */
/* SAU Region Base Address Register Definitions */
#define SAU_RBAR_BADDR_Pos 5U /*!< SAU RBAR: BADDR Position */
#define SAU_RBAR_BADDR_Msk (0x7FFFFFFUL << SAU_RBAR_BADDR_Pos) /*!< SAU RBAR: BADDR Mask */
/* SAU Region Limit Address Register Definitions */
#define SAU_RLAR_LADDR_Pos 5U /*!< SAU RLAR: LADDR Position */
#define SAU_RLAR_LADDR_Msk (0x7FFFFFFUL << SAU_RLAR_LADDR_Pos) /*!< SAU RLAR: LADDR Mask */
#define SAU_RLAR_NSC_Pos 1U /*!< SAU RLAR: NSC Position */
#define SAU_RLAR_NSC_Msk (1UL << SAU_RLAR_NSC_Pos) /*!< SAU RLAR: NSC Mask */
#define SAU_RLAR_ENABLE_Pos 0U /*!< SAU RLAR: ENABLE Position */
#define SAU_RLAR_ENABLE_Msk (1UL /*<< SAU_RLAR_ENABLE_Pos*/) /*!< SAU RLAR: ENABLE Mask */
#endif /* defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U) */
/*@} end of group CMSIS_SAU */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
uint32_t RESERVED4[1U];
__IOM uint32_t DAUTHCTRL; /*!< Offset: 0x014 (R/W) Debug Authentication Control Register */
__IOM uint32_t DSCSR; /*!< Offset: 0x018 (R/W) Debug Security Control and Status Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESTART_ST_Pos 26U /*!< CoreDebug DHCSR: S_RESTART_ST Position */
#define CoreDebug_DHCSR_S_RESTART_ST_Msk (1UL << CoreDebug_DHCSR_S_RESTART_ST_Pos) /*!< CoreDebug DHCSR: S_RESTART_ST Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register */
#define CoreDebug_DEMCR_DWTENA_Pos 24U /*!< CoreDebug DEMCR: DWTENA Position */
#define CoreDebug_DEMCR_DWTENA_Msk (1UL << CoreDebug_DEMCR_DWTENA_Pos) /*!< CoreDebug DEMCR: DWTENA Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/* Debug Authentication Control Register Definitions */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos 3U /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Position */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Mask */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos 2U /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Msk (1UL << CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos) /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Mask */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Pos 1U /*!< CoreDebug DAUTHCTRL: INTSPIDEN Position */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPIDEN Mask */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Pos 0U /*!< CoreDebug DAUTHCTRL: SPIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Msk (1UL /*<< CoreDebug_DAUTHCTRL_SPIDENSEL_Pos*/) /*!< CoreDebug DAUTHCTRL: SPIDENSEL Mask */
/* Debug Security Control and Status Register Definitions */
#define CoreDebug_DSCSR_CDS_Pos 16U /*!< CoreDebug DSCSR: CDS Position */
#define CoreDebug_DSCSR_CDS_Msk (1UL << CoreDebug_DSCSR_CDS_Pos) /*!< CoreDebug DSCSR: CDS Mask */
#define CoreDebug_DSCSR_SBRSEL_Pos 1U /*!< CoreDebug DSCSR: SBRSEL Position */
#define CoreDebug_DSCSR_SBRSEL_Msk (1UL << CoreDebug_DSCSR_SBRSEL_Pos) /*!< CoreDebug DSCSR: SBRSEL Mask */
#define CoreDebug_DSCSR_SBRSELEN_Pos 0U /*!< CoreDebug DSCSR: SBRSELEN Position */
#define CoreDebug_DSCSR_SBRSELEN_Msk (1UL /*<< CoreDebug_DSCSR_SBRSELEN_Pos*/) /*!< CoreDebug DSCSR: SBRSELEN Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE ) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SAU_BASE (SCS_BASE + 0x0DD0UL) /*!< Security Attribution Unit */
#define SAU ((SAU_Type *) SAU_BASE ) /*!< Security Attribution Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SCS_BASE_NS (0xE002E000UL) /*!< System Control Space Base Address (non-secure address space) */
#define CoreDebug_BASE_NS (0xE002EDF0UL) /*!< Core Debug Base Address (non-secure address space) */
#define SysTick_BASE_NS (SCS_BASE_NS + 0x0010UL) /*!< SysTick Base Address (non-secure address space) */
#define NVIC_BASE_NS (SCS_BASE_NS + 0x0100UL) /*!< NVIC Base Address (non-secure address space) */
#define SCB_BASE_NS (SCS_BASE_NS + 0x0D00UL) /*!< System Control Block Base Address (non-secure address space) */
#define SCB_NS ((SCB_Type *) SCB_BASE_NS ) /*!< SCB configuration struct (non-secure address space) */
#define SysTick_NS ((SysTick_Type *) SysTick_BASE_NS ) /*!< SysTick configuration struct (non-secure address space) */
#define NVIC_NS ((NVIC_Type *) NVIC_BASE_NS ) /*!< NVIC configuration struct (non-secure address space) */
#define CoreDebug_NS ((CoreDebug_Type *) CoreDebug_BASE_NS) /*!< Core Debug configuration struct (non-secure address space) */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE_NS (SCS_BASE_NS + 0x0D90UL) /*!< Memory Protection Unit (non-secure address space) */
#define MPU_NS ((MPU_Type *) MPU_BASE_NS ) /*!< Memory Protection Unit (non-secure address space) */
#endif
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
/*#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping not available for Cortex-M23 */
/*#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping not available for Cortex-M23 */
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* Special LR values for Secure/Non-Secure call handling and exception handling */
/* Function Return Payload (from ARMv8-M Architecture Reference Manual) LR value on entry from Secure BLXNS */
#define FNC_RETURN (0xFEFFFFFFUL) /* bit [0] ignored when processing a branch */
/* The following EXC_RETURN mask values are used to evaluate the LR on exception entry */
#define EXC_RETURN_PREFIX (0xFF000000UL) /* bits [31:24] set to indicate an EXC_RETURN value */
#define EXC_RETURN_S (0x00000040UL) /* bit [6] stack used to push registers: 0=Non-secure 1=Secure */
#define EXC_RETURN_DCRS (0x00000020UL) /* bit [5] stacking rules for called registers: 0=skipped 1=saved */
#define EXC_RETURN_FTYPE (0x00000010UL) /* bit [4] allocate stack for floating-point context: 0=done 1=skipped */
#define EXC_RETURN_MODE (0x00000008UL) /* bit [3] processor mode for return: 0=Handler mode 1=Thread mode */
#define EXC_RETURN_SPSEL (0x00000004UL) /* bit [2] stack pointer used to restore context: 0=MSP 1=PSP */
#define EXC_RETURN_ES (0x00000001UL) /* bit [0] security state exception was taken to: 0=Non-secure 1=Secure */
/* Integrity Signature (from ARMv8-M Architecture Reference Manual) for exception context stacking */
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U) /* Value for processors with floating-point extension: */
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125AUL) /* bit [0] SFTC must match LR bit[4] EXC_RETURN_FTYPE */
#else
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125BUL) /* Value for processors without floating-point extension */
#endif
/* Interrupt Priorities are WORD accessible only under Armv6-M */
/* The following MACROS handle generation of the register offset and byte masks */
#define _BIT_SHIFT(IRQn) ( ((((uint32_t)(int32_t)(IRQn)) ) & 0x03UL) * 8UL)
#define _SHP_IDX(IRQn) ( (((((uint32_t)(int32_t)(IRQn)) & 0x0FUL)-8UL) >> 2UL) )
#define _IP_IDX(IRQn) ( (((uint32_t)(int32_t)(IRQn)) >> 2UL) )
#define __NVIC_SetPriorityGrouping(X) (void)(X)
#define __NVIC_GetPriorityGrouping() (0U)
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Get Interrupt Target State
\details Reads the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
\return 1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_GetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Target State
\details Sets the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_SetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] |= ((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Clear Interrupt Target State
\details Clears the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_ClearTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] &= ~((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IPR[_IP_IDX(IRQn)] = ((uint32_t)(NVIC->IPR[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB->SHPR[_SHP_IDX(IRQn)] = ((uint32_t)(SCB->SHPR[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IPR[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB->SHPR[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
If VTOR is not present address 0 must be mapped to SRAM.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
uint32_t *vectors = (uint32_t *)SCB->VTOR;
#else
uint32_t *vectors = (uint32_t *)0x0U;
#endif
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
__DSB();
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
uint32_t *vectors = (uint32_t *)SCB->VTOR;
#else
uint32_t *vectors = (uint32_t *)0x0U;
#endif
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = ((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
SCB_AIRCR_SYSRESETREQ_Msk);
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable Interrupt (non-secure)
\details Enables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_EnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Interrupt Enable status (non-secure)
\details Returns a device specific interrupt enable status from the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetEnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt (non-secure)
\details Disables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_DisableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Pending Interrupt (non-secure)
\details Reads the NVIC pending register in the non-secure NVIC when in secure state and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt (non-secure)
\details Sets the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_SetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt (non-secure)
\details Clears the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_ClearPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt (non-secure)
\details Reads the active register in non-secure NVIC when in secure state and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetActive_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority (non-secure)
\details Sets the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every non-secure processor exception.
*/
__STATIC_INLINE void TZ_NVIC_SetPriority_NS(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->IPR[_IP_IDX(IRQn)] = ((uint32_t)(NVIC_NS->IPR[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB_NS->SHPR[_SHP_IDX(IRQn)] = ((uint32_t)(SCB_NS->SHPR[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority (non-secure)
\details Reads the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority. Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriority_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IPR[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB_NS->SHPR[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
#endif /* defined (__ARM_FEATURE_CMSE) &&(__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv8.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ########################## SAU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SAUFunctions SAU Functions
\brief Functions that configure the SAU.
@{
*/
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable SAU
\details Enables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Enable(void)
{
SAU->CTRL |= (SAU_CTRL_ENABLE_Msk);
}
/**
\brief Disable SAU
\details Disables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Disable(void)
{
SAU->CTRL &= ~(SAU_CTRL_ENABLE_Msk);
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_SAUFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief System Tick Configuration (non-secure)
\details Initializes the non-secure System Timer and its interrupt when in secure state, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>TZ_SysTick_Config_NS</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t TZ_SysTick_Config_NS(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick_NS->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
TZ_NVIC_SetPriority_NS (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick_NS->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick_NS->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM23_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 102,697 | C | 50.426139 | 178 | 0.551087 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/cmsis_armcc.h | /**************************************************************************//**
* @file cmsis_armcc.h
* @brief CMSIS compiler ARMCC (Arm Compiler 5) header file
* @version V5.1.0
* @date 08. May 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef __CMSIS_ARMCC_H
#define __CMSIS_ARMCC_H
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION < 400677)
#error "Please use Arm Compiler Toolchain V4.0.677 or later!"
#endif
/* CMSIS compiler control architecture macros */
#if ((defined (__TARGET_ARCH_6_M ) && (__TARGET_ARCH_6_M == 1)) || \
(defined (__TARGET_ARCH_6S_M ) && (__TARGET_ARCH_6S_M == 1)) )
#define __ARM_ARCH_6M__ 1
#endif
#if (defined (__TARGET_ARCH_7_M ) && (__TARGET_ARCH_7_M == 1))
#define __ARM_ARCH_7M__ 1
#endif
#if (defined (__TARGET_ARCH_7E_M) && (__TARGET_ARCH_7E_M == 1))
#define __ARM_ARCH_7EM__ 1
#endif
/* __ARM_ARCH_8M_BASE__ not applicable */
/* __ARM_ARCH_8M_MAIN__ not applicable */
/* CMSIS compiler control DSP macros */
#if ((defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) )
#define __ARM_FEATURE_DSP 1
#endif
/* CMSIS compiler specific defines */
#ifndef __ASM
#define __ASM __asm
#endif
#ifndef __INLINE
#define __INLINE __inline
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static __inline
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE static __forceinline
#endif
#ifndef __NO_RETURN
#define __NO_RETURN __declspec(noreturn)
#endif
#ifndef __USED
#define __USED __attribute__((used))
#endif
#ifndef __WEAK
#define __WEAK __attribute__((weak))
#endif
#ifndef __PACKED
#define __PACKED __attribute__((packed))
#endif
#ifndef __PACKED_STRUCT
#define __PACKED_STRUCT __packed struct
#endif
#ifndef __PACKED_UNION
#define __PACKED_UNION __packed union
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
#define __UNALIGNED_UINT32(x) (*((__packed uint32_t *)(x)))
#endif
#ifndef __UNALIGNED_UINT16_WRITE
#define __UNALIGNED_UINT16_WRITE(addr, val) ((*((__packed uint16_t *)(addr))) = (val))
#endif
#ifndef __UNALIGNED_UINT16_READ
#define __UNALIGNED_UINT16_READ(addr) (*((const __packed uint16_t *)(addr)))
#endif
#ifndef __UNALIGNED_UINT32_WRITE
#define __UNALIGNED_UINT32_WRITE(addr, val) ((*((__packed uint32_t *)(addr))) = (val))
#endif
#ifndef __UNALIGNED_UINT32_READ
#define __UNALIGNED_UINT32_READ(addr) (*((const __packed uint32_t *)(addr)))
#endif
#ifndef __ALIGNED
#define __ALIGNED(x) __attribute__((aligned(x)))
#endif
#ifndef __RESTRICT
#define __RESTRICT __restrict
#endif
#ifndef __COMPILER_BARRIER
#define __COMPILER_BARRIER() __memory_changed()
#endif
/* ######################### Startup and Lowlevel Init ######################## */
#ifndef __PROGRAM_START
#define __PROGRAM_START __main
#endif
#ifndef __INITIAL_SP
#define __INITIAL_SP Image$$ARM_LIB_STACK$$ZI$$Limit
#endif
#ifndef __STACK_LIMIT
#define __STACK_LIMIT Image$$ARM_LIB_STACK$$ZI$$Base
#endif
#ifndef __VECTOR_TABLE
#define __VECTOR_TABLE __Vectors
#endif
#ifndef __VECTOR_TABLE_ATTRIBUTE
#define __VECTOR_TABLE_ATTRIBUTE __attribute((used, section("RESET")))
#endif
/* ########################### Core Function Access ########################### */
/** \ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_RegAccFunctions CMSIS Core Register Access Functions
@{
*/
/**
\brief Enable IRQ Interrupts
\details Enables IRQ interrupts by clearing the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
/* intrinsic void __enable_irq(); */
/**
\brief Disable IRQ Interrupts
\details Disables IRQ interrupts by setting the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
/* intrinsic void __disable_irq(); */
/**
\brief Get Control Register
\details Returns the content of the Control Register.
\return Control Register value
*/
__STATIC_INLINE uint32_t __get_CONTROL(void)
{
register uint32_t __regControl __ASM("control");
return(__regControl);
}
/**
\brief Set Control Register
\details Writes the given value to the Control Register.
\param [in] control Control Register value to set
*/
__STATIC_INLINE void __set_CONTROL(uint32_t control)
{
register uint32_t __regControl __ASM("control");
__regControl = control;
}
/**
\brief Get IPSR Register
\details Returns the content of the IPSR Register.
\return IPSR Register value
*/
__STATIC_INLINE uint32_t __get_IPSR(void)
{
register uint32_t __regIPSR __ASM("ipsr");
return(__regIPSR);
}
/**
\brief Get APSR Register
\details Returns the content of the APSR Register.
\return APSR Register value
*/
__STATIC_INLINE uint32_t __get_APSR(void)
{
register uint32_t __regAPSR __ASM("apsr");
return(__regAPSR);
}
/**
\brief Get xPSR Register
\details Returns the content of the xPSR Register.
\return xPSR Register value
*/
__STATIC_INLINE uint32_t __get_xPSR(void)
{
register uint32_t __regXPSR __ASM("xpsr");
return(__regXPSR);
}
/**
\brief Get Process Stack Pointer
\details Returns the current value of the Process Stack Pointer (PSP).
\return PSP Register value
*/
__STATIC_INLINE uint32_t __get_PSP(void)
{
register uint32_t __regProcessStackPointer __ASM("psp");
return(__regProcessStackPointer);
}
/**
\brief Set Process Stack Pointer
\details Assigns the given value to the Process Stack Pointer (PSP).
\param [in] topOfProcStack Process Stack Pointer value to set
*/
__STATIC_INLINE void __set_PSP(uint32_t topOfProcStack)
{
register uint32_t __regProcessStackPointer __ASM("psp");
__regProcessStackPointer = topOfProcStack;
}
/**
\brief Get Main Stack Pointer
\details Returns the current value of the Main Stack Pointer (MSP).
\return MSP Register value
*/
__STATIC_INLINE uint32_t __get_MSP(void)
{
register uint32_t __regMainStackPointer __ASM("msp");
return(__regMainStackPointer);
}
/**
\brief Set Main Stack Pointer
\details Assigns the given value to the Main Stack Pointer (MSP).
\param [in] topOfMainStack Main Stack Pointer value to set
*/
__STATIC_INLINE void __set_MSP(uint32_t topOfMainStack)
{
register uint32_t __regMainStackPointer __ASM("msp");
__regMainStackPointer = topOfMainStack;
}
/**
\brief Get Priority Mask
\details Returns the current state of the priority mask bit from the Priority Mask Register.
\return Priority Mask value
*/
__STATIC_INLINE uint32_t __get_PRIMASK(void)
{
register uint32_t __regPriMask __ASM("primask");
return(__regPriMask);
}
/**
\brief Set Priority Mask
\details Assigns the given value to the Priority Mask Register.
\param [in] priMask Priority Mask
*/
__STATIC_INLINE void __set_PRIMASK(uint32_t priMask)
{
register uint32_t __regPriMask __ASM("primask");
__regPriMask = (priMask);
}
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) )
/**
\brief Enable FIQ
\details Enables FIQ interrupts by clearing the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
#define __enable_fault_irq __enable_fiq
/**
\brief Disable FIQ
\details Disables FIQ interrupts by setting the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
#define __disable_fault_irq __disable_fiq
/**
\brief Get Base Priority
\details Returns the current value of the Base Priority register.
\return Base Priority register value
*/
__STATIC_INLINE uint32_t __get_BASEPRI(void)
{
register uint32_t __regBasePri __ASM("basepri");
return(__regBasePri);
}
/**
\brief Set Base Priority
\details Assigns the given value to the Base Priority register.
\param [in] basePri Base Priority value to set
*/
__STATIC_INLINE void __set_BASEPRI(uint32_t basePri)
{
register uint32_t __regBasePri __ASM("basepri");
__regBasePri = (basePri & 0xFFU);
}
/**
\brief Set Base Priority with condition
\details Assigns the given value to the Base Priority register only if BASEPRI masking is disabled,
or the new value increases the BASEPRI priority level.
\param [in] basePri Base Priority value to set
*/
__STATIC_INLINE void __set_BASEPRI_MAX(uint32_t basePri)
{
register uint32_t __regBasePriMax __ASM("basepri_max");
__regBasePriMax = (basePri & 0xFFU);
}
/**
\brief Get Fault Mask
\details Returns the current value of the Fault Mask register.
\return Fault Mask register value
*/
__STATIC_INLINE uint32_t __get_FAULTMASK(void)
{
register uint32_t __regFaultMask __ASM("faultmask");
return(__regFaultMask);
}
/**
\brief Set Fault Mask
\details Assigns the given value to the Fault Mask register.
\param [in] faultMask Fault Mask value to set
*/
__STATIC_INLINE void __set_FAULTMASK(uint32_t faultMask)
{
register uint32_t __regFaultMask __ASM("faultmask");
__regFaultMask = (faultMask & (uint32_t)1U);
}
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) ) */
/**
\brief Get FPSCR
\details Returns the current value of the Floating Point Status/Control register.
\return Floating Point Status/Control register value
*/
__STATIC_INLINE uint32_t __get_FPSCR(void)
{
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
register uint32_t __regfpscr __ASM("fpscr");
return(__regfpscr);
#else
return(0U);
#endif
}
/**
\brief Set FPSCR
\details Assigns the given value to the Floating Point Status/Control register.
\param [in] fpscr Floating Point Status/Control value to set
*/
__STATIC_INLINE void __set_FPSCR(uint32_t fpscr)
{
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
register uint32_t __regfpscr __ASM("fpscr");
__regfpscr = (fpscr);
#else
(void)fpscr;
#endif
}
/*@} end of CMSIS_Core_RegAccFunctions */
/* ########################## Core Instruction Access ######################### */
/** \defgroup CMSIS_Core_InstructionInterface CMSIS Core Instruction Interface
Access to dedicated instructions
@{
*/
/**
\brief No Operation
\details No Operation does nothing. This instruction can be used for code alignment purposes.
*/
#define __NOP __nop
/**
\brief Wait For Interrupt
\details Wait For Interrupt is a hint instruction that suspends execution until one of a number of events occurs.
*/
#define __WFI __wfi
/**
\brief Wait For Event
\details Wait For Event is a hint instruction that permits the processor to enter
a low-power state until one of a number of events occurs.
*/
#define __WFE __wfe
/**
\brief Send Event
\details Send Event is a hint instruction. It causes an event to be signaled to the CPU.
*/
#define __SEV __sev
/**
\brief Instruction Synchronization Barrier
\details Instruction Synchronization Barrier flushes the pipeline in the processor,
so that all instructions following the ISB are fetched from cache or memory,
after the instruction has been completed.
*/
#define __ISB() do {\
__schedule_barrier();\
__isb(0xF);\
__schedule_barrier();\
} while (0U)
/**
\brief Data Synchronization Barrier
\details Acts as a special kind of Data Memory Barrier.
It completes when all explicit memory accesses before this instruction complete.
*/
#define __DSB() do {\
__schedule_barrier();\
__dsb(0xF);\
__schedule_barrier();\
} while (0U)
/**
\brief Data Memory Barrier
\details Ensures the apparent order of the explicit memory operations before
and after the instruction, without ensuring their completion.
*/
#define __DMB() do {\
__schedule_barrier();\
__dmb(0xF);\
__schedule_barrier();\
} while (0U)
/**
\brief Reverse byte order (32 bit)
\details Reverses the byte order in unsigned integer value. For example, 0x12345678 becomes 0x78563412.
\param [in] value Value to reverse
\return Reversed value
*/
#define __REV __rev
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order within each halfword of a word. For example, 0x12345678 becomes 0x34127856.
\param [in] value Value to reverse
\return Reversed value
*/
#ifndef __NO_EMBEDDED_ASM
__attribute__((section(".rev16_text"))) __STATIC_INLINE __ASM uint32_t __REV16(uint32_t value)
{
rev16 r0, r0
bx lr
}
#endif
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order in a 16-bit value and returns the signed 16-bit result. For example, 0x0080 becomes 0x8000.
\param [in] value Value to reverse
\return Reversed value
*/
#ifndef __NO_EMBEDDED_ASM
__attribute__((section(".revsh_text"))) __STATIC_INLINE __ASM int16_t __REVSH(int16_t value)
{
revsh r0, r0
bx lr
}
#endif
/**
\brief Rotate Right in unsigned value (32 bit)
\details Rotate Right (immediate) provides the value of the contents of a register rotated by a variable number of bits.
\param [in] op1 Value to rotate
\param [in] op2 Number of Bits to rotate
\return Rotated value
*/
#define __ROR __ror
/**
\brief Breakpoint
\details Causes the processor to enter Debug state.
Debug tools can use this to investigate system state when the instruction at a particular address is reached.
\param [in] value is ignored by the processor.
If required, a debugger can use it to store additional information about the breakpoint.
*/
#define __BKPT(value) __breakpoint(value)
/**
\brief Reverse bit order of value
\details Reverses the bit order of the given value.
\param [in] value Value to reverse
\return Reversed value
*/
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) )
#define __RBIT __rbit
#else
__attribute__((always_inline)) __STATIC_INLINE uint32_t __RBIT(uint32_t value)
{
uint32_t result;
uint32_t s = (4U /*sizeof(v)*/ * 8U) - 1U; /* extra shift needed at end */
result = value; /* r will be reversed bits of v; first get LSB of v */
for (value >>= 1U; value != 0U; value >>= 1U)
{
result <<= 1U;
result |= value & 1U;
s--;
}
result <<= s; /* shift when v's highest bits are zero */
return result;
}
#endif
/**
\brief Count leading zeros
\details Counts the number of leading zeros of a data value.
\param [in] value Value to count the leading zeros
\return number of leading zeros in value
*/
#define __CLZ __clz
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) )
/**
\brief LDR Exclusive (8 bit)
\details Executes a exclusive LDR instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION < 5060020)
#define __LDREXB(ptr) ((uint8_t ) __ldrex(ptr))
#else
#define __LDREXB(ptr) _Pragma("push") _Pragma("diag_suppress 3731") ((uint8_t ) __ldrex(ptr)) _Pragma("pop")
#endif
/**
\brief LDR Exclusive (16 bit)
\details Executes a exclusive LDR instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION < 5060020)
#define __LDREXH(ptr) ((uint16_t) __ldrex(ptr))
#else
#define __LDREXH(ptr) _Pragma("push") _Pragma("diag_suppress 3731") ((uint16_t) __ldrex(ptr)) _Pragma("pop")
#endif
/**
\brief LDR Exclusive (32 bit)
\details Executes a exclusive LDR instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION < 5060020)
#define __LDREXW(ptr) ((uint32_t ) __ldrex(ptr))
#else
#define __LDREXW(ptr) _Pragma("push") _Pragma("diag_suppress 3731") ((uint32_t ) __ldrex(ptr)) _Pragma("pop")
#endif
/**
\brief STR Exclusive (8 bit)
\details Executes a exclusive STR instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION < 5060020)
#define __STREXB(value, ptr) __strex(value, ptr)
#else
#define __STREXB(value, ptr) _Pragma("push") _Pragma("diag_suppress 3731") __strex(value, ptr) _Pragma("pop")
#endif
/**
\brief STR Exclusive (16 bit)
\details Executes a exclusive STR instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION < 5060020)
#define __STREXH(value, ptr) __strex(value, ptr)
#else
#define __STREXH(value, ptr) _Pragma("push") _Pragma("diag_suppress 3731") __strex(value, ptr) _Pragma("pop")
#endif
/**
\brief STR Exclusive (32 bit)
\details Executes a exclusive STR instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION < 5060020)
#define __STREXW(value, ptr) __strex(value, ptr)
#else
#define __STREXW(value, ptr) _Pragma("push") _Pragma("diag_suppress 3731") __strex(value, ptr) _Pragma("pop")
#endif
/**
\brief Remove the exclusive lock
\details Removes the exclusive lock which is created by LDREX.
*/
#define __CLREX __clrex
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (1..32)
\return Saturated value
*/
#define __SSAT __ssat
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (0..31)
\return Saturated value
*/
#define __USAT __usat
/**
\brief Rotate Right with Extend (32 bit)
\details Moves each bit of a bitstring right by one bit.
The carry input is shifted in at the left end of the bitstring.
\param [in] value Value to rotate
\return Rotated value
*/
#ifndef __NO_EMBEDDED_ASM
__attribute__((section(".rrx_text"))) __STATIC_INLINE __ASM uint32_t __RRX(uint32_t value)
{
rrx r0, r0
bx lr
}
#endif
/**
\brief LDRT Unprivileged (8 bit)
\details Executes a Unprivileged LDRT instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
#define __LDRBT(ptr) ((uint8_t ) __ldrt(ptr))
/**
\brief LDRT Unprivileged (16 bit)
\details Executes a Unprivileged LDRT instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
#define __LDRHT(ptr) ((uint16_t) __ldrt(ptr))
/**
\brief LDRT Unprivileged (32 bit)
\details Executes a Unprivileged LDRT instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
#define __LDRT(ptr) ((uint32_t ) __ldrt(ptr))
/**
\brief STRT Unprivileged (8 bit)
\details Executes a Unprivileged STRT instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
#define __STRBT(value, ptr) __strt(value, ptr)
/**
\brief STRT Unprivileged (16 bit)
\details Executes a Unprivileged STRT instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
#define __STRHT(value, ptr) __strt(value, ptr)
/**
\brief STRT Unprivileged (32 bit)
\details Executes a Unprivileged STRT instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
#define __STRT(value, ptr) __strt(value, ptr)
#else /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) ) */
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (1..32)
\return Saturated value
*/
__attribute__((always_inline)) __STATIC_INLINE int32_t __SSAT(int32_t val, uint32_t sat)
{
if ((sat >= 1U) && (sat <= 32U))
{
const int32_t max = (int32_t)((1U << (sat - 1U)) - 1U);
const int32_t min = -1 - max ;
if (val > max)
{
return max;
}
else if (val < min)
{
return min;
}
}
return val;
}
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (0..31)
\return Saturated value
*/
__attribute__((always_inline)) __STATIC_INLINE uint32_t __USAT(int32_t val, uint32_t sat)
{
if (sat <= 31U)
{
const uint32_t max = ((1U << sat) - 1U);
if (val > (int32_t)max)
{
return max;
}
else if (val < 0)
{
return 0U;
}
}
return (uint32_t)val;
}
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) ) */
/*@}*/ /* end of group CMSIS_Core_InstructionInterface */
/* ################### Compiler specific Intrinsics ########################### */
/** \defgroup CMSIS_SIMD_intrinsics CMSIS SIMD Intrinsics
Access to dedicated SIMD instructions
@{
*/
#if ((defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) )
#define __SADD8 __sadd8
#define __QADD8 __qadd8
#define __SHADD8 __shadd8
#define __UADD8 __uadd8
#define __UQADD8 __uqadd8
#define __UHADD8 __uhadd8
#define __SSUB8 __ssub8
#define __QSUB8 __qsub8
#define __SHSUB8 __shsub8
#define __USUB8 __usub8
#define __UQSUB8 __uqsub8
#define __UHSUB8 __uhsub8
#define __SADD16 __sadd16
#define __QADD16 __qadd16
#define __SHADD16 __shadd16
#define __UADD16 __uadd16
#define __UQADD16 __uqadd16
#define __UHADD16 __uhadd16
#define __SSUB16 __ssub16
#define __QSUB16 __qsub16
#define __SHSUB16 __shsub16
#define __USUB16 __usub16
#define __UQSUB16 __uqsub16
#define __UHSUB16 __uhsub16
#define __SASX __sasx
#define __QASX __qasx
#define __SHASX __shasx
#define __UASX __uasx
#define __UQASX __uqasx
#define __UHASX __uhasx
#define __SSAX __ssax
#define __QSAX __qsax
#define __SHSAX __shsax
#define __USAX __usax
#define __UQSAX __uqsax
#define __UHSAX __uhsax
#define __USAD8 __usad8
#define __USADA8 __usada8
#define __SSAT16 __ssat16
#define __USAT16 __usat16
#define __UXTB16 __uxtb16
#define __UXTAB16 __uxtab16
#define __SXTB16 __sxtb16
#define __SXTAB16 __sxtab16
#define __SMUAD __smuad
#define __SMUADX __smuadx
#define __SMLAD __smlad
#define __SMLADX __smladx
#define __SMLALD __smlald
#define __SMLALDX __smlaldx
#define __SMUSD __smusd
#define __SMUSDX __smusdx
#define __SMLSD __smlsd
#define __SMLSDX __smlsdx
#define __SMLSLD __smlsld
#define __SMLSLDX __smlsldx
#define __SEL __sel
#define __QADD __qadd
#define __QSUB __qsub
#define __PKHBT(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0x0000FFFFUL) | \
((((uint32_t)(ARG2)) << (ARG3)) & 0xFFFF0000UL) )
#define __PKHTB(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0xFFFF0000UL) | \
((((uint32_t)(ARG2)) >> (ARG3)) & 0x0000FFFFUL) )
#define __SMMLA(ARG1,ARG2,ARG3) ( (int32_t)((((int64_t)(ARG1) * (ARG2)) + \
((int64_t)(ARG3) << 32U) ) >> 32U))
#endif /* ((defined (__ARM_ARCH_7EM__) && (__ARM_ARCH_7EM__ == 1)) ) */
/*@} end of group CMSIS_SIMD_intrinsics */
#endif /* __CMSIS_ARMCC_H */
| 28,132 | C | 30.43352 | 126 | 0.557621 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/tz_context.h | /******************************************************************************
* @file tz_context.h
* @brief Context Management for Armv8-M TrustZone
* @version V1.0.1
* @date 10. January 2018
******************************************************************************/
/*
* Copyright (c) 2017-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef TZ_CONTEXT_H
#define TZ_CONTEXT_H
#include <stdint.h>
#ifndef TZ_MODULEID_T
#define TZ_MODULEID_T
/// \details Data type that identifies secure software modules called by a process.
typedef uint32_t TZ_ModuleId_t;
#endif
/// \details TZ Memory ID identifies an allocated memory slot.
typedef uint32_t TZ_MemoryId_t;
/// Initialize secure context memory system
/// \return execution status (1: success, 0: error)
uint32_t TZ_InitContextSystem_S (void);
/// Allocate context memory for calling secure software modules in TrustZone
/// \param[in] module identifies software modules called from non-secure mode
/// \return value != 0 id TrustZone memory slot identifier
/// \return value 0 no memory available or internal error
TZ_MemoryId_t TZ_AllocModuleContext_S (TZ_ModuleId_t module);
/// Free context memory that was previously allocated with \ref TZ_AllocModuleContext_S
/// \param[in] id TrustZone memory slot identifier
/// \return execution status (1: success, 0: error)
uint32_t TZ_FreeModuleContext_S (TZ_MemoryId_t id);
/// Load secure context (called on RTOS thread context switch)
/// \param[in] id TrustZone memory slot identifier
/// \return execution status (1: success, 0: error)
uint32_t TZ_LoadContext_S (TZ_MemoryId_t id);
/// Store secure context (called on RTOS thread context switch)
/// \param[in] id TrustZone memory slot identifier
/// \return execution status (1: success, 0: error)
uint32_t TZ_StoreContext_S (TZ_MemoryId_t id);
#endif // TZ_CONTEXT_H
| 2,687 | C | 36.859154 | 88 | 0.68329 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/cmsis_iccarm.h | /**************************************************************************//**
* @file cmsis_iccarm.h
* @brief CMSIS compiler ICCARM (IAR Compiler for Arm) header file
* @version V5.1.0
* @date 08. May 2019
******************************************************************************/
//------------------------------------------------------------------------------
//
// Copyright (c) 2017-2019 IAR Systems
// Copyright (c) 2017-2019 Arm Limited. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License")
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//
//------------------------------------------------------------------------------
#ifndef __CMSIS_ICCARM_H__
#define __CMSIS_ICCARM_H__
#ifndef __ICCARM__
#error This file should only be compiled by ICCARM
#endif
#pragma system_include
#define __IAR_FT _Pragma("inline=forced") __intrinsic
#if (__VER__ >= 8000000)
#define __ICCARM_V8 1
#else
#define __ICCARM_V8 0
#endif
#ifndef __ALIGNED
#if __ICCARM_V8
#define __ALIGNED(x) __attribute__((aligned(x)))
#elif (__VER__ >= 7080000)
/* Needs IAR language extensions */
#define __ALIGNED(x) __attribute__((aligned(x)))
#else
#warning No compiler specific solution for __ALIGNED.__ALIGNED is ignored.
#define __ALIGNED(x)
#endif
#endif
/* Define compiler macros for CPU architecture, used in CMSIS 5.
*/
#if __ARM_ARCH_6M__ || __ARM_ARCH_7M__ || __ARM_ARCH_7EM__ || __ARM_ARCH_8M_BASE__ || __ARM_ARCH_8M_MAIN__
/* Macros already defined */
#else
#if defined(__ARM8M_MAINLINE__) || defined(__ARM8EM_MAINLINE__)
#define __ARM_ARCH_8M_MAIN__ 1
#elif defined(__ARM8M_BASELINE__)
#define __ARM_ARCH_8M_BASE__ 1
#elif defined(__ARM_ARCH_PROFILE) && __ARM_ARCH_PROFILE == 'M'
#if __ARM_ARCH == 6
#define __ARM_ARCH_6M__ 1
#elif __ARM_ARCH == 7
#if __ARM_FEATURE_DSP
#define __ARM_ARCH_7EM__ 1
#else
#define __ARM_ARCH_7M__ 1
#endif
#endif /* __ARM_ARCH */
#endif /* __ARM_ARCH_PROFILE == 'M' */
#endif
/* Alternativ core deduction for older ICCARM's */
#if !defined(__ARM_ARCH_6M__) && !defined(__ARM_ARCH_7M__) && !defined(__ARM_ARCH_7EM__) && \
!defined(__ARM_ARCH_8M_BASE__) && !defined(__ARM_ARCH_8M_MAIN__)
#if defined(__ARM6M__) && (__CORE__ == __ARM6M__)
#define __ARM_ARCH_6M__ 1
#elif defined(__ARM7M__) && (__CORE__ == __ARM7M__)
#define __ARM_ARCH_7M__ 1
#elif defined(__ARM7EM__) && (__CORE__ == __ARM7EM__)
#define __ARM_ARCH_7EM__ 1
#elif defined(__ARM8M_BASELINE__) && (__CORE == __ARM8M_BASELINE__)
#define __ARM_ARCH_8M_BASE__ 1
#elif defined(__ARM8M_MAINLINE__) && (__CORE == __ARM8M_MAINLINE__)
#define __ARM_ARCH_8M_MAIN__ 1
#elif defined(__ARM8EM_MAINLINE__) && (__CORE == __ARM8EM_MAINLINE__)
#define __ARM_ARCH_8M_MAIN__ 1
#else
#error "Unknown target."
#endif
#endif
#if defined(__ARM_ARCH_6M__) && __ARM_ARCH_6M__==1
#define __IAR_M0_FAMILY 1
#elif defined(__ARM_ARCH_8M_BASE__) && __ARM_ARCH_8M_BASE__==1
#define __IAR_M0_FAMILY 1
#else
#define __IAR_M0_FAMILY 0
#endif
#ifndef __ASM
#define __ASM __asm
#endif
#ifndef __COMPILER_BARRIER
#define __COMPILER_BARRIER() __ASM volatile("":::"memory")
#endif
#ifndef __INLINE
#define __INLINE inline
#endif
#ifndef __NO_RETURN
#if __ICCARM_V8
#define __NO_RETURN __attribute__((__noreturn__))
#else
#define __NO_RETURN _Pragma("object_attribute=__noreturn")
#endif
#endif
#ifndef __PACKED
#if __ICCARM_V8
#define __PACKED __attribute__((packed, aligned(1)))
#else
/* Needs IAR language extensions */
#define __PACKED __packed
#endif
#endif
#ifndef __PACKED_STRUCT
#if __ICCARM_V8
#define __PACKED_STRUCT struct __attribute__((packed, aligned(1)))
#else
/* Needs IAR language extensions */
#define __PACKED_STRUCT __packed struct
#endif
#endif
#ifndef __PACKED_UNION
#if __ICCARM_V8
#define __PACKED_UNION union __attribute__((packed, aligned(1)))
#else
/* Needs IAR language extensions */
#define __PACKED_UNION __packed union
#endif
#endif
#ifndef __RESTRICT
#if __ICCARM_V8
#define __RESTRICT __restrict
#else
/* Needs IAR language extensions */
#define __RESTRICT restrict
#endif
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static inline
#endif
#ifndef __FORCEINLINE
#define __FORCEINLINE _Pragma("inline=forced")
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE __FORCEINLINE __STATIC_INLINE
#endif
#ifndef __UNALIGNED_UINT16_READ
#pragma language=save
#pragma language=extended
__IAR_FT uint16_t __iar_uint16_read(void const *ptr)
{
return *(__packed uint16_t*)(ptr);
}
#pragma language=restore
#define __UNALIGNED_UINT16_READ(PTR) __iar_uint16_read(PTR)
#endif
#ifndef __UNALIGNED_UINT16_WRITE
#pragma language=save
#pragma language=extended
__IAR_FT void __iar_uint16_write(void const *ptr, uint16_t val)
{
*(__packed uint16_t*)(ptr) = val;;
}
#pragma language=restore
#define __UNALIGNED_UINT16_WRITE(PTR,VAL) __iar_uint16_write(PTR,VAL)
#endif
#ifndef __UNALIGNED_UINT32_READ
#pragma language=save
#pragma language=extended
__IAR_FT uint32_t __iar_uint32_read(void const *ptr)
{
return *(__packed uint32_t*)(ptr);
}
#pragma language=restore
#define __UNALIGNED_UINT32_READ(PTR) __iar_uint32_read(PTR)
#endif
#ifndef __UNALIGNED_UINT32_WRITE
#pragma language=save
#pragma language=extended
__IAR_FT void __iar_uint32_write(void const *ptr, uint32_t val)
{
*(__packed uint32_t*)(ptr) = val;;
}
#pragma language=restore
#define __UNALIGNED_UINT32_WRITE(PTR,VAL) __iar_uint32_write(PTR,VAL)
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
#pragma language=save
#pragma language=extended
__packed struct __iar_u32 { uint32_t v; };
#pragma language=restore
#define __UNALIGNED_UINT32(PTR) (((struct __iar_u32 *)(PTR))->v)
#endif
#ifndef __USED
#if __ICCARM_V8
#define __USED __attribute__((used))
#else
#define __USED _Pragma("__root")
#endif
#endif
#ifndef __WEAK
#if __ICCARM_V8
#define __WEAK __attribute__((weak))
#else
#define __WEAK _Pragma("__weak")
#endif
#endif
#ifndef __PROGRAM_START
#define __PROGRAM_START __iar_program_start
#endif
#ifndef __INITIAL_SP
#define __INITIAL_SP CSTACK$$Limit
#endif
#ifndef __STACK_LIMIT
#define __STACK_LIMIT CSTACK$$Base
#endif
#ifndef __VECTOR_TABLE
#define __VECTOR_TABLE __vector_table
#endif
#ifndef __VECTOR_TABLE_ATTRIBUTE
#define __VECTOR_TABLE_ATTRIBUTE @".intvec"
#endif
#ifndef __ICCARM_INTRINSICS_VERSION__
#define __ICCARM_INTRINSICS_VERSION__ 0
#endif
#if __ICCARM_INTRINSICS_VERSION__ == 2
#if defined(__CLZ)
#undef __CLZ
#endif
#if defined(__REVSH)
#undef __REVSH
#endif
#if defined(__RBIT)
#undef __RBIT
#endif
#if defined(__SSAT)
#undef __SSAT
#endif
#if defined(__USAT)
#undef __USAT
#endif
#include "iccarm_builtin.h"
#define __disable_fault_irq __iar_builtin_disable_fiq
#define __disable_irq __iar_builtin_disable_interrupt
#define __enable_fault_irq __iar_builtin_enable_fiq
#define __enable_irq __iar_builtin_enable_interrupt
#define __arm_rsr __iar_builtin_rsr
#define __arm_wsr __iar_builtin_wsr
#define __get_APSR() (__arm_rsr("APSR"))
#define __get_BASEPRI() (__arm_rsr("BASEPRI"))
#define __get_CONTROL() (__arm_rsr("CONTROL"))
#define __get_FAULTMASK() (__arm_rsr("FAULTMASK"))
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
#define __get_FPSCR() (__arm_rsr("FPSCR"))
#define __set_FPSCR(VALUE) (__arm_wsr("FPSCR", (VALUE)))
#else
#define __get_FPSCR() ( 0 )
#define __set_FPSCR(VALUE) ((void)VALUE)
#endif
#define __get_IPSR() (__arm_rsr("IPSR"))
#define __get_MSP() (__arm_rsr("MSP"))
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
#define __get_MSPLIM() (0U)
#else
#define __get_MSPLIM() (__arm_rsr("MSPLIM"))
#endif
#define __get_PRIMASK() (__arm_rsr("PRIMASK"))
#define __get_PSP() (__arm_rsr("PSP"))
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
#define __get_PSPLIM() (0U)
#else
#define __get_PSPLIM() (__arm_rsr("PSPLIM"))
#endif
#define __get_xPSR() (__arm_rsr("xPSR"))
#define __set_BASEPRI(VALUE) (__arm_wsr("BASEPRI", (VALUE)))
#define __set_BASEPRI_MAX(VALUE) (__arm_wsr("BASEPRI_MAX", (VALUE)))
#define __set_CONTROL(VALUE) (__arm_wsr("CONTROL", (VALUE)))
#define __set_FAULTMASK(VALUE) (__arm_wsr("FAULTMASK", (VALUE)))
#define __set_MSP(VALUE) (__arm_wsr("MSP", (VALUE)))
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
#define __set_MSPLIM(VALUE) ((void)(VALUE))
#else
#define __set_MSPLIM(VALUE) (__arm_wsr("MSPLIM", (VALUE)))
#endif
#define __set_PRIMASK(VALUE) (__arm_wsr("PRIMASK", (VALUE)))
#define __set_PSP(VALUE) (__arm_wsr("PSP", (VALUE)))
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
#define __set_PSPLIM(VALUE) ((void)(VALUE))
#else
#define __set_PSPLIM(VALUE) (__arm_wsr("PSPLIM", (VALUE)))
#endif
#define __TZ_get_CONTROL_NS() (__arm_rsr("CONTROL_NS"))
#define __TZ_set_CONTROL_NS(VALUE) (__arm_wsr("CONTROL_NS", (VALUE)))
#define __TZ_get_PSP_NS() (__arm_rsr("PSP_NS"))
#define __TZ_set_PSP_NS(VALUE) (__arm_wsr("PSP_NS", (VALUE)))
#define __TZ_get_MSP_NS() (__arm_rsr("MSP_NS"))
#define __TZ_set_MSP_NS(VALUE) (__arm_wsr("MSP_NS", (VALUE)))
#define __TZ_get_SP_NS() (__arm_rsr("SP_NS"))
#define __TZ_set_SP_NS(VALUE) (__arm_wsr("SP_NS", (VALUE)))
#define __TZ_get_PRIMASK_NS() (__arm_rsr("PRIMASK_NS"))
#define __TZ_set_PRIMASK_NS(VALUE) (__arm_wsr("PRIMASK_NS", (VALUE)))
#define __TZ_get_BASEPRI_NS() (__arm_rsr("BASEPRI_NS"))
#define __TZ_set_BASEPRI_NS(VALUE) (__arm_wsr("BASEPRI_NS", (VALUE)))
#define __TZ_get_FAULTMASK_NS() (__arm_rsr("FAULTMASK_NS"))
#define __TZ_set_FAULTMASK_NS(VALUE)(__arm_wsr("FAULTMASK_NS", (VALUE)))
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
#define __TZ_get_PSPLIM_NS() (0U)
#define __TZ_set_PSPLIM_NS(VALUE) ((void)(VALUE))
#else
#define __TZ_get_PSPLIM_NS() (__arm_rsr("PSPLIM_NS"))
#define __TZ_set_PSPLIM_NS(VALUE) (__arm_wsr("PSPLIM_NS", (VALUE)))
#endif
#define __TZ_get_MSPLIM_NS() (__arm_rsr("MSPLIM_NS"))
#define __TZ_set_MSPLIM_NS(VALUE) (__arm_wsr("MSPLIM_NS", (VALUE)))
#define __NOP __iar_builtin_no_operation
#define __CLZ __iar_builtin_CLZ
#define __CLREX __iar_builtin_CLREX
#define __DMB __iar_builtin_DMB
#define __DSB __iar_builtin_DSB
#define __ISB __iar_builtin_ISB
#define __LDREXB __iar_builtin_LDREXB
#define __LDREXH __iar_builtin_LDREXH
#define __LDREXW __iar_builtin_LDREX
#define __RBIT __iar_builtin_RBIT
#define __REV __iar_builtin_REV
#define __REV16 __iar_builtin_REV16
__IAR_FT int16_t __REVSH(int16_t val)
{
return (int16_t) __iar_builtin_REVSH(val);
}
#define __ROR __iar_builtin_ROR
#define __RRX __iar_builtin_RRX
#define __SEV __iar_builtin_SEV
#if !__IAR_M0_FAMILY
#define __SSAT __iar_builtin_SSAT
#endif
#define __STREXB __iar_builtin_STREXB
#define __STREXH __iar_builtin_STREXH
#define __STREXW __iar_builtin_STREX
#if !__IAR_M0_FAMILY
#define __USAT __iar_builtin_USAT
#endif
#define __WFE __iar_builtin_WFE
#define __WFI __iar_builtin_WFI
#if __ARM_MEDIA__
#define __SADD8 __iar_builtin_SADD8
#define __QADD8 __iar_builtin_QADD8
#define __SHADD8 __iar_builtin_SHADD8
#define __UADD8 __iar_builtin_UADD8
#define __UQADD8 __iar_builtin_UQADD8
#define __UHADD8 __iar_builtin_UHADD8
#define __SSUB8 __iar_builtin_SSUB8
#define __QSUB8 __iar_builtin_QSUB8
#define __SHSUB8 __iar_builtin_SHSUB8
#define __USUB8 __iar_builtin_USUB8
#define __UQSUB8 __iar_builtin_UQSUB8
#define __UHSUB8 __iar_builtin_UHSUB8
#define __SADD16 __iar_builtin_SADD16
#define __QADD16 __iar_builtin_QADD16
#define __SHADD16 __iar_builtin_SHADD16
#define __UADD16 __iar_builtin_UADD16
#define __UQADD16 __iar_builtin_UQADD16
#define __UHADD16 __iar_builtin_UHADD16
#define __SSUB16 __iar_builtin_SSUB16
#define __QSUB16 __iar_builtin_QSUB16
#define __SHSUB16 __iar_builtin_SHSUB16
#define __USUB16 __iar_builtin_USUB16
#define __UQSUB16 __iar_builtin_UQSUB16
#define __UHSUB16 __iar_builtin_UHSUB16
#define __SASX __iar_builtin_SASX
#define __QASX __iar_builtin_QASX
#define __SHASX __iar_builtin_SHASX
#define __UASX __iar_builtin_UASX
#define __UQASX __iar_builtin_UQASX
#define __UHASX __iar_builtin_UHASX
#define __SSAX __iar_builtin_SSAX
#define __QSAX __iar_builtin_QSAX
#define __SHSAX __iar_builtin_SHSAX
#define __USAX __iar_builtin_USAX
#define __UQSAX __iar_builtin_UQSAX
#define __UHSAX __iar_builtin_UHSAX
#define __USAD8 __iar_builtin_USAD8
#define __USADA8 __iar_builtin_USADA8
#define __SSAT16 __iar_builtin_SSAT16
#define __USAT16 __iar_builtin_USAT16
#define __UXTB16 __iar_builtin_UXTB16
#define __UXTAB16 __iar_builtin_UXTAB16
#define __SXTB16 __iar_builtin_SXTB16
#define __SXTAB16 __iar_builtin_SXTAB16
#define __SMUAD __iar_builtin_SMUAD
#define __SMUADX __iar_builtin_SMUADX
#define __SMMLA __iar_builtin_SMMLA
#define __SMLAD __iar_builtin_SMLAD
#define __SMLADX __iar_builtin_SMLADX
#define __SMLALD __iar_builtin_SMLALD
#define __SMLALDX __iar_builtin_SMLALDX
#define __SMUSD __iar_builtin_SMUSD
#define __SMUSDX __iar_builtin_SMUSDX
#define __SMLSD __iar_builtin_SMLSD
#define __SMLSDX __iar_builtin_SMLSDX
#define __SMLSLD __iar_builtin_SMLSLD
#define __SMLSLDX __iar_builtin_SMLSLDX
#define __SEL __iar_builtin_SEL
#define __QADD __iar_builtin_QADD
#define __QSUB __iar_builtin_QSUB
#define __PKHBT __iar_builtin_PKHBT
#define __PKHTB __iar_builtin_PKHTB
#endif
#else /* __ICCARM_INTRINSICS_VERSION__ == 2 */
#if __IAR_M0_FAMILY
/* Avoid clash between intrinsics.h and arm_math.h when compiling for Cortex-M0. */
#define __CLZ __cmsis_iar_clz_not_active
#define __SSAT __cmsis_iar_ssat_not_active
#define __USAT __cmsis_iar_usat_not_active
#define __RBIT __cmsis_iar_rbit_not_active
#define __get_APSR __cmsis_iar_get_APSR_not_active
#endif
#if (!((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) ))
#define __get_FPSCR __cmsis_iar_get_FPSR_not_active
#define __set_FPSCR __cmsis_iar_set_FPSR_not_active
#endif
#ifdef __INTRINSICS_INCLUDED
#error intrinsics.h is already included previously!
#endif
#include <intrinsics.h>
#if __IAR_M0_FAMILY
/* Avoid clash between intrinsics.h and arm_math.h when compiling for Cortex-M0. */
#undef __CLZ
#undef __SSAT
#undef __USAT
#undef __RBIT
#undef __get_APSR
__STATIC_INLINE uint8_t __CLZ(uint32_t data)
{
if (data == 0U) { return 32U; }
uint32_t count = 0U;
uint32_t mask = 0x80000000U;
while ((data & mask) == 0U)
{
count += 1U;
mask = mask >> 1U;
}
return count;
}
__STATIC_INLINE uint32_t __RBIT(uint32_t v)
{
uint8_t sc = 31U;
uint32_t r = v;
for (v >>= 1U; v; v >>= 1U)
{
r <<= 1U;
r |= v & 1U;
sc--;
}
return (r << sc);
}
__STATIC_INLINE uint32_t __get_APSR(void)
{
uint32_t res;
__asm("MRS %0,APSR" : "=r" (res));
return res;
}
#endif
#if (!((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) ))
#undef __get_FPSCR
#undef __set_FPSCR
#define __get_FPSCR() (0)
#define __set_FPSCR(VALUE) ((void)VALUE)
#endif
#pragma diag_suppress=Pe940
#pragma diag_suppress=Pe177
#define __enable_irq __enable_interrupt
#define __disable_irq __disable_interrupt
#define __NOP __no_operation
#define __get_xPSR __get_PSR
#if (!defined(__ARM_ARCH_6M__) || __ARM_ARCH_6M__==0)
__IAR_FT uint32_t __LDREXW(uint32_t volatile *ptr)
{
return __LDREX((unsigned long *)ptr);
}
__IAR_FT uint32_t __STREXW(uint32_t value, uint32_t volatile *ptr)
{
return __STREX(value, (unsigned long *)ptr);
}
#endif
/* __CORTEX_M is defined in core_cm0.h, core_cm3.h and core_cm4.h. */
#if (__CORTEX_M >= 0x03)
__IAR_FT uint32_t __RRX(uint32_t value)
{
uint32_t result;
__ASM("RRX %0, %1" : "=r"(result) : "r" (value) : "cc");
return(result);
}
__IAR_FT void __set_BASEPRI_MAX(uint32_t value)
{
__asm volatile("MSR BASEPRI_MAX,%0"::"r" (value));
}
#define __enable_fault_irq __enable_fiq
#define __disable_fault_irq __disable_fiq
#endif /* (__CORTEX_M >= 0x03) */
__IAR_FT uint32_t __ROR(uint32_t op1, uint32_t op2)
{
return (op1 >> op2) | (op1 << ((sizeof(op1)*8)-op2));
}
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
__IAR_FT uint32_t __get_MSPLIM(void)
{
uint32_t res;
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE ) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
res = 0U;
#else
__asm volatile("MRS %0,MSPLIM" : "=r" (res));
#endif
return res;
}
__IAR_FT void __set_MSPLIM(uint32_t value)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE ) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
(void)value;
#else
__asm volatile("MSR MSPLIM,%0" :: "r" (value));
#endif
}
__IAR_FT uint32_t __get_PSPLIM(void)
{
uint32_t res;
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE ) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
res = 0U;
#else
__asm volatile("MRS %0,PSPLIM" : "=r" (res));
#endif
return res;
}
__IAR_FT void __set_PSPLIM(uint32_t value)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE ) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)value;
#else
__asm volatile("MSR PSPLIM,%0" :: "r" (value));
#endif
}
__IAR_FT uint32_t __TZ_get_CONTROL_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,CONTROL_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_CONTROL_NS(uint32_t value)
{
__asm volatile("MSR CONTROL_NS,%0" :: "r" (value));
}
__IAR_FT uint32_t __TZ_get_PSP_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,PSP_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_PSP_NS(uint32_t value)
{
__asm volatile("MSR PSP_NS,%0" :: "r" (value));
}
__IAR_FT uint32_t __TZ_get_MSP_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,MSP_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_MSP_NS(uint32_t value)
{
__asm volatile("MSR MSP_NS,%0" :: "r" (value));
}
__IAR_FT uint32_t __TZ_get_SP_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,SP_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_SP_NS(uint32_t value)
{
__asm volatile("MSR SP_NS,%0" :: "r" (value));
}
__IAR_FT uint32_t __TZ_get_PRIMASK_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,PRIMASK_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_PRIMASK_NS(uint32_t value)
{
__asm volatile("MSR PRIMASK_NS,%0" :: "r" (value));
}
__IAR_FT uint32_t __TZ_get_BASEPRI_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,BASEPRI_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_BASEPRI_NS(uint32_t value)
{
__asm volatile("MSR BASEPRI_NS,%0" :: "r" (value));
}
__IAR_FT uint32_t __TZ_get_FAULTMASK_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,FAULTMASK_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_FAULTMASK_NS(uint32_t value)
{
__asm volatile("MSR FAULTMASK_NS,%0" :: "r" (value));
}
__IAR_FT uint32_t __TZ_get_PSPLIM_NS(void)
{
uint32_t res;
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE ) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
res = 0U;
#else
__asm volatile("MRS %0,PSPLIM_NS" : "=r" (res));
#endif
return res;
}
__IAR_FT void __TZ_set_PSPLIM_NS(uint32_t value)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE ) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)value;
#else
__asm volatile("MSR PSPLIM_NS,%0" :: "r" (value));
#endif
}
__IAR_FT uint32_t __TZ_get_MSPLIM_NS(void)
{
uint32_t res;
__asm volatile("MRS %0,MSPLIM_NS" : "=r" (res));
return res;
}
__IAR_FT void __TZ_set_MSPLIM_NS(uint32_t value)
{
__asm volatile("MSR MSPLIM_NS,%0" :: "r" (value));
}
#endif /* __ARM_ARCH_8M_MAIN__ or __ARM_ARCH_8M_BASE__ */
#endif /* __ICCARM_INTRINSICS_VERSION__ == 2 */
#define __BKPT(value) __asm volatile ("BKPT %0" : : "i"(value))
#if __IAR_M0_FAMILY
__STATIC_INLINE int32_t __SSAT(int32_t val, uint32_t sat)
{
if ((sat >= 1U) && (sat <= 32U))
{
const int32_t max = (int32_t)((1U << (sat - 1U)) - 1U);
const int32_t min = -1 - max ;
if (val > max)
{
return max;
}
else if (val < min)
{
return min;
}
}
return val;
}
__STATIC_INLINE uint32_t __USAT(int32_t val, uint32_t sat)
{
if (sat <= 31U)
{
const uint32_t max = ((1U << sat) - 1U);
if (val > (int32_t)max)
{
return max;
}
else if (val < 0)
{
return 0U;
}
}
return (uint32_t)val;
}
#endif
#if (__CORTEX_M >= 0x03) /* __CORTEX_M is defined in core_cm0.h, core_cm3.h and core_cm4.h. */
__IAR_FT uint8_t __LDRBT(volatile uint8_t *addr)
{
uint32_t res;
__ASM("LDRBT %0, [%1]" : "=r" (res) : "r" (addr) : "memory");
return ((uint8_t)res);
}
__IAR_FT uint16_t __LDRHT(volatile uint16_t *addr)
{
uint32_t res;
__ASM("LDRHT %0, [%1]" : "=r" (res) : "r" (addr) : "memory");
return ((uint16_t)res);
}
__IAR_FT uint32_t __LDRT(volatile uint32_t *addr)
{
uint32_t res;
__ASM("LDRT %0, [%1]" : "=r" (res) : "r" (addr) : "memory");
return res;
}
__IAR_FT void __STRBT(uint8_t value, volatile uint8_t *addr)
{
__ASM("STRBT %1, [%0]" : : "r" (addr), "r" ((uint32_t)value) : "memory");
}
__IAR_FT void __STRHT(uint16_t value, volatile uint16_t *addr)
{
__ASM("STRHT %1, [%0]" : : "r" (addr), "r" ((uint32_t)value) : "memory");
}
__IAR_FT void __STRT(uint32_t value, volatile uint32_t *addr)
{
__ASM("STRT %1, [%0]" : : "r" (addr), "r" (value) : "memory");
}
#endif /* (__CORTEX_M >= 0x03) */
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
__IAR_FT uint8_t __LDAB(volatile uint8_t *ptr)
{
uint32_t res;
__ASM volatile ("LDAB %0, [%1]" : "=r" (res) : "r" (ptr) : "memory");
return ((uint8_t)res);
}
__IAR_FT uint16_t __LDAH(volatile uint16_t *ptr)
{
uint32_t res;
__ASM volatile ("LDAH %0, [%1]" : "=r" (res) : "r" (ptr) : "memory");
return ((uint16_t)res);
}
__IAR_FT uint32_t __LDA(volatile uint32_t *ptr)
{
uint32_t res;
__ASM volatile ("LDA %0, [%1]" : "=r" (res) : "r" (ptr) : "memory");
return res;
}
__IAR_FT void __STLB(uint8_t value, volatile uint8_t *ptr)
{
__ASM volatile ("STLB %1, [%0]" :: "r" (ptr), "r" (value) : "memory");
}
__IAR_FT void __STLH(uint16_t value, volatile uint16_t *ptr)
{
__ASM volatile ("STLH %1, [%0]" :: "r" (ptr), "r" (value) : "memory");
}
__IAR_FT void __STL(uint32_t value, volatile uint32_t *ptr)
{
__ASM volatile ("STL %1, [%0]" :: "r" (ptr), "r" (value) : "memory");
}
__IAR_FT uint8_t __LDAEXB(volatile uint8_t *ptr)
{
uint32_t res;
__ASM volatile ("LDAEXB %0, [%1]" : "=r" (res) : "r" (ptr) : "memory");
return ((uint8_t)res);
}
__IAR_FT uint16_t __LDAEXH(volatile uint16_t *ptr)
{
uint32_t res;
__ASM volatile ("LDAEXH %0, [%1]" : "=r" (res) : "r" (ptr) : "memory");
return ((uint16_t)res);
}
__IAR_FT uint32_t __LDAEX(volatile uint32_t *ptr)
{
uint32_t res;
__ASM volatile ("LDAEX %0, [%1]" : "=r" (res) : "r" (ptr) : "memory");
return res;
}
__IAR_FT uint32_t __STLEXB(uint8_t value, volatile uint8_t *ptr)
{
uint32_t res;
__ASM volatile ("STLEXB %0, %2, [%1]" : "=r" (res) : "r" (ptr), "r" (value) : "memory");
return res;
}
__IAR_FT uint32_t __STLEXH(uint16_t value, volatile uint16_t *ptr)
{
uint32_t res;
__ASM volatile ("STLEXH %0, %2, [%1]" : "=r" (res) : "r" (ptr), "r" (value) : "memory");
return res;
}
__IAR_FT uint32_t __STLEX(uint32_t value, volatile uint32_t *ptr)
{
uint32_t res;
__ASM volatile ("STLEX %0, %2, [%1]" : "=r" (res) : "r" (ptr), "r" (value) : "memory");
return res;
}
#endif /* __ARM_ARCH_8M_MAIN__ or __ARM_ARCH_8M_BASE__ */
#undef __IAR_FT
#undef __IAR_M0_FAMILY
#undef __ICCARM_V8
#pragma diag_default=Pe940
#pragma diag_default=Pe177
#endif /* __CMSIS_ICCARM_H__ */
| 28,163 | C | 28.185492 | 106 | 0.553457 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm0.h | /**************************************************************************//**
* @file core_cm0.h
* @brief CMSIS Cortex-M0 Core Peripheral Access Layer Header File
* @version V5.0.6
* @date 13. March 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM0_H_GENERIC
#define __CORE_CM0_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M0
@{
*/
#include "cmsis_version.h"
/* CMSIS CM0 definitions */
#define __CM0_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM0_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM0_CMSIS_VERSION ((__CM0_CMSIS_VERSION_MAIN << 16U) | \
__CM0_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (0U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM0_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM0_H_DEPENDANT
#define __CORE_CM0_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM0_REV
#define __CM0_REV 0x0000U
#warning "__CM0_REV not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 2U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M0 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:28; /*!< bit: 0..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:15; /*!< bit: 9..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t _reserved1:3; /*!< bit: 25..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t _reserved0:1; /*!< bit: 0 Reserved */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[1U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[31U];
__IOM uint32_t ICER[1U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RESERVED1[31U];
__IOM uint32_t ISPR[1U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[31U];
__IOM uint32_t ICPR[1U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[31U];
uint32_t RESERVED4[64U];
__IOM uint32_t IP[8U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register */
} NVIC_Type;
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
uint32_t RESERVED0;
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
uint32_t RESERVED1;
__IOM uint32_t SHP[2U]; /*!< Offset: 0x01C (R/W) System Handlers Priority Registers. [0] is RESERVED */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Cortex-M0 Core Debug Registers (DCB registers, SHCSR, and DFSR) are only accessible over DAP and not via processor.
Therefore they are not covered by the Cortex-M0 header file.
@{
*/
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
/*#define NVIC_GetActive __NVIC_GetActive not available for Cortex-M0 */
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
/* Interrupt Priorities are WORD accessible only under Armv6-M */
/* The following MACROS handle generation of the register offset and byte masks */
#define _BIT_SHIFT(IRQn) ( ((((uint32_t)(int32_t)(IRQn)) ) & 0x03UL) * 8UL)
#define _SHP_IDX(IRQn) ( (((((uint32_t)(int32_t)(IRQn)) & 0x0FUL)-8UL) >> 2UL) )
#define _IP_IDX(IRQn) ( (((uint32_t)(int32_t)(IRQn)) >> 2UL) )
#define __NVIC_SetPriorityGrouping(X) (void)(X)
#define __NVIC_GetPriorityGrouping() (0U)
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[_IP_IDX(IRQn)] = ((uint32_t)(NVIC->IP[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB->SHP[_SHP_IDX(IRQn)] = ((uint32_t)(SCB->SHP[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IP[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB->SHP[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
Address 0 must be mapped to SRAM.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t vectors = 0x0U;
(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4)) = vector;
/* ARM Application Note 321 states that the M0 does not require the architectural barrier */
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t vectors = 0x0U;
return (uint32_t)(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4));
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = ((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
SCB_AIRCR_SYSRESETREQ_Msk);
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM0_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 41,430 | C | 42.474292 | 178 | 0.556384 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/mpu_armv8.h | /******************************************************************************
* @file mpu_armv8.h
* @brief CMSIS MPU API for Armv8-M and Armv8.1-M MPU
* @version V5.1.0
* @date 08. March 2019
******************************************************************************/
/*
* Copyright (c) 2017-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef ARM_MPU_ARMV8_H
#define ARM_MPU_ARMV8_H
/** \brief Attribute for device memory (outer only) */
#define ARM_MPU_ATTR_DEVICE ( 0U )
/** \brief Attribute for non-cacheable, normal memory */
#define ARM_MPU_ATTR_NON_CACHEABLE ( 4U )
/** \brief Attribute for normal memory (outer and inner)
* \param NT Non-Transient: Set to 1 for non-transient data.
* \param WB Write-Back: Set to 1 to use write-back update policy.
* \param RA Read Allocation: Set to 1 to use cache allocation on read miss.
* \param WA Write Allocation: Set to 1 to use cache allocation on write miss.
*/
#define ARM_MPU_ATTR_MEMORY_(NT, WB, RA, WA) \
(((NT & 1U) << 3U) | ((WB & 1U) << 2U) | ((RA & 1U) << 1U) | (WA & 1U))
/** \brief Device memory type non Gathering, non Re-ordering, non Early Write Acknowledgement */
#define ARM_MPU_ATTR_DEVICE_nGnRnE (0U)
/** \brief Device memory type non Gathering, non Re-ordering, Early Write Acknowledgement */
#define ARM_MPU_ATTR_DEVICE_nGnRE (1U)
/** \brief Device memory type non Gathering, Re-ordering, Early Write Acknowledgement */
#define ARM_MPU_ATTR_DEVICE_nGRE (2U)
/** \brief Device memory type Gathering, Re-ordering, Early Write Acknowledgement */
#define ARM_MPU_ATTR_DEVICE_GRE (3U)
/** \brief Memory Attribute
* \param O Outer memory attributes
* \param I O == ARM_MPU_ATTR_DEVICE: Device memory attributes, else: Inner memory attributes
*/
#define ARM_MPU_ATTR(O, I) (((O & 0xFU) << 4U) | (((O & 0xFU) != 0U) ? (I & 0xFU) : ((I & 0x3U) << 2U)))
/** \brief Normal memory non-shareable */
#define ARM_MPU_SH_NON (0U)
/** \brief Normal memory outer shareable */
#define ARM_MPU_SH_OUTER (2U)
/** \brief Normal memory inner shareable */
#define ARM_MPU_SH_INNER (3U)
/** \brief Memory access permissions
* \param RO Read-Only: Set to 1 for read-only memory.
* \param NP Non-Privileged: Set to 1 for non-privileged memory.
*/
#define ARM_MPU_AP_(RO, NP) (((RO & 1U) << 1U) | (NP & 1U))
/** \brief Region Base Address Register value
* \param BASE The base address bits [31:5] of a memory region. The value is zero extended. Effective address gets 32 byte aligned.
* \param SH Defines the Shareability domain for this memory region.
* \param RO Read-Only: Set to 1 for a read-only memory region.
* \param NP Non-Privileged: Set to 1 for a non-privileged memory region.
* \oaram XN eXecute Never: Set to 1 for a non-executable memory region.
*/
#define ARM_MPU_RBAR(BASE, SH, RO, NP, XN) \
((BASE & MPU_RBAR_BASE_Msk) | \
((SH << MPU_RBAR_SH_Pos) & MPU_RBAR_SH_Msk) | \
((ARM_MPU_AP_(RO, NP) << MPU_RBAR_AP_Pos) & MPU_RBAR_AP_Msk) | \
((XN << MPU_RBAR_XN_Pos) & MPU_RBAR_XN_Msk))
/** \brief Region Limit Address Register value
* \param LIMIT The limit address bits [31:5] for this memory region. The value is one extended.
* \param IDX The attribute index to be associated with this memory region.
*/
#define ARM_MPU_RLAR(LIMIT, IDX) \
((LIMIT & MPU_RLAR_LIMIT_Msk) | \
((IDX << MPU_RLAR_AttrIndx_Pos) & MPU_RLAR_AttrIndx_Msk) | \
(MPU_RLAR_EN_Msk))
#if defined(MPU_RLAR_PXN_Pos)
/** \brief Region Limit Address Register with PXN value
* \param LIMIT The limit address bits [31:5] for this memory region. The value is one extended.
* \param PXN Privileged execute never. Defines whether code can be executed from this privileged region.
* \param IDX The attribute index to be associated with this memory region.
*/
#define ARM_MPU_RLAR_PXN(LIMIT, PXN, IDX) \
((LIMIT & MPU_RLAR_LIMIT_Msk) | \
((PXN << MPU_RLAR_PXN_Pos) & MPU_RLAR_PXN_Msk) | \
((IDX << MPU_RLAR_AttrIndx_Pos) & MPU_RLAR_AttrIndx_Msk) | \
(MPU_RLAR_EN_Msk))
#endif
/**
* Struct for a single MPU Region
*/
typedef struct {
uint32_t RBAR; /*!< Region Base Address Register value */
uint32_t RLAR; /*!< Region Limit Address Register value */
} ARM_MPU_Region_t;
/** Enable the MPU.
* \param MPU_Control Default access permissions for unconfigured regions.
*/
__STATIC_INLINE void ARM_MPU_Enable(uint32_t MPU_Control)
{
MPU->CTRL = MPU_Control | MPU_CTRL_ENABLE_Msk;
#ifdef SCB_SHCSR_MEMFAULTENA_Msk
SCB->SHCSR |= SCB_SHCSR_MEMFAULTENA_Msk;
#endif
__DSB();
__ISB();
}
/** Disable the MPU.
*/
__STATIC_INLINE void ARM_MPU_Disable(void)
{
__DMB();
#ifdef SCB_SHCSR_MEMFAULTENA_Msk
SCB->SHCSR &= ~SCB_SHCSR_MEMFAULTENA_Msk;
#endif
MPU->CTRL &= ~MPU_CTRL_ENABLE_Msk;
}
#ifdef MPU_NS
/** Enable the Non-secure MPU.
* \param MPU_Control Default access permissions for unconfigured regions.
*/
__STATIC_INLINE void ARM_MPU_Enable_NS(uint32_t MPU_Control)
{
MPU_NS->CTRL = MPU_Control | MPU_CTRL_ENABLE_Msk;
#ifdef SCB_SHCSR_MEMFAULTENA_Msk
SCB_NS->SHCSR |= SCB_SHCSR_MEMFAULTENA_Msk;
#endif
__DSB();
__ISB();
}
/** Disable the Non-secure MPU.
*/
__STATIC_INLINE void ARM_MPU_Disable_NS(void)
{
__DMB();
#ifdef SCB_SHCSR_MEMFAULTENA_Msk
SCB_NS->SHCSR &= ~SCB_SHCSR_MEMFAULTENA_Msk;
#endif
MPU_NS->CTRL &= ~MPU_CTRL_ENABLE_Msk;
}
#endif
/** Set the memory attribute encoding to the given MPU.
* \param mpu Pointer to the MPU to be configured.
* \param idx The attribute index to be set [0-7]
* \param attr The attribute value to be set.
*/
__STATIC_INLINE void ARM_MPU_SetMemAttrEx(MPU_Type* mpu, uint8_t idx, uint8_t attr)
{
const uint8_t reg = idx / 4U;
const uint32_t pos = ((idx % 4U) * 8U);
const uint32_t mask = 0xFFU << pos;
if (reg >= (sizeof(mpu->MAIR) / sizeof(mpu->MAIR[0]))) {
return; // invalid index
}
mpu->MAIR[reg] = ((mpu->MAIR[reg] & ~mask) | ((attr << pos) & mask));
}
/** Set the memory attribute encoding.
* \param idx The attribute index to be set [0-7]
* \param attr The attribute value to be set.
*/
__STATIC_INLINE void ARM_MPU_SetMemAttr(uint8_t idx, uint8_t attr)
{
ARM_MPU_SetMemAttrEx(MPU, idx, attr);
}
#ifdef MPU_NS
/** Set the memory attribute encoding to the Non-secure MPU.
* \param idx The attribute index to be set [0-7]
* \param attr The attribute value to be set.
*/
__STATIC_INLINE void ARM_MPU_SetMemAttr_NS(uint8_t idx, uint8_t attr)
{
ARM_MPU_SetMemAttrEx(MPU_NS, idx, attr);
}
#endif
/** Clear and disable the given MPU region of the given MPU.
* \param mpu Pointer to MPU to be used.
* \param rnr Region number to be cleared.
*/
__STATIC_INLINE void ARM_MPU_ClrRegionEx(MPU_Type* mpu, uint32_t rnr)
{
mpu->RNR = rnr;
mpu->RLAR = 0U;
}
/** Clear and disable the given MPU region.
* \param rnr Region number to be cleared.
*/
__STATIC_INLINE void ARM_MPU_ClrRegion(uint32_t rnr)
{
ARM_MPU_ClrRegionEx(MPU, rnr);
}
#ifdef MPU_NS
/** Clear and disable the given Non-secure MPU region.
* \param rnr Region number to be cleared.
*/
__STATIC_INLINE void ARM_MPU_ClrRegion_NS(uint32_t rnr)
{
ARM_MPU_ClrRegionEx(MPU_NS, rnr);
}
#endif
/** Configure the given MPU region of the given MPU.
* \param mpu Pointer to MPU to be used.
* \param rnr Region number to be configured.
* \param rbar Value for RBAR register.
* \param rlar Value for RLAR register.
*/
__STATIC_INLINE void ARM_MPU_SetRegionEx(MPU_Type* mpu, uint32_t rnr, uint32_t rbar, uint32_t rlar)
{
mpu->RNR = rnr;
mpu->RBAR = rbar;
mpu->RLAR = rlar;
}
/** Configure the given MPU region.
* \param rnr Region number to be configured.
* \param rbar Value for RBAR register.
* \param rlar Value for RLAR register.
*/
__STATIC_INLINE void ARM_MPU_SetRegion(uint32_t rnr, uint32_t rbar, uint32_t rlar)
{
ARM_MPU_SetRegionEx(MPU, rnr, rbar, rlar);
}
#ifdef MPU_NS
/** Configure the given Non-secure MPU region.
* \param rnr Region number to be configured.
* \param rbar Value for RBAR register.
* \param rlar Value for RLAR register.
*/
__STATIC_INLINE void ARM_MPU_SetRegion_NS(uint32_t rnr, uint32_t rbar, uint32_t rlar)
{
ARM_MPU_SetRegionEx(MPU_NS, rnr, rbar, rlar);
}
#endif
/** Memcopy with strictly ordered memory access, e.g. for register targets.
* \param dst Destination data is copied to.
* \param src Source data is copied from.
* \param len Amount of data words to be copied.
*/
__STATIC_INLINE void ARM_MPU_OrderedMemcpy(volatile uint32_t* dst, const uint32_t* __RESTRICT src, uint32_t len)
{
uint32_t i;
for (i = 0U; i < len; ++i)
{
dst[i] = src[i];
}
}
/** Load the given number of MPU regions from a table to the given MPU.
* \param mpu Pointer to the MPU registers to be used.
* \param rnr First region number to be configured.
* \param table Pointer to the MPU configuration table.
* \param cnt Amount of regions to be configured.
*/
__STATIC_INLINE void ARM_MPU_LoadEx(MPU_Type* mpu, uint32_t rnr, ARM_MPU_Region_t const* table, uint32_t cnt)
{
const uint32_t rowWordSize = sizeof(ARM_MPU_Region_t)/4U;
if (cnt == 1U) {
mpu->RNR = rnr;
ARM_MPU_OrderedMemcpy(&(mpu->RBAR), &(table->RBAR), rowWordSize);
} else {
uint32_t rnrBase = rnr & ~(MPU_TYPE_RALIASES-1U);
uint32_t rnrOffset = rnr % MPU_TYPE_RALIASES;
mpu->RNR = rnrBase;
while ((rnrOffset + cnt) > MPU_TYPE_RALIASES) {
uint32_t c = MPU_TYPE_RALIASES - rnrOffset;
ARM_MPU_OrderedMemcpy(&(mpu->RBAR)+(rnrOffset*2U), &(table->RBAR), c*rowWordSize);
table += c;
cnt -= c;
rnrOffset = 0U;
rnrBase += MPU_TYPE_RALIASES;
mpu->RNR = rnrBase;
}
ARM_MPU_OrderedMemcpy(&(mpu->RBAR)+(rnrOffset*2U), &(table->RBAR), cnt*rowWordSize);
}
}
/** Load the given number of MPU regions from a table.
* \param rnr First region number to be configured.
* \param table Pointer to the MPU configuration table.
* \param cnt Amount of regions to be configured.
*/
__STATIC_INLINE void ARM_MPU_Load(uint32_t rnr, ARM_MPU_Region_t const* table, uint32_t cnt)
{
ARM_MPU_LoadEx(MPU, rnr, table, cnt);
}
#ifdef MPU_NS
/** Load the given number of MPU regions from a table to the Non-secure MPU.
* \param rnr First region number to be configured.
* \param table Pointer to the MPU configuration table.
* \param cnt Amount of regions to be configured.
*/
__STATIC_INLINE void ARM_MPU_Load_NS(uint32_t rnr, ARM_MPU_Region_t const* table, uint32_t cnt)
{
ARM_MPU_LoadEx(MPU_NS, rnr, table, cnt);
}
#endif
#endif
| 11,255 | C | 31.43804 | 130 | 0.668769 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_cm3.h | /**************************************************************************//**
* @file core_cm3.h
* @brief CMSIS Cortex-M3 Core Peripheral Access Layer Header File
* @version V5.1.0
* @date 13. March 2019
******************************************************************************/
/*
* Copyright (c) 2009-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_CM3_H_GENERIC
#define __CORE_CM3_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_M3
@{
*/
#include "cmsis_version.h"
/* CMSIS CM3 definitions */
#define __CM3_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __CM3_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __CM3_CMSIS_VERSION ((__CM3_CMSIS_VERSION_MAIN << 16U) | \
__CM3_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M (3U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM3_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_CM3_H_DEPENDANT
#define __CORE_CM3_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __CM3_REV
#define __CM3_REV 0x0200U
#warning "__CM3_REV not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 3U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group Cortex_M3 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:27; /*!< bit: 0..26 Reserved */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
#define APSR_Q_Pos 27U /*!< APSR: Q Position */
#define APSR_Q_Msk (1UL << APSR_Q_Pos) /*!< APSR: Q Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:1; /*!< bit: 9 Reserved */
uint32_t ICI_IT_1:6; /*!< bit: 10..15 ICI/IT part 1 */
uint32_t _reserved1:8; /*!< bit: 16..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit */
uint32_t ICI_IT_2:2; /*!< bit: 25..26 ICI/IT part 2 */
uint32_t Q:1; /*!< bit: 27 Saturation condition flag */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_Q_Pos 27U /*!< xPSR: Q Position */
#define xPSR_Q_Msk (1UL << xPSR_Q_Pos) /*!< xPSR: Q Mask */
#define xPSR_ICI_IT_2_Pos 25U /*!< xPSR: ICI/IT part 2 Position */
#define xPSR_ICI_IT_2_Msk (3UL << xPSR_ICI_IT_2_Pos) /*!< xPSR: ICI/IT part 2 Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ICI_IT_1_Pos 10U /*!< xPSR: ICI/IT part 1 Position */
#define xPSR_ICI_IT_1_Msk (0x3FUL << xPSR_ICI_IT_1_Pos) /*!< xPSR: ICI/IT part 1 Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[8U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[24U];
__IOM uint32_t ICER[8U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RESERVED1[24U];
__IOM uint32_t ISPR[8U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[24U];
__IOM uint32_t ICPR[8U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[24U];
__IOM uint32_t IABR[8U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[56U];
__IOM uint8_t IP[240U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register (8Bit wide) */
uint32_t RESERVED5[644U];
__OM uint32_t STIR; /*!< Offset: 0xE00 ( /W) Software Trigger Interrupt Register */
} NVIC_Type;
/* Software Triggered Interrupt Register Definitions */
#define NVIC_STIR_INTID_Pos 0U /*!< STIR: INTLINESNUM Position */
#define NVIC_STIR_INTID_Msk (0x1FFUL /*<< NVIC_STIR_INTID_Pos*/) /*!< STIR: INTLINESNUM Mask */
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
__IOM uint8_t SHP[12U]; /*!< Offset: 0x018 (R/W) System Handlers Priority Registers (4-7, 8-11, 12-15) */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
__IOM uint32_t CFSR; /*!< Offset: 0x028 (R/W) Configurable Fault Status Register */
__IOM uint32_t HFSR; /*!< Offset: 0x02C (R/W) HardFault Status Register */
__IOM uint32_t DFSR; /*!< Offset: 0x030 (R/W) Debug Fault Status Register */
__IOM uint32_t MMFAR; /*!< Offset: 0x034 (R/W) MemManage Fault Address Register */
__IOM uint32_t BFAR; /*!< Offset: 0x038 (R/W) BusFault Address Register */
__IOM uint32_t AFSR; /*!< Offset: 0x03C (R/W) Auxiliary Fault Status Register */
__IM uint32_t PFR[2U]; /*!< Offset: 0x040 (R/ ) Processor Feature Register */
__IM uint32_t DFR; /*!< Offset: 0x048 (R/ ) Debug Feature Register */
__IM uint32_t ADR; /*!< Offset: 0x04C (R/ ) Auxiliary Feature Register */
__IM uint32_t MMFR[4U]; /*!< Offset: 0x050 (R/ ) Memory Model Feature Register */
__IM uint32_t ISAR[5U]; /*!< Offset: 0x060 (R/ ) Instruction Set Attributes Register */
uint32_t RESERVED0[5U];
__IOM uint32_t CPACR; /*!< Offset: 0x088 (R/W) Coprocessor Access Control Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Vector Table Offset Register Definitions */
#if defined (__CM3_REV) && (__CM3_REV < 0x0201U) /* core r2p1 */
#define SCB_VTOR_TBLBASE_Pos 29U /*!< SCB VTOR: TBLBASE Position */
#define SCB_VTOR_TBLBASE_Msk (1UL << SCB_VTOR_TBLBASE_Pos) /*!< SCB VTOR: TBLBASE Mask */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x3FFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
#else
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
#endif
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIGROUP_Pos 8U /*!< SCB AIRCR: PRIGROUP Position */
#define SCB_AIRCR_PRIGROUP_Msk (7UL << SCB_AIRCR_PRIGROUP_Pos) /*!< SCB AIRCR: PRIGROUP Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
#define SCB_AIRCR_VECTRESET_Pos 0U /*!< SCB AIRCR: VECTRESET Position */
#define SCB_AIRCR_VECTRESET_Msk (1UL /*<< SCB_AIRCR_VECTRESET_Pos*/) /*!< SCB AIRCR: VECTRESET Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
#define SCB_CCR_NONBASETHRDENA_Pos 0U /*!< SCB CCR: NONBASETHRDENA Position */
#define SCB_CCR_NONBASETHRDENA_Msk (1UL /*<< SCB_CCR_NONBASETHRDENA_Pos*/) /*!< SCB CCR: NONBASETHRDENA Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_USGFAULTENA_Pos 18U /*!< SCB SHCSR: USGFAULTENA Position */
#define SCB_SHCSR_USGFAULTENA_Msk (1UL << SCB_SHCSR_USGFAULTENA_Pos) /*!< SCB SHCSR: USGFAULTENA Mask */
#define SCB_SHCSR_BUSFAULTENA_Pos 17U /*!< SCB SHCSR: BUSFAULTENA Position */
#define SCB_SHCSR_BUSFAULTENA_Msk (1UL << SCB_SHCSR_BUSFAULTENA_Pos) /*!< SCB SHCSR: BUSFAULTENA Mask */
#define SCB_SHCSR_MEMFAULTENA_Pos 16U /*!< SCB SHCSR: MEMFAULTENA Position */
#define SCB_SHCSR_MEMFAULTENA_Msk (1UL << SCB_SHCSR_MEMFAULTENA_Pos) /*!< SCB SHCSR: MEMFAULTENA Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_BUSFAULTPENDED_Pos 14U /*!< SCB SHCSR: BUSFAULTPENDED Position */
#define SCB_SHCSR_BUSFAULTPENDED_Msk (1UL << SCB_SHCSR_BUSFAULTPENDED_Pos) /*!< SCB SHCSR: BUSFAULTPENDED Mask */
#define SCB_SHCSR_MEMFAULTPENDED_Pos 13U /*!< SCB SHCSR: MEMFAULTPENDED Position */
#define SCB_SHCSR_MEMFAULTPENDED_Msk (1UL << SCB_SHCSR_MEMFAULTPENDED_Pos) /*!< SCB SHCSR: MEMFAULTPENDED Mask */
#define SCB_SHCSR_USGFAULTPENDED_Pos 12U /*!< SCB SHCSR: USGFAULTPENDED Position */
#define SCB_SHCSR_USGFAULTPENDED_Msk (1UL << SCB_SHCSR_USGFAULTPENDED_Pos) /*!< SCB SHCSR: USGFAULTPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_MONITORACT_Pos 8U /*!< SCB SHCSR: MONITORACT Position */
#define SCB_SHCSR_MONITORACT_Msk (1UL << SCB_SHCSR_MONITORACT_Pos) /*!< SCB SHCSR: MONITORACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_USGFAULTACT_Pos 3U /*!< SCB SHCSR: USGFAULTACT Position */
#define SCB_SHCSR_USGFAULTACT_Msk (1UL << SCB_SHCSR_USGFAULTACT_Pos) /*!< SCB SHCSR: USGFAULTACT Mask */
#define SCB_SHCSR_BUSFAULTACT_Pos 1U /*!< SCB SHCSR: BUSFAULTACT Position */
#define SCB_SHCSR_BUSFAULTACT_Msk (1UL << SCB_SHCSR_BUSFAULTACT_Pos) /*!< SCB SHCSR: BUSFAULTACT Mask */
#define SCB_SHCSR_MEMFAULTACT_Pos 0U /*!< SCB SHCSR: MEMFAULTACT Position */
#define SCB_SHCSR_MEMFAULTACT_Msk (1UL /*<< SCB_SHCSR_MEMFAULTACT_Pos*/) /*!< SCB SHCSR: MEMFAULTACT Mask */
/* SCB Configurable Fault Status Register Definitions */
#define SCB_CFSR_USGFAULTSR_Pos 16U /*!< SCB CFSR: Usage Fault Status Register Position */
#define SCB_CFSR_USGFAULTSR_Msk (0xFFFFUL << SCB_CFSR_USGFAULTSR_Pos) /*!< SCB CFSR: Usage Fault Status Register Mask */
#define SCB_CFSR_BUSFAULTSR_Pos 8U /*!< SCB CFSR: Bus Fault Status Register Position */
#define SCB_CFSR_BUSFAULTSR_Msk (0xFFUL << SCB_CFSR_BUSFAULTSR_Pos) /*!< SCB CFSR: Bus Fault Status Register Mask */
#define SCB_CFSR_MEMFAULTSR_Pos 0U /*!< SCB CFSR: Memory Manage Fault Status Register Position */
#define SCB_CFSR_MEMFAULTSR_Msk (0xFFUL /*<< SCB_CFSR_MEMFAULTSR_Pos*/) /*!< SCB CFSR: Memory Manage Fault Status Register Mask */
/* MemManage Fault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_MMARVALID_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 7U) /*!< SCB CFSR (MMFSR): MMARVALID Position */
#define SCB_CFSR_MMARVALID_Msk (1UL << SCB_CFSR_MMARVALID_Pos) /*!< SCB CFSR (MMFSR): MMARVALID Mask */
#define SCB_CFSR_MSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 4U) /*!< SCB CFSR (MMFSR): MSTKERR Position */
#define SCB_CFSR_MSTKERR_Msk (1UL << SCB_CFSR_MSTKERR_Pos) /*!< SCB CFSR (MMFSR): MSTKERR Mask */
#define SCB_CFSR_MUNSTKERR_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 3U) /*!< SCB CFSR (MMFSR): MUNSTKERR Position */
#define SCB_CFSR_MUNSTKERR_Msk (1UL << SCB_CFSR_MUNSTKERR_Pos) /*!< SCB CFSR (MMFSR): MUNSTKERR Mask */
#define SCB_CFSR_DACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 1U) /*!< SCB CFSR (MMFSR): DACCVIOL Position */
#define SCB_CFSR_DACCVIOL_Msk (1UL << SCB_CFSR_DACCVIOL_Pos) /*!< SCB CFSR (MMFSR): DACCVIOL Mask */
#define SCB_CFSR_IACCVIOL_Pos (SCB_SHCSR_MEMFAULTACT_Pos + 0U) /*!< SCB CFSR (MMFSR): IACCVIOL Position */
#define SCB_CFSR_IACCVIOL_Msk (1UL /*<< SCB_CFSR_IACCVIOL_Pos*/) /*!< SCB CFSR (MMFSR): IACCVIOL Mask */
/* BusFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_BFARVALID_Pos (SCB_CFSR_BUSFAULTSR_Pos + 7U) /*!< SCB CFSR (BFSR): BFARVALID Position */
#define SCB_CFSR_BFARVALID_Msk (1UL << SCB_CFSR_BFARVALID_Pos) /*!< SCB CFSR (BFSR): BFARVALID Mask */
#define SCB_CFSR_STKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 4U) /*!< SCB CFSR (BFSR): STKERR Position */
#define SCB_CFSR_STKERR_Msk (1UL << SCB_CFSR_STKERR_Pos) /*!< SCB CFSR (BFSR): STKERR Mask */
#define SCB_CFSR_UNSTKERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 3U) /*!< SCB CFSR (BFSR): UNSTKERR Position */
#define SCB_CFSR_UNSTKERR_Msk (1UL << SCB_CFSR_UNSTKERR_Pos) /*!< SCB CFSR (BFSR): UNSTKERR Mask */
#define SCB_CFSR_IMPRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 2U) /*!< SCB CFSR (BFSR): IMPRECISERR Position */
#define SCB_CFSR_IMPRECISERR_Msk (1UL << SCB_CFSR_IMPRECISERR_Pos) /*!< SCB CFSR (BFSR): IMPRECISERR Mask */
#define SCB_CFSR_PRECISERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 1U) /*!< SCB CFSR (BFSR): PRECISERR Position */
#define SCB_CFSR_PRECISERR_Msk (1UL << SCB_CFSR_PRECISERR_Pos) /*!< SCB CFSR (BFSR): PRECISERR Mask */
#define SCB_CFSR_IBUSERR_Pos (SCB_CFSR_BUSFAULTSR_Pos + 0U) /*!< SCB CFSR (BFSR): IBUSERR Position */
#define SCB_CFSR_IBUSERR_Msk (1UL << SCB_CFSR_IBUSERR_Pos) /*!< SCB CFSR (BFSR): IBUSERR Mask */
/* UsageFault Status Register (part of SCB Configurable Fault Status Register) */
#define SCB_CFSR_DIVBYZERO_Pos (SCB_CFSR_USGFAULTSR_Pos + 9U) /*!< SCB CFSR (UFSR): DIVBYZERO Position */
#define SCB_CFSR_DIVBYZERO_Msk (1UL << SCB_CFSR_DIVBYZERO_Pos) /*!< SCB CFSR (UFSR): DIVBYZERO Mask */
#define SCB_CFSR_UNALIGNED_Pos (SCB_CFSR_USGFAULTSR_Pos + 8U) /*!< SCB CFSR (UFSR): UNALIGNED Position */
#define SCB_CFSR_UNALIGNED_Msk (1UL << SCB_CFSR_UNALIGNED_Pos) /*!< SCB CFSR (UFSR): UNALIGNED Mask */
#define SCB_CFSR_NOCP_Pos (SCB_CFSR_USGFAULTSR_Pos + 3U) /*!< SCB CFSR (UFSR): NOCP Position */
#define SCB_CFSR_NOCP_Msk (1UL << SCB_CFSR_NOCP_Pos) /*!< SCB CFSR (UFSR): NOCP Mask */
#define SCB_CFSR_INVPC_Pos (SCB_CFSR_USGFAULTSR_Pos + 2U) /*!< SCB CFSR (UFSR): INVPC Position */
#define SCB_CFSR_INVPC_Msk (1UL << SCB_CFSR_INVPC_Pos) /*!< SCB CFSR (UFSR): INVPC Mask */
#define SCB_CFSR_INVSTATE_Pos (SCB_CFSR_USGFAULTSR_Pos + 1U) /*!< SCB CFSR (UFSR): INVSTATE Position */
#define SCB_CFSR_INVSTATE_Msk (1UL << SCB_CFSR_INVSTATE_Pos) /*!< SCB CFSR (UFSR): INVSTATE Mask */
#define SCB_CFSR_UNDEFINSTR_Pos (SCB_CFSR_USGFAULTSR_Pos + 0U) /*!< SCB CFSR (UFSR): UNDEFINSTR Position */
#define SCB_CFSR_UNDEFINSTR_Msk (1UL << SCB_CFSR_UNDEFINSTR_Pos) /*!< SCB CFSR (UFSR): UNDEFINSTR Mask */
/* SCB Hard Fault Status Register Definitions */
#define SCB_HFSR_DEBUGEVT_Pos 31U /*!< SCB HFSR: DEBUGEVT Position */
#define SCB_HFSR_DEBUGEVT_Msk (1UL << SCB_HFSR_DEBUGEVT_Pos) /*!< SCB HFSR: DEBUGEVT Mask */
#define SCB_HFSR_FORCED_Pos 30U /*!< SCB HFSR: FORCED Position */
#define SCB_HFSR_FORCED_Msk (1UL << SCB_HFSR_FORCED_Pos) /*!< SCB HFSR: FORCED Mask */
#define SCB_HFSR_VECTTBL_Pos 1U /*!< SCB HFSR: VECTTBL Position */
#define SCB_HFSR_VECTTBL_Msk (1UL << SCB_HFSR_VECTTBL_Pos) /*!< SCB HFSR: VECTTBL Mask */
/* SCB Debug Fault Status Register Definitions */
#define SCB_DFSR_EXTERNAL_Pos 4U /*!< SCB DFSR: EXTERNAL Position */
#define SCB_DFSR_EXTERNAL_Msk (1UL << SCB_DFSR_EXTERNAL_Pos) /*!< SCB DFSR: EXTERNAL Mask */
#define SCB_DFSR_VCATCH_Pos 3U /*!< SCB DFSR: VCATCH Position */
#define SCB_DFSR_VCATCH_Msk (1UL << SCB_DFSR_VCATCH_Pos) /*!< SCB DFSR: VCATCH Mask */
#define SCB_DFSR_DWTTRAP_Pos 2U /*!< SCB DFSR: DWTTRAP Position */
#define SCB_DFSR_DWTTRAP_Msk (1UL << SCB_DFSR_DWTTRAP_Pos) /*!< SCB DFSR: DWTTRAP Mask */
#define SCB_DFSR_BKPT_Pos 1U /*!< SCB DFSR: BKPT Position */
#define SCB_DFSR_BKPT_Msk (1UL << SCB_DFSR_BKPT_Pos) /*!< SCB DFSR: BKPT Mask */
#define SCB_DFSR_HALTED_Pos 0U /*!< SCB DFSR: HALTED Position */
#define SCB_DFSR_HALTED_Msk (1UL /*<< SCB_DFSR_HALTED_Pos*/) /*!< SCB DFSR: HALTED Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[1U];
__IM uint32_t ICTR; /*!< Offset: 0x004 (R/ ) Interrupt Controller Type Register */
#if defined (__CM3_REV) && (__CM3_REV >= 0x200U)
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
#else
uint32_t RESERVED1[1U];
#endif
} SCnSCB_Type;
/* Interrupt Controller Type Register Definitions */
#define SCnSCB_ICTR_INTLINESNUM_Pos 0U /*!< ICTR: INTLINESNUM Position */
#define SCnSCB_ICTR_INTLINESNUM_Msk (0xFUL /*<< SCnSCB_ICTR_INTLINESNUM_Pos*/) /*!< ICTR: INTLINESNUM Mask */
/* Auxiliary Control Register Definitions */
#if defined (__CM3_REV) && (__CM3_REV >= 0x200U)
#define SCnSCB_ACTLR_DISOOFP_Pos 9U /*!< ACTLR: DISOOFP Position */
#define SCnSCB_ACTLR_DISOOFP_Msk (1UL << SCnSCB_ACTLR_DISOOFP_Pos) /*!< ACTLR: DISOOFP Mask */
#define SCnSCB_ACTLR_DISFPCA_Pos 8U /*!< ACTLR: DISFPCA Position */
#define SCnSCB_ACTLR_DISFPCA_Msk (1UL << SCnSCB_ACTLR_DISFPCA_Pos) /*!< ACTLR: DISFPCA Mask */
#define SCnSCB_ACTLR_DISFOLD_Pos 2U /*!< ACTLR: DISFOLD Position */
#define SCnSCB_ACTLR_DISFOLD_Msk (1UL << SCnSCB_ACTLR_DISFOLD_Pos) /*!< ACTLR: DISFOLD Mask */
#define SCnSCB_ACTLR_DISDEFWBUF_Pos 1U /*!< ACTLR: DISDEFWBUF Position */
#define SCnSCB_ACTLR_DISDEFWBUF_Msk (1UL << SCnSCB_ACTLR_DISDEFWBUF_Pos) /*!< ACTLR: DISDEFWBUF Mask */
#define SCnSCB_ACTLR_DISMCYCINT_Pos 0U /*!< ACTLR: DISMCYCINT Position */
#define SCnSCB_ACTLR_DISMCYCINT_Msk (1UL /*<< SCnSCB_ACTLR_DISMCYCINT_Pos*/) /*!< ACTLR: DISMCYCINT Mask */
#endif
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_ITM Instrumentation Trace Macrocell (ITM)
\brief Type definitions for the Instrumentation Trace Macrocell (ITM)
@{
*/
/**
\brief Structure type to access the Instrumentation Trace Macrocell Register (ITM).
*/
typedef struct
{
__OM union
{
__OM uint8_t u8; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 8-bit */
__OM uint16_t u16; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 16-bit */
__OM uint32_t u32; /*!< Offset: 0x000 ( /W) ITM Stimulus Port 32-bit */
} PORT [32U]; /*!< Offset: 0x000 ( /W) ITM Stimulus Port Registers */
uint32_t RESERVED0[864U];
__IOM uint32_t TER; /*!< Offset: 0xE00 (R/W) ITM Trace Enable Register */
uint32_t RESERVED1[15U];
__IOM uint32_t TPR; /*!< Offset: 0xE40 (R/W) ITM Trace Privilege Register */
uint32_t RESERVED2[15U];
__IOM uint32_t TCR; /*!< Offset: 0xE80 (R/W) ITM Trace Control Register */
uint32_t RESERVED3[32U];
uint32_t RESERVED4[43U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) ITM Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) ITM Lock Status Register */
uint32_t RESERVED5[6U];
__IM uint32_t PID4; /*!< Offset: 0xFD0 (R/ ) ITM Peripheral Identification Register #4 */
__IM uint32_t PID5; /*!< Offset: 0xFD4 (R/ ) ITM Peripheral Identification Register #5 */
__IM uint32_t PID6; /*!< Offset: 0xFD8 (R/ ) ITM Peripheral Identification Register #6 */
__IM uint32_t PID7; /*!< Offset: 0xFDC (R/ ) ITM Peripheral Identification Register #7 */
__IM uint32_t PID0; /*!< Offset: 0xFE0 (R/ ) ITM Peripheral Identification Register #0 */
__IM uint32_t PID1; /*!< Offset: 0xFE4 (R/ ) ITM Peripheral Identification Register #1 */
__IM uint32_t PID2; /*!< Offset: 0xFE8 (R/ ) ITM Peripheral Identification Register #2 */
__IM uint32_t PID3; /*!< Offset: 0xFEC (R/ ) ITM Peripheral Identification Register #3 */
__IM uint32_t CID0; /*!< Offset: 0xFF0 (R/ ) ITM Component Identification Register #0 */
__IM uint32_t CID1; /*!< Offset: 0xFF4 (R/ ) ITM Component Identification Register #1 */
__IM uint32_t CID2; /*!< Offset: 0xFF8 (R/ ) ITM Component Identification Register #2 */
__IM uint32_t CID3; /*!< Offset: 0xFFC (R/ ) ITM Component Identification Register #3 */
} ITM_Type;
/* ITM Trace Privilege Register Definitions */
#define ITM_TPR_PRIVMASK_Pos 0U /*!< ITM TPR: PRIVMASK Position */
#define ITM_TPR_PRIVMASK_Msk (0xFFFFFFFFUL /*<< ITM_TPR_PRIVMASK_Pos*/) /*!< ITM TPR: PRIVMASK Mask */
/* ITM Trace Control Register Definitions */
#define ITM_TCR_BUSY_Pos 23U /*!< ITM TCR: BUSY Position */
#define ITM_TCR_BUSY_Msk (1UL << ITM_TCR_BUSY_Pos) /*!< ITM TCR: BUSY Mask */
#define ITM_TCR_TraceBusID_Pos 16U /*!< ITM TCR: ATBID Position */
#define ITM_TCR_TraceBusID_Msk (0x7FUL << ITM_TCR_TraceBusID_Pos) /*!< ITM TCR: ATBID Mask */
#define ITM_TCR_GTSFREQ_Pos 10U /*!< ITM TCR: Global timestamp frequency Position */
#define ITM_TCR_GTSFREQ_Msk (3UL << ITM_TCR_GTSFREQ_Pos) /*!< ITM TCR: Global timestamp frequency Mask */
#define ITM_TCR_TSPrescale_Pos 8U /*!< ITM TCR: TSPrescale Position */
#define ITM_TCR_TSPrescale_Msk (3UL << ITM_TCR_TSPrescale_Pos) /*!< ITM TCR: TSPrescale Mask */
#define ITM_TCR_SWOENA_Pos 4U /*!< ITM TCR: SWOENA Position */
#define ITM_TCR_SWOENA_Msk (1UL << ITM_TCR_SWOENA_Pos) /*!< ITM TCR: SWOENA Mask */
#define ITM_TCR_DWTENA_Pos 3U /*!< ITM TCR: DWTENA Position */
#define ITM_TCR_DWTENA_Msk (1UL << ITM_TCR_DWTENA_Pos) /*!< ITM TCR: DWTENA Mask */
#define ITM_TCR_SYNCENA_Pos 2U /*!< ITM TCR: SYNCENA Position */
#define ITM_TCR_SYNCENA_Msk (1UL << ITM_TCR_SYNCENA_Pos) /*!< ITM TCR: SYNCENA Mask */
#define ITM_TCR_TSENA_Pos 1U /*!< ITM TCR: TSENA Position */
#define ITM_TCR_TSENA_Msk (1UL << ITM_TCR_TSENA_Pos) /*!< ITM TCR: TSENA Mask */
#define ITM_TCR_ITMENA_Pos 0U /*!< ITM TCR: ITM Enable bit Position */
#define ITM_TCR_ITMENA_Msk (1UL /*<< ITM_TCR_ITMENA_Pos*/) /*!< ITM TCR: ITM Enable bit Mask */
/* ITM Lock Status Register Definitions */
#define ITM_LSR_ByteAcc_Pos 2U /*!< ITM LSR: ByteAcc Position */
#define ITM_LSR_ByteAcc_Msk (1UL << ITM_LSR_ByteAcc_Pos) /*!< ITM LSR: ByteAcc Mask */
#define ITM_LSR_Access_Pos 1U /*!< ITM LSR: Access Position */
#define ITM_LSR_Access_Msk (1UL << ITM_LSR_Access_Pos) /*!< ITM LSR: Access Mask */
#define ITM_LSR_Present_Pos 0U /*!< ITM LSR: Present Position */
#define ITM_LSR_Present_Msk (1UL /*<< ITM_LSR_Present_Pos*/) /*!< ITM LSR: Present Mask */
/*@}*/ /* end of group CMSIS_ITM */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
__IOM uint32_t CYCCNT; /*!< Offset: 0x004 (R/W) Cycle Count Register */
__IOM uint32_t CPICNT; /*!< Offset: 0x008 (R/W) CPI Count Register */
__IOM uint32_t EXCCNT; /*!< Offset: 0x00C (R/W) Exception Overhead Count Register */
__IOM uint32_t SLEEPCNT; /*!< Offset: 0x010 (R/W) Sleep Count Register */
__IOM uint32_t LSUCNT; /*!< Offset: 0x014 (R/W) LSU Count Register */
__IOM uint32_t FOLDCNT; /*!< Offset: 0x018 (R/W) Folded-instruction Count Register */
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
__IOM uint32_t MASK0; /*!< Offset: 0x024 (R/W) Mask Register 0 */
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED0[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
__IOM uint32_t MASK1; /*!< Offset: 0x034 (R/W) Mask Register 1 */
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED1[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
__IOM uint32_t MASK2; /*!< Offset: 0x044 (R/W) Mask Register 2 */
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
__IOM uint32_t MASK3; /*!< Offset: 0x054 (R/W) Mask Register 3 */
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
#define DWT_CTRL_CYCEVTENA_Pos 22U /*!< DWT CTRL: CYCEVTENA Position */
#define DWT_CTRL_CYCEVTENA_Msk (0x1UL << DWT_CTRL_CYCEVTENA_Pos) /*!< DWT CTRL: CYCEVTENA Mask */
#define DWT_CTRL_FOLDEVTENA_Pos 21U /*!< DWT CTRL: FOLDEVTENA Position */
#define DWT_CTRL_FOLDEVTENA_Msk (0x1UL << DWT_CTRL_FOLDEVTENA_Pos) /*!< DWT CTRL: FOLDEVTENA Mask */
#define DWT_CTRL_LSUEVTENA_Pos 20U /*!< DWT CTRL: LSUEVTENA Position */
#define DWT_CTRL_LSUEVTENA_Msk (0x1UL << DWT_CTRL_LSUEVTENA_Pos) /*!< DWT CTRL: LSUEVTENA Mask */
#define DWT_CTRL_SLEEPEVTENA_Pos 19U /*!< DWT CTRL: SLEEPEVTENA Position */
#define DWT_CTRL_SLEEPEVTENA_Msk (0x1UL << DWT_CTRL_SLEEPEVTENA_Pos) /*!< DWT CTRL: SLEEPEVTENA Mask */
#define DWT_CTRL_EXCEVTENA_Pos 18U /*!< DWT CTRL: EXCEVTENA Position */
#define DWT_CTRL_EXCEVTENA_Msk (0x1UL << DWT_CTRL_EXCEVTENA_Pos) /*!< DWT CTRL: EXCEVTENA Mask */
#define DWT_CTRL_CPIEVTENA_Pos 17U /*!< DWT CTRL: CPIEVTENA Position */
#define DWT_CTRL_CPIEVTENA_Msk (0x1UL << DWT_CTRL_CPIEVTENA_Pos) /*!< DWT CTRL: CPIEVTENA Mask */
#define DWT_CTRL_EXCTRCENA_Pos 16U /*!< DWT CTRL: EXCTRCENA Position */
#define DWT_CTRL_EXCTRCENA_Msk (0x1UL << DWT_CTRL_EXCTRCENA_Pos) /*!< DWT CTRL: EXCTRCENA Mask */
#define DWT_CTRL_PCSAMPLENA_Pos 12U /*!< DWT CTRL: PCSAMPLENA Position */
#define DWT_CTRL_PCSAMPLENA_Msk (0x1UL << DWT_CTRL_PCSAMPLENA_Pos) /*!< DWT CTRL: PCSAMPLENA Mask */
#define DWT_CTRL_SYNCTAP_Pos 10U /*!< DWT CTRL: SYNCTAP Position */
#define DWT_CTRL_SYNCTAP_Msk (0x3UL << DWT_CTRL_SYNCTAP_Pos) /*!< DWT CTRL: SYNCTAP Mask */
#define DWT_CTRL_CYCTAP_Pos 9U /*!< DWT CTRL: CYCTAP Position */
#define DWT_CTRL_CYCTAP_Msk (0x1UL << DWT_CTRL_CYCTAP_Pos) /*!< DWT CTRL: CYCTAP Mask */
#define DWT_CTRL_POSTINIT_Pos 5U /*!< DWT CTRL: POSTINIT Position */
#define DWT_CTRL_POSTINIT_Msk (0xFUL << DWT_CTRL_POSTINIT_Pos) /*!< DWT CTRL: POSTINIT Mask */
#define DWT_CTRL_POSTPRESET_Pos 1U /*!< DWT CTRL: POSTPRESET Position */
#define DWT_CTRL_POSTPRESET_Msk (0xFUL << DWT_CTRL_POSTPRESET_Pos) /*!< DWT CTRL: POSTPRESET Mask */
#define DWT_CTRL_CYCCNTENA_Pos 0U /*!< DWT CTRL: CYCCNTENA Position */
#define DWT_CTRL_CYCCNTENA_Msk (0x1UL /*<< DWT_CTRL_CYCCNTENA_Pos*/) /*!< DWT CTRL: CYCCNTENA Mask */
/* DWT CPI Count Register Definitions */
#define DWT_CPICNT_CPICNT_Pos 0U /*!< DWT CPICNT: CPICNT Position */
#define DWT_CPICNT_CPICNT_Msk (0xFFUL /*<< DWT_CPICNT_CPICNT_Pos*/) /*!< DWT CPICNT: CPICNT Mask */
/* DWT Exception Overhead Count Register Definitions */
#define DWT_EXCCNT_EXCCNT_Pos 0U /*!< DWT EXCCNT: EXCCNT Position */
#define DWT_EXCCNT_EXCCNT_Msk (0xFFUL /*<< DWT_EXCCNT_EXCCNT_Pos*/) /*!< DWT EXCCNT: EXCCNT Mask */
/* DWT Sleep Count Register Definitions */
#define DWT_SLEEPCNT_SLEEPCNT_Pos 0U /*!< DWT SLEEPCNT: SLEEPCNT Position */
#define DWT_SLEEPCNT_SLEEPCNT_Msk (0xFFUL /*<< DWT_SLEEPCNT_SLEEPCNT_Pos*/) /*!< DWT SLEEPCNT: SLEEPCNT Mask */
/* DWT LSU Count Register Definitions */
#define DWT_LSUCNT_LSUCNT_Pos 0U /*!< DWT LSUCNT: LSUCNT Position */
#define DWT_LSUCNT_LSUCNT_Msk (0xFFUL /*<< DWT_LSUCNT_LSUCNT_Pos*/) /*!< DWT LSUCNT: LSUCNT Mask */
/* DWT Folded-instruction Count Register Definitions */
#define DWT_FOLDCNT_FOLDCNT_Pos 0U /*!< DWT FOLDCNT: FOLDCNT Position */
#define DWT_FOLDCNT_FOLDCNT_Msk (0xFFUL /*<< DWT_FOLDCNT_FOLDCNT_Pos*/) /*!< DWT FOLDCNT: FOLDCNT Mask */
/* DWT Comparator Mask Register Definitions */
#define DWT_MASK_MASK_Pos 0U /*!< DWT MASK: MASK Position */
#define DWT_MASK_MASK_Msk (0x1FUL /*<< DWT_MASK_MASK_Pos*/) /*!< DWT MASK: MASK Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVADDR1_Pos 16U /*!< DWT FUNCTION: DATAVADDR1 Position */
#define DWT_FUNCTION_DATAVADDR1_Msk (0xFUL << DWT_FUNCTION_DATAVADDR1_Pos) /*!< DWT FUNCTION: DATAVADDR1 Mask */
#define DWT_FUNCTION_DATAVADDR0_Pos 12U /*!< DWT FUNCTION: DATAVADDR0 Position */
#define DWT_FUNCTION_DATAVADDR0_Msk (0xFUL << DWT_FUNCTION_DATAVADDR0_Pos) /*!< DWT FUNCTION: DATAVADDR0 Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_LNK1ENA_Pos 9U /*!< DWT FUNCTION: LNK1ENA Position */
#define DWT_FUNCTION_LNK1ENA_Msk (0x1UL << DWT_FUNCTION_LNK1ENA_Pos) /*!< DWT FUNCTION: LNK1ENA Mask */
#define DWT_FUNCTION_DATAVMATCH_Pos 8U /*!< DWT FUNCTION: DATAVMATCH Position */
#define DWT_FUNCTION_DATAVMATCH_Msk (0x1UL << DWT_FUNCTION_DATAVMATCH_Pos) /*!< DWT FUNCTION: DATAVMATCH Mask */
#define DWT_FUNCTION_CYCMATCH_Pos 7U /*!< DWT FUNCTION: CYCMATCH Position */
#define DWT_FUNCTION_CYCMATCH_Msk (0x1UL << DWT_FUNCTION_CYCMATCH_Pos) /*!< DWT FUNCTION: CYCMATCH Mask */
#define DWT_FUNCTION_EMITRANGE_Pos 5U /*!< DWT FUNCTION: EMITRANGE Position */
#define DWT_FUNCTION_EMITRANGE_Msk (0x1UL << DWT_FUNCTION_EMITRANGE_Pos) /*!< DWT FUNCTION: EMITRANGE Mask */
#define DWT_FUNCTION_FUNCTION_Pos 0U /*!< DWT FUNCTION: FUNCTION Position */
#define DWT_FUNCTION_FUNCTION_Msk (0xFUL /*<< DWT_FUNCTION_FUNCTION_Pos*/) /*!< DWT FUNCTION: FUNCTION Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Size Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Size Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IM uint32_t FSCR; /*!< Offset: 0x308 (R/ ) Formatter Synchronization Counter Register */
uint32_t RESERVED3[759U];
__IM uint32_t TRIGGER; /*!< Offset: 0xEE8 (R/ ) TRIGGER Register */
__IM uint32_t FIFO0; /*!< Offset: 0xEEC (R/ ) Integration ETM Data */
__IM uint32_t ITATBCTR2; /*!< Offset: 0xEF0 (R/ ) ITATBCTR2 */
uint32_t RESERVED4[1U];
__IM uint32_t ITATBCTR0; /*!< Offset: 0xEF8 (R/ ) ITATBCTR0 */
__IM uint32_t FIFO1; /*!< Offset: 0xEFC (R/ ) Integration ITM Data */
__IOM uint32_t ITCTRL; /*!< Offset: 0xF00 (R/W) Integration Mode Control */
uint32_t RESERVED5[39U];
__IOM uint32_t CLAIMSET; /*!< Offset: 0xFA0 (R/W) Claim tag set */
__IOM uint32_t CLAIMCLR; /*!< Offset: 0xFA4 (R/W) Claim tag clear */
uint32_t RESERVED7[8U];
__IM uint32_t DEVID; /*!< Offset: 0xFC8 (R/ ) TPIU_DEVID */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) TPIU_DEVTYPE */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_PRESCALER_Pos 0U /*!< TPI ACPR: PRESCALER Position */
#define TPI_ACPR_PRESCALER_Msk (0x1FFFUL /*<< TPI_ACPR_PRESCALER_Pos*/) /*!< TPI ACPR: PRESCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI TRIGGER Register Definitions */
#define TPI_TRIGGER_TRIGGER_Pos 0U /*!< TPI TRIGGER: TRIGGER Position */
#define TPI_TRIGGER_TRIGGER_Msk (0x1UL /*<< TPI_TRIGGER_TRIGGER_Pos*/) /*!< TPI TRIGGER: TRIGGER Mask */
/* TPI Integration ETM Data Register Definitions (FIFO0) */
#define TPI_FIFO0_ITM_ATVALID_Pos 29U /*!< TPI FIFO0: ITM_ATVALID Position */
#define TPI_FIFO0_ITM_ATVALID_Msk (0x1UL << TPI_FIFO0_ITM_ATVALID_Pos) /*!< TPI FIFO0: ITM_ATVALID Mask */
#define TPI_FIFO0_ITM_bytecount_Pos 27U /*!< TPI FIFO0: ITM_bytecount Position */
#define TPI_FIFO0_ITM_bytecount_Msk (0x3UL << TPI_FIFO0_ITM_bytecount_Pos) /*!< TPI FIFO0: ITM_bytecount Mask */
#define TPI_FIFO0_ETM_ATVALID_Pos 26U /*!< TPI FIFO0: ETM_ATVALID Position */
#define TPI_FIFO0_ETM_ATVALID_Msk (0x1UL << TPI_FIFO0_ETM_ATVALID_Pos) /*!< TPI FIFO0: ETM_ATVALID Mask */
#define TPI_FIFO0_ETM_bytecount_Pos 24U /*!< TPI FIFO0: ETM_bytecount Position */
#define TPI_FIFO0_ETM_bytecount_Msk (0x3UL << TPI_FIFO0_ETM_bytecount_Pos) /*!< TPI FIFO0: ETM_bytecount Mask */
#define TPI_FIFO0_ETM2_Pos 16U /*!< TPI FIFO0: ETM2 Position */
#define TPI_FIFO0_ETM2_Msk (0xFFUL << TPI_FIFO0_ETM2_Pos) /*!< TPI FIFO0: ETM2 Mask */
#define TPI_FIFO0_ETM1_Pos 8U /*!< TPI FIFO0: ETM1 Position */
#define TPI_FIFO0_ETM1_Msk (0xFFUL << TPI_FIFO0_ETM1_Pos) /*!< TPI FIFO0: ETM1 Mask */
#define TPI_FIFO0_ETM0_Pos 0U /*!< TPI FIFO0: ETM0 Position */
#define TPI_FIFO0_ETM0_Msk (0xFFUL /*<< TPI_FIFO0_ETM0_Pos*/) /*!< TPI FIFO0: ETM0 Mask */
/* TPI ITATBCTR2 Register Definitions */
#define TPI_ITATBCTR2_ATREADY2_Pos 0U /*!< TPI ITATBCTR2: ATREADY2 Position */
#define TPI_ITATBCTR2_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY2_Pos*/) /*!< TPI ITATBCTR2: ATREADY2 Mask */
#define TPI_ITATBCTR2_ATREADY1_Pos 0U /*!< TPI ITATBCTR2: ATREADY1 Position */
#define TPI_ITATBCTR2_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR2_ATREADY1_Pos*/) /*!< TPI ITATBCTR2: ATREADY1 Mask */
/* TPI Integration ITM Data Register Definitions (FIFO1) */
#define TPI_FIFO1_ITM_ATVALID_Pos 29U /*!< TPI FIFO1: ITM_ATVALID Position */
#define TPI_FIFO1_ITM_ATVALID_Msk (0x1UL << TPI_FIFO1_ITM_ATVALID_Pos) /*!< TPI FIFO1: ITM_ATVALID Mask */
#define TPI_FIFO1_ITM_bytecount_Pos 27U /*!< TPI FIFO1: ITM_bytecount Position */
#define TPI_FIFO1_ITM_bytecount_Msk (0x3UL << TPI_FIFO1_ITM_bytecount_Pos) /*!< TPI FIFO1: ITM_bytecount Mask */
#define TPI_FIFO1_ETM_ATVALID_Pos 26U /*!< TPI FIFO1: ETM_ATVALID Position */
#define TPI_FIFO1_ETM_ATVALID_Msk (0x1UL << TPI_FIFO1_ETM_ATVALID_Pos) /*!< TPI FIFO1: ETM_ATVALID Mask */
#define TPI_FIFO1_ETM_bytecount_Pos 24U /*!< TPI FIFO1: ETM_bytecount Position */
#define TPI_FIFO1_ETM_bytecount_Msk (0x3UL << TPI_FIFO1_ETM_bytecount_Pos) /*!< TPI FIFO1: ETM_bytecount Mask */
#define TPI_FIFO1_ITM2_Pos 16U /*!< TPI FIFO1: ITM2 Position */
#define TPI_FIFO1_ITM2_Msk (0xFFUL << TPI_FIFO1_ITM2_Pos) /*!< TPI FIFO1: ITM2 Mask */
#define TPI_FIFO1_ITM1_Pos 8U /*!< TPI FIFO1: ITM1 Position */
#define TPI_FIFO1_ITM1_Msk (0xFFUL << TPI_FIFO1_ITM1_Pos) /*!< TPI FIFO1: ITM1 Mask */
#define TPI_FIFO1_ITM0_Pos 0U /*!< TPI FIFO1: ITM0 Position */
#define TPI_FIFO1_ITM0_Msk (0xFFUL /*<< TPI_FIFO1_ITM0_Pos*/) /*!< TPI FIFO1: ITM0 Mask */
/* TPI ITATBCTR0 Register Definitions */
#define TPI_ITATBCTR0_ATREADY2_Pos 0U /*!< TPI ITATBCTR0: ATREADY2 Position */
#define TPI_ITATBCTR0_ATREADY2_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY2_Pos*/) /*!< TPI ITATBCTR0: ATREADY2 Mask */
#define TPI_ITATBCTR0_ATREADY1_Pos 0U /*!< TPI ITATBCTR0: ATREADY1 Position */
#define TPI_ITATBCTR0_ATREADY1_Msk (0x1UL /*<< TPI_ITATBCTR0_ATREADY1_Pos*/) /*!< TPI ITATBCTR0: ATREADY1 Mask */
/* TPI Integration Mode Control Register Definitions */
#define TPI_ITCTRL_Mode_Pos 0U /*!< TPI ITCTRL: Mode Position */
#define TPI_ITCTRL_Mode_Msk (0x3UL /*<< TPI_ITCTRL_Mode_Pos*/) /*!< TPI ITCTRL: Mode Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_MinBufSz_Pos 6U /*!< TPI DEVID: MinBufSz Position */
#define TPI_DEVID_MinBufSz_Msk (0x7UL << TPI_DEVID_MinBufSz_Pos) /*!< TPI DEVID: MinBufSz Mask */
#define TPI_DEVID_AsynClkIn_Pos 5U /*!< TPI DEVID: AsynClkIn Position */
#define TPI_DEVID_AsynClkIn_Msk (0x1UL << TPI_DEVID_AsynClkIn_Pos) /*!< TPI DEVID: AsynClkIn Mask */
#define TPI_DEVID_NrTraceInput_Pos 0U /*!< TPI DEVID: NrTraceInput Position */
#define TPI_DEVID_NrTraceInput_Msk (0x1FUL /*<< TPI_DEVID_NrTraceInput_Pos*/) /*!< TPI DEVID: NrTraceInput Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region RNRber Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RASR; /*!< Offset: 0x010 (R/W) MPU Region Attribute and Size Register */
__IOM uint32_t RBAR_A1; /*!< Offset: 0x014 (R/W) MPU Alias 1 Region Base Address Register */
__IOM uint32_t RASR_A1; /*!< Offset: 0x018 (R/W) MPU Alias 1 Region Attribute and Size Register */
__IOM uint32_t RBAR_A2; /*!< Offset: 0x01C (R/W) MPU Alias 2 Region Base Address Register */
__IOM uint32_t RASR_A2; /*!< Offset: 0x020 (R/W) MPU Alias 2 Region Attribute and Size Register */
__IOM uint32_t RBAR_A3; /*!< Offset: 0x024 (R/W) MPU Alias 3 Region Base Address Register */
__IOM uint32_t RASR_A3; /*!< Offset: 0x028 (R/W) MPU Alias 3 Region Attribute and Size Register */
} MPU_Type;
#define MPU_TYPE_RALIASES 4U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_ADDR_Pos 5U /*!< MPU RBAR: ADDR Position */
#define MPU_RBAR_ADDR_Msk (0x7FFFFFFUL << MPU_RBAR_ADDR_Pos) /*!< MPU RBAR: ADDR Mask */
#define MPU_RBAR_VALID_Pos 4U /*!< MPU RBAR: VALID Position */
#define MPU_RBAR_VALID_Msk (1UL << MPU_RBAR_VALID_Pos) /*!< MPU RBAR: VALID Mask */
#define MPU_RBAR_REGION_Pos 0U /*!< MPU RBAR: REGION Position */
#define MPU_RBAR_REGION_Msk (0xFUL /*<< MPU_RBAR_REGION_Pos*/) /*!< MPU RBAR: REGION Mask */
/* MPU Region Attribute and Size Register Definitions */
#define MPU_RASR_ATTRS_Pos 16U /*!< MPU RASR: MPU Region Attribute field Position */
#define MPU_RASR_ATTRS_Msk (0xFFFFUL << MPU_RASR_ATTRS_Pos) /*!< MPU RASR: MPU Region Attribute field Mask */
#define MPU_RASR_XN_Pos 28U /*!< MPU RASR: ATTRS.XN Position */
#define MPU_RASR_XN_Msk (1UL << MPU_RASR_XN_Pos) /*!< MPU RASR: ATTRS.XN Mask */
#define MPU_RASR_AP_Pos 24U /*!< MPU RASR: ATTRS.AP Position */
#define MPU_RASR_AP_Msk (0x7UL << MPU_RASR_AP_Pos) /*!< MPU RASR: ATTRS.AP Mask */
#define MPU_RASR_TEX_Pos 19U /*!< MPU RASR: ATTRS.TEX Position */
#define MPU_RASR_TEX_Msk (0x7UL << MPU_RASR_TEX_Pos) /*!< MPU RASR: ATTRS.TEX Mask */
#define MPU_RASR_S_Pos 18U /*!< MPU RASR: ATTRS.S Position */
#define MPU_RASR_S_Msk (1UL << MPU_RASR_S_Pos) /*!< MPU RASR: ATTRS.S Mask */
#define MPU_RASR_C_Pos 17U /*!< MPU RASR: ATTRS.C Position */
#define MPU_RASR_C_Msk (1UL << MPU_RASR_C_Pos) /*!< MPU RASR: ATTRS.C Mask */
#define MPU_RASR_B_Pos 16U /*!< MPU RASR: ATTRS.B Position */
#define MPU_RASR_B_Msk (1UL << MPU_RASR_B_Pos) /*!< MPU RASR: ATTRS.B Mask */
#define MPU_RASR_SRD_Pos 8U /*!< MPU RASR: Sub-Region Disable Position */
#define MPU_RASR_SRD_Msk (0xFFUL << MPU_RASR_SRD_Pos) /*!< MPU RASR: Sub-Region Disable Mask */
#define MPU_RASR_SIZE_Pos 1U /*!< MPU RASR: Region Size Field Position */
#define MPU_RASR_SIZE_Msk (0x1FUL << MPU_RASR_SIZE_Pos) /*!< MPU RASR: Region Size Field Mask */
#define MPU_RASR_ENABLE_Pos 0U /*!< MPU RASR: Region enable bit Position */
#define MPU_RASR_ENABLE_Msk (1UL /*<< MPU_RASR_ENABLE_Pos*/) /*!< MPU RASR: Region enable bit Disable Mask */
/*@} end of group CMSIS_MPU */
#endif
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_SNAPSTALL_Pos 5U /*!< CoreDebug DHCSR: C_SNAPSTALL Position */
#define CoreDebug_DHCSR_C_SNAPSTALL_Msk (1UL << CoreDebug_DHCSR_C_SNAPSTALL_Pos) /*!< CoreDebug DHCSR: C_SNAPSTALL Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register Definitions */
#define CoreDebug_DEMCR_TRCENA_Pos 24U /*!< CoreDebug DEMCR: TRCENA Position */
#define CoreDebug_DEMCR_TRCENA_Msk (1UL << CoreDebug_DEMCR_TRCENA_Pos) /*!< CoreDebug DEMCR: TRCENA Mask */
#define CoreDebug_DEMCR_MON_REQ_Pos 19U /*!< CoreDebug DEMCR: MON_REQ Position */
#define CoreDebug_DEMCR_MON_REQ_Msk (1UL << CoreDebug_DEMCR_MON_REQ_Pos) /*!< CoreDebug DEMCR: MON_REQ Mask */
#define CoreDebug_DEMCR_MON_STEP_Pos 18U /*!< CoreDebug DEMCR: MON_STEP Position */
#define CoreDebug_DEMCR_MON_STEP_Msk (1UL << CoreDebug_DEMCR_MON_STEP_Pos) /*!< CoreDebug DEMCR: MON_STEP Mask */
#define CoreDebug_DEMCR_MON_PEND_Pos 17U /*!< CoreDebug DEMCR: MON_PEND Position */
#define CoreDebug_DEMCR_MON_PEND_Msk (1UL << CoreDebug_DEMCR_MON_PEND_Pos) /*!< CoreDebug DEMCR: MON_PEND Mask */
#define CoreDebug_DEMCR_MON_EN_Pos 16U /*!< CoreDebug DEMCR: MON_EN Position */
#define CoreDebug_DEMCR_MON_EN_Msk (1UL << CoreDebug_DEMCR_MON_EN_Pos) /*!< CoreDebug DEMCR: MON_EN Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_INTERR_Pos 9U /*!< CoreDebug DEMCR: VC_INTERR Position */
#define CoreDebug_DEMCR_VC_INTERR_Msk (1UL << CoreDebug_DEMCR_VC_INTERR_Pos) /*!< CoreDebug DEMCR: VC_INTERR Mask */
#define CoreDebug_DEMCR_VC_BUSERR_Pos 8U /*!< CoreDebug DEMCR: VC_BUSERR Position */
#define CoreDebug_DEMCR_VC_BUSERR_Msk (1UL << CoreDebug_DEMCR_VC_BUSERR_Pos) /*!< CoreDebug DEMCR: VC_BUSERR Mask */
#define CoreDebug_DEMCR_VC_STATERR_Pos 7U /*!< CoreDebug DEMCR: VC_STATERR Position */
#define CoreDebug_DEMCR_VC_STATERR_Msk (1UL << CoreDebug_DEMCR_VC_STATERR_Pos) /*!< CoreDebug DEMCR: VC_STATERR Mask */
#define CoreDebug_DEMCR_VC_CHKERR_Pos 6U /*!< CoreDebug DEMCR: VC_CHKERR Position */
#define CoreDebug_DEMCR_VC_CHKERR_Msk (1UL << CoreDebug_DEMCR_VC_CHKERR_Pos) /*!< CoreDebug DEMCR: VC_CHKERR Mask */
#define CoreDebug_DEMCR_VC_NOCPERR_Pos 5U /*!< CoreDebug DEMCR: VC_NOCPERR Position */
#define CoreDebug_DEMCR_VC_NOCPERR_Msk (1UL << CoreDebug_DEMCR_VC_NOCPERR_Pos) /*!< CoreDebug DEMCR: VC_NOCPERR Mask */
#define CoreDebug_DEMCR_VC_MMERR_Pos 4U /*!< CoreDebug DEMCR: VC_MMERR Position */
#define CoreDebug_DEMCR_VC_MMERR_Msk (1UL << CoreDebug_DEMCR_VC_MMERR_Pos) /*!< CoreDebug DEMCR: VC_MMERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define ITM_BASE (0xE0000000UL) /*!< ITM Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define ITM ((ITM_Type *) ITM_BASE ) /*!< ITM configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Debug Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
/**
\brief Set Priority Grouping
\details Sets the priority grouping field using the required unlock sequence.
The parameter PriorityGroup is assigned to the field SCB->AIRCR [10:8] PRIGROUP field.
Only values from 0..7 are used.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Priority grouping field.
*/
__STATIC_INLINE void __NVIC_SetPriorityGrouping(uint32_t PriorityGroup)
{
uint32_t reg_value;
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
reg_value = SCB->AIRCR; /* read old register configuration */
reg_value &= ~((uint32_t)(SCB_AIRCR_VECTKEY_Msk | SCB_AIRCR_PRIGROUP_Msk)); /* clear bits to change */
reg_value = (reg_value |
((uint32_t)0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(PriorityGroupTmp << SCB_AIRCR_PRIGROUP_Pos) ); /* Insert write key and priority group */
SCB->AIRCR = reg_value;
}
/**
\brief Get Priority Grouping
\details Reads the priority grouping field from the NVIC Interrupt Controller.
\return Priority grouping field (SCB->AIRCR [10:8] PRIGROUP field).
*/
__STATIC_INLINE uint32_t __NVIC_GetPriorityGrouping(void)
{
return ((uint32_t)((SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) >> SCB_AIRCR_PRIGROUP_Pos));
}
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[((uint32_t)IRQn)] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
else
{
SCB->SHP[(((uint32_t)IRQn) & 0xFUL)-4UL] = (uint8_t)((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL);
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return(((uint32_t)NVIC->IP[((uint32_t)IRQn)] >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return(((uint32_t)SCB->SHP[(((uint32_t)IRQn) & 0xFUL)-4UL] >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4)) = vector;
/* ARM Application Note 321 states that the M3 does not require the architectural barrier */
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t vectors = (uint32_t )SCB->VTOR;
return (uint32_t)(* (int *) (vectors + ((int32_t)IRQn + NVIC_USER_IRQ_OFFSET) * 4));
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = (uint32_t)((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
(SCB->AIRCR & SCB_AIRCR_PRIGROUP_Msk) |
SCB_AIRCR_SYSRESETREQ_Msk ); /* Keep priority group unchanged */
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv7.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
/* ##################################### Debug In/Output function ########################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_core_DebugFunctions ITM Functions
\brief Functions that access the ITM debug interface.
@{
*/
extern volatile int32_t ITM_RxBuffer; /*!< External variable to receive characters. */
#define ITM_RXBUFFER_EMPTY ((int32_t)0x5AA55AA5U) /*!< Value identifying \ref ITM_RxBuffer is ready for next character. */
/**
\brief ITM Send Character
\details Transmits a character via the ITM channel 0, and
\li Just returns when no debugger is connected that has booked the output.
\li Is blocking when a debugger is connected, but the previous character sent has not been transmitted.
\param [in] ch Character to transmit.
\returns Character to transmit.
*/
__STATIC_INLINE uint32_t ITM_SendChar (uint32_t ch)
{
if (((ITM->TCR & ITM_TCR_ITMENA_Msk) != 0UL) && /* ITM enabled */
((ITM->TER & 1UL ) != 0UL) ) /* ITM Port #0 enabled */
{
while (ITM->PORT[0U].u32 == 0UL)
{
__NOP();
}
ITM->PORT[0U].u8 = (uint8_t)ch;
}
return (ch);
}
/**
\brief ITM Receive Character
\details Inputs a character via the external variable \ref ITM_RxBuffer.
\return Received character.
\return -1 No character pending.
*/
__STATIC_INLINE int32_t ITM_ReceiveChar (void)
{
int32_t ch = -1; /* no character available */
if (ITM_RxBuffer != ITM_RXBUFFER_EMPTY)
{
ch = ITM_RxBuffer;
ITM_RxBuffer = ITM_RXBUFFER_EMPTY; /* ready for next character */
}
return (ch);
}
/**
\brief ITM Check Character
\details Checks whether a character is pending for reading in the variable \ref ITM_RxBuffer.
\return 0 No character available.
\return 1 Character available.
*/
__STATIC_INLINE int32_t ITM_CheckChar (void)
{
if (ITM_RxBuffer == ITM_RXBUFFER_EMPTY)
{
return (0); /* no character available */
}
else
{
return (1); /* character available */
}
}
/*@} end of CMSIS_core_DebugFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_CM3_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 109,420 | C | 55.460784 | 178 | 0.531749 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/cmsis_armclang_ltm.h | /**************************************************************************//**
* @file cmsis_armclang_ltm.h
* @brief CMSIS compiler armclang (Arm Compiler 6) header file
* @version V1.2.0
* @date 08. May 2019
******************************************************************************/
/*
* Copyright (c) 2018-2019 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*lint -esym(9058, IRQn)*/ /* disable MISRA 2012 Rule 2.4 for IRQn */
#ifndef __CMSIS_ARMCLANG_H
#define __CMSIS_ARMCLANG_H
#pragma clang system_header /* treat file as system include file */
#ifndef __ARM_COMPAT_H
#include <arm_compat.h> /* Compatibility header for Arm Compiler 5 intrinsics */
#endif
/* CMSIS compiler specific defines */
#ifndef __ASM
#define __ASM __asm
#endif
#ifndef __INLINE
#define __INLINE __inline
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static __inline
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE __attribute__((always_inline)) static __inline
#endif
#ifndef __NO_RETURN
#define __NO_RETURN __attribute__((__noreturn__))
#endif
#ifndef __USED
#define __USED __attribute__((used))
#endif
#ifndef __WEAK
#define __WEAK __attribute__((weak))
#endif
#ifndef __PACKED
#define __PACKED __attribute__((packed, aligned(1)))
#endif
#ifndef __PACKED_STRUCT
#define __PACKED_STRUCT struct __attribute__((packed, aligned(1)))
#endif
#ifndef __PACKED_UNION
#define __PACKED_UNION union __attribute__((packed, aligned(1)))
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT32)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT32 */
struct __attribute__((packed)) T_UINT32 { uint32_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT32(x) (((struct T_UINT32 *)(x))->v)
#endif
#ifndef __UNALIGNED_UINT16_WRITE
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT16_WRITE)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT16_WRITE */
__PACKED_STRUCT T_UINT16_WRITE { uint16_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT16_WRITE(addr, val) (void)((((struct T_UINT16_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT16_READ
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT16_READ)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT16_READ */
__PACKED_STRUCT T_UINT16_READ { uint16_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT16_READ(addr) (((const struct T_UINT16_READ *)(const void *)(addr))->v)
#endif
#ifndef __UNALIGNED_UINT32_WRITE
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT32_WRITE)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT32_WRITE */
__PACKED_STRUCT T_UINT32_WRITE { uint32_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT32_WRITE(addr, val) (void)((((struct T_UINT32_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT32_READ
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpacked"
/*lint -esym(9058, T_UINT32_READ)*/ /* disable MISRA 2012 Rule 2.4 for T_UINT32_READ */
__PACKED_STRUCT T_UINT32_READ { uint32_t v; };
#pragma clang diagnostic pop
#define __UNALIGNED_UINT32_READ(addr) (((const struct T_UINT32_READ *)(const void *)(addr))->v)
#endif
#ifndef __ALIGNED
#define __ALIGNED(x) __attribute__((aligned(x)))
#endif
#ifndef __RESTRICT
#define __RESTRICT __restrict
#endif
#ifndef __COMPILER_BARRIER
#define __COMPILER_BARRIER() __ASM volatile("":::"memory")
#endif
/* ######################### Startup and Lowlevel Init ######################## */
#ifndef __PROGRAM_START
#define __PROGRAM_START __main
#endif
#ifndef __INITIAL_SP
#define __INITIAL_SP Image$$ARM_LIB_STACK$$ZI$$Limit
#endif
#ifndef __STACK_LIMIT
#define __STACK_LIMIT Image$$ARM_LIB_STACK$$ZI$$Base
#endif
#ifndef __VECTOR_TABLE
#define __VECTOR_TABLE __Vectors
#endif
#ifndef __VECTOR_TABLE_ATTRIBUTE
#define __VECTOR_TABLE_ATTRIBUTE __attribute((used, section("RESET")))
#endif
/* ########################### Core Function Access ########################### */
/** \ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_RegAccFunctions CMSIS Core Register Access Functions
@{
*/
/**
\brief Enable IRQ Interrupts
\details Enables IRQ interrupts by clearing the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
/* intrinsic void __enable_irq(); see arm_compat.h */
/**
\brief Disable IRQ Interrupts
\details Disables IRQ interrupts by setting the I-bit in the CPSR.
Can only be executed in Privileged modes.
*/
/* intrinsic void __disable_irq(); see arm_compat.h */
/**
\brief Get Control Register
\details Returns the content of the Control Register.
\return Control Register value
*/
__STATIC_FORCEINLINE uint32_t __get_CONTROL(void)
{
uint32_t result;
__ASM volatile ("MRS %0, control" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Control Register (non-secure)
\details Returns the content of the non-secure Control Register when in secure mode.
\return non-secure Control Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_CONTROL_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, control_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Control Register
\details Writes the given value to the Control Register.
\param [in] control Control Register value to set
*/
__STATIC_FORCEINLINE void __set_CONTROL(uint32_t control)
{
__ASM volatile ("MSR control, %0" : : "r" (control) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Control Register (non-secure)
\details Writes the given value to the non-secure Control Register when in secure state.
\param [in] control Control Register value to set
*/
__STATIC_FORCEINLINE void __TZ_set_CONTROL_NS(uint32_t control)
{
__ASM volatile ("MSR control_ns, %0" : : "r" (control) : "memory");
}
#endif
/**
\brief Get IPSR Register
\details Returns the content of the IPSR Register.
\return IPSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_IPSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, ipsr" : "=r" (result) );
return(result);
}
/**
\brief Get APSR Register
\details Returns the content of the APSR Register.
\return APSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_APSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, apsr" : "=r" (result) );
return(result);
}
/**
\brief Get xPSR Register
\details Returns the content of the xPSR Register.
\return xPSR Register value
*/
__STATIC_FORCEINLINE uint32_t __get_xPSR(void)
{
uint32_t result;
__ASM volatile ("MRS %0, xpsr" : "=r" (result) );
return(result);
}
/**
\brief Get Process Stack Pointer
\details Returns the current value of the Process Stack Pointer (PSP).
\return PSP Register value
*/
__STATIC_FORCEINLINE uint32_t __get_PSP(void)
{
uint32_t result;
__ASM volatile ("MRS %0, psp" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Process Stack Pointer (non-secure)
\details Returns the current value of the non-secure Process Stack Pointer (PSP) when in secure state.
\return PSP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PSP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, psp_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Process Stack Pointer
\details Assigns the given value to the Process Stack Pointer (PSP).
\param [in] topOfProcStack Process Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __set_PSP(uint32_t topOfProcStack)
{
__ASM volatile ("MSR psp, %0" : : "r" (topOfProcStack) : );
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Process Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Process Stack Pointer (PSP) when in secure state.
\param [in] topOfProcStack Process Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_PSP_NS(uint32_t topOfProcStack)
{
__ASM volatile ("MSR psp_ns, %0" : : "r" (topOfProcStack) : );
}
#endif
/**
\brief Get Main Stack Pointer
\details Returns the current value of the Main Stack Pointer (MSP).
\return MSP Register value
*/
__STATIC_FORCEINLINE uint32_t __get_MSP(void)
{
uint32_t result;
__ASM volatile ("MRS %0, msp" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Main Stack Pointer (non-secure)
\details Returns the current value of the non-secure Main Stack Pointer (MSP) when in secure state.
\return MSP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_MSP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, msp_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Main Stack Pointer
\details Assigns the given value to the Main Stack Pointer (MSP).
\param [in] topOfMainStack Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __set_MSP(uint32_t topOfMainStack)
{
__ASM volatile ("MSR msp, %0" : : "r" (topOfMainStack) : );
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Main Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Main Stack Pointer (MSP) when in secure state.
\param [in] topOfMainStack Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_MSP_NS(uint32_t topOfMainStack)
{
__ASM volatile ("MSR msp_ns, %0" : : "r" (topOfMainStack) : );
}
#endif
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Stack Pointer (non-secure)
\details Returns the current value of the non-secure Stack Pointer (SP) when in secure state.
\return SP Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_SP_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, sp_ns" : "=r" (result) );
return(result);
}
/**
\brief Set Stack Pointer (non-secure)
\details Assigns the given value to the non-secure Stack Pointer (SP) when in secure state.
\param [in] topOfStack Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_SP_NS(uint32_t topOfStack)
{
__ASM volatile ("MSR sp_ns, %0" : : "r" (topOfStack) : );
}
#endif
/**
\brief Get Priority Mask
\details Returns the current state of the priority mask bit from the Priority Mask Register.
\return Priority Mask value
*/
__STATIC_FORCEINLINE uint32_t __get_PRIMASK(void)
{
uint32_t result;
__ASM volatile ("MRS %0, primask" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Priority Mask (non-secure)
\details Returns the current state of the non-secure priority mask bit from the Priority Mask Register when in secure state.
\return Priority Mask value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PRIMASK_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, primask_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Priority Mask
\details Assigns the given value to the Priority Mask Register.
\param [in] priMask Priority Mask
*/
__STATIC_FORCEINLINE void __set_PRIMASK(uint32_t priMask)
{
__ASM volatile ("MSR primask, %0" : : "r" (priMask) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Priority Mask (non-secure)
\details Assigns the given value to the non-secure Priority Mask Register when in secure state.
\param [in] priMask Priority Mask
*/
__STATIC_FORCEINLINE void __TZ_set_PRIMASK_NS(uint32_t priMask)
{
__ASM volatile ("MSR primask_ns, %0" : : "r" (priMask) : "memory");
}
#endif
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) )
/**
\brief Enable FIQ
\details Enables FIQ interrupts by clearing the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
#define __enable_fault_irq __enable_fiq /* see arm_compat.h */
/**
\brief Disable FIQ
\details Disables FIQ interrupts by setting the F-bit in the CPSR.
Can only be executed in Privileged modes.
*/
#define __disable_fault_irq __disable_fiq /* see arm_compat.h */
/**
\brief Get Base Priority
\details Returns the current value of the Base Priority register.
\return Base Priority register value
*/
__STATIC_FORCEINLINE uint32_t __get_BASEPRI(void)
{
uint32_t result;
__ASM volatile ("MRS %0, basepri" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Base Priority (non-secure)
\details Returns the current value of the non-secure Base Priority register when in secure state.
\return Base Priority register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_BASEPRI_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, basepri_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Base Priority
\details Assigns the given value to the Base Priority register.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __set_BASEPRI(uint32_t basePri)
{
__ASM volatile ("MSR basepri, %0" : : "r" (basePri) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Base Priority (non-secure)
\details Assigns the given value to the non-secure Base Priority register when in secure state.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __TZ_set_BASEPRI_NS(uint32_t basePri)
{
__ASM volatile ("MSR basepri_ns, %0" : : "r" (basePri) : "memory");
}
#endif
/**
\brief Set Base Priority with condition
\details Assigns the given value to the Base Priority register only if BASEPRI masking is disabled,
or the new value increases the BASEPRI priority level.
\param [in] basePri Base Priority value to set
*/
__STATIC_FORCEINLINE void __set_BASEPRI_MAX(uint32_t basePri)
{
__ASM volatile ("MSR basepri_max, %0" : : "r" (basePri) : "memory");
}
/**
\brief Get Fault Mask
\details Returns the current value of the Fault Mask register.
\return Fault Mask register value
*/
__STATIC_FORCEINLINE uint32_t __get_FAULTMASK(void)
{
uint32_t result;
__ASM volatile ("MRS %0, faultmask" : "=r" (result) );
return(result);
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Fault Mask (non-secure)
\details Returns the current value of the non-secure Fault Mask register when in secure state.
\return Fault Mask register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_FAULTMASK_NS(void)
{
uint32_t result;
__ASM volatile ("MRS %0, faultmask_ns" : "=r" (result) );
return(result);
}
#endif
/**
\brief Set Fault Mask
\details Assigns the given value to the Fault Mask register.
\param [in] faultMask Fault Mask value to set
*/
__STATIC_FORCEINLINE void __set_FAULTMASK(uint32_t faultMask)
{
__ASM volatile ("MSR faultmask, %0" : : "r" (faultMask) : "memory");
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Fault Mask (non-secure)
\details Assigns the given value to the non-secure Fault Mask register when in secure state.
\param [in] faultMask Fault Mask value to set
*/
__STATIC_FORCEINLINE void __TZ_set_FAULTMASK_NS(uint32_t faultMask)
{
__ASM volatile ("MSR faultmask_ns, %0" : : "r" (faultMask) : "memory");
}
#endif
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief Get Process Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always in non-secure
mode.
\details Returns the current value of the Process Stack Pointer Limit (PSPLIM).
\return PSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __get_PSPLIM(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, psplim" : "=r" (result) );
return result;
#endif
}
#if (defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Process Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always in non-secure
mode.
\details Returns the current value of the non-secure Process Stack Pointer Limit (PSPLIM) when in secure state.
\return PSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_PSPLIM_NS(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, psplim_ns" : "=r" (result) );
return result;
#endif
}
#endif
/**
\brief Set Process Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored in non-secure
mode.
\details Assigns the given value to the Process Stack Pointer Limit (PSPLIM).
\param [in] ProcStackPtrLimit Process Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __set_PSPLIM(uint32_t ProcStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)ProcStackPtrLimit;
#else
__ASM volatile ("MSR psplim, %0" : : "r" (ProcStackPtrLimit));
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Process Stack Pointer (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored in non-secure
mode.
\details Assigns the given value to the non-secure Process Stack Pointer Limit (PSPLIM) when in secure state.
\param [in] ProcStackPtrLimit Process Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __TZ_set_PSPLIM_NS(uint32_t ProcStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure PSPLIM is RAZ/WI
(void)ProcStackPtrLimit;
#else
__ASM volatile ("MSR psplim_ns, %0\n" : : "r" (ProcStackPtrLimit));
#endif
}
#endif
/**
\brief Get Main Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always.
\details Returns the current value of the Main Stack Pointer Limit (MSPLIM).
\return MSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __get_MSPLIM(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, msplim" : "=r" (result) );
return result;
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Get Main Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence zero is returned always.
\details Returns the current value of the non-secure Main Stack Pointer Limit(MSPLIM) when in secure state.
\return MSPLIM Register value
*/
__STATIC_FORCEINLINE uint32_t __TZ_get_MSPLIM_NS(void)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
return 0U;
#else
uint32_t result;
__ASM volatile ("MRS %0, msplim_ns" : "=r" (result) );
return result;
#endif
}
#endif
/**
\brief Set Main Stack Pointer Limit
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored.
\details Assigns the given value to the Main Stack Pointer Limit (MSPLIM).
\param [in] MainStackPtrLimit Main Stack Pointer Limit value to set
*/
__STATIC_FORCEINLINE void __set_MSPLIM(uint32_t MainStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) && \
(!defined (__ARM_FEATURE_CMSE) || (__ARM_FEATURE_CMSE < 3)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
(void)MainStackPtrLimit;
#else
__ASM volatile ("MSR msplim, %0" : : "r" (MainStackPtrLimit));
#endif
}
#if (defined (__ARM_FEATURE_CMSE ) && (__ARM_FEATURE_CMSE == 3))
/**
\brief Set Main Stack Pointer Limit (non-secure)
Devices without ARMv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
Stack Pointer Limit register hence the write is silently ignored.
\details Assigns the given value to the non-secure Main Stack Pointer Limit (MSPLIM) when in secure state.
\param [in] MainStackPtrLimit Main Stack Pointer value to set
*/
__STATIC_FORCEINLINE void __TZ_set_MSPLIM_NS(uint32_t MainStackPtrLimit)
{
#if (!(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)))
// without main extensions, the non-secure MSPLIM is RAZ/WI
(void)MainStackPtrLimit;
#else
__ASM volatile ("MSR msplim_ns, %0" : : "r" (MainStackPtrLimit));
#endif
}
#endif
#endif /* ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
/**
\brief Get FPSCR
\details Returns the current value of the Floating Point Status/Control register.
\return Floating Point Status/Control register value
*/
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
#define __get_FPSCR (uint32_t)__builtin_arm_get_fpscr
#else
#define __get_FPSCR() ((uint32_t)0U)
#endif
/**
\brief Set FPSCR
\details Assigns the given value to the Floating Point Status/Control register.
\param [in] fpscr Floating Point Status/Control value to set
*/
#if ((defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U)) && \
(defined (__FPU_USED ) && (__FPU_USED == 1U)) )
#define __set_FPSCR __builtin_arm_set_fpscr
#else
#define __set_FPSCR(x) ((void)(x))
#endif
/*@} end of CMSIS_Core_RegAccFunctions */
/* ########################## Core Instruction Access ######################### */
/** \defgroup CMSIS_Core_InstructionInterface CMSIS Core Instruction Interface
Access to dedicated instructions
@{
*/
/* Define macros for porting to both thumb1 and thumb2.
* For thumb1, use low register (r0-r7), specified by constraint "l"
* Otherwise, use general registers, specified by constraint "r" */
#if defined (__thumb__) && !defined (__thumb2__)
#define __CMSIS_GCC_OUT_REG(r) "=l" (r)
#define __CMSIS_GCC_USE_REG(r) "l" (r)
#else
#define __CMSIS_GCC_OUT_REG(r) "=r" (r)
#define __CMSIS_GCC_USE_REG(r) "r" (r)
#endif
/**
\brief No Operation
\details No Operation does nothing. This instruction can be used for code alignment purposes.
*/
#define __NOP __builtin_arm_nop
/**
\brief Wait For Interrupt
\details Wait For Interrupt is a hint instruction that suspends execution until one of a number of events occurs.
*/
#define __WFI __builtin_arm_wfi
/**
\brief Wait For Event
\details Wait For Event is a hint instruction that permits the processor to enter
a low-power state until one of a number of events occurs.
*/
#define __WFE __builtin_arm_wfe
/**
\brief Send Event
\details Send Event is a hint instruction. It causes an event to be signaled to the CPU.
*/
#define __SEV __builtin_arm_sev
/**
\brief Instruction Synchronization Barrier
\details Instruction Synchronization Barrier flushes the pipeline in the processor,
so that all instructions following the ISB are fetched from cache or memory,
after the instruction has been completed.
*/
#define __ISB() __builtin_arm_isb(0xF)
/**
\brief Data Synchronization Barrier
\details Acts as a special kind of Data Memory Barrier.
It completes when all explicit memory accesses before this instruction complete.
*/
#define __DSB() __builtin_arm_dsb(0xF)
/**
\brief Data Memory Barrier
\details Ensures the apparent order of the explicit memory operations before
and after the instruction, without ensuring their completion.
*/
#define __DMB() __builtin_arm_dmb(0xF)
/**
\brief Reverse byte order (32 bit)
\details Reverses the byte order in unsigned integer value. For example, 0x12345678 becomes 0x78563412.
\param [in] value Value to reverse
\return Reversed value
*/
#define __REV(value) __builtin_bswap32(value)
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order within each halfword of a word. For example, 0x12345678 becomes 0x34127856.
\param [in] value Value to reverse
\return Reversed value
*/
#define __REV16(value) __ROR(__REV(value), 16)
/**
\brief Reverse byte order (16 bit)
\details Reverses the byte order in a 16-bit value and returns the signed 16-bit result. For example, 0x0080 becomes 0x8000.
\param [in] value Value to reverse
\return Reversed value
*/
#define __REVSH(value) (int16_t)__builtin_bswap16(value)
/**
\brief Rotate Right in unsigned value (32 bit)
\details Rotate Right (immediate) provides the value of the contents of a register rotated by a variable number of bits.
\param [in] op1 Value to rotate
\param [in] op2 Number of Bits to rotate
\return Rotated value
*/
__STATIC_FORCEINLINE uint32_t __ROR(uint32_t op1, uint32_t op2)
{
op2 %= 32U;
if (op2 == 0U)
{
return op1;
}
return (op1 >> op2) | (op1 << (32U - op2));
}
/**
\brief Breakpoint
\details Causes the processor to enter Debug state.
Debug tools can use this to investigate system state when the instruction at a particular address is reached.
\param [in] value is ignored by the processor.
If required, a debugger can use it to store additional information about the breakpoint.
*/
#define __BKPT(value) __ASM volatile ("bkpt "#value)
/**
\brief Reverse bit order of value
\details Reverses the bit order of the given value.
\param [in] value Value to reverse
\return Reversed value
*/
#define __RBIT __builtin_arm_rbit
/**
\brief Count leading zeros
\details Counts the number of leading zeros of a data value.
\param [in] value Value to count the leading zeros
\return number of leading zeros in value
*/
__STATIC_FORCEINLINE uint8_t __CLZ(uint32_t value)
{
/* Even though __builtin_clz produces a CLZ instruction on ARM, formally
__builtin_clz(0) is undefined behaviour, so handle this case specially.
This guarantees ARM-compatible results if happening to compile on a non-ARM
target, and ensures the compiler doesn't decide to activate any
optimisations using the logic "value was passed to __builtin_clz, so it
is non-zero".
ARM Compiler 6.10 and possibly earlier will optimise this test away, leaving a
single CLZ instruction.
*/
if (value == 0U)
{
return 32U;
}
return __builtin_clz(value);
}
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief LDR Exclusive (8 bit)
\details Executes a exclusive LDR instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
#define __LDREXB (uint8_t)__builtin_arm_ldrex
/**
\brief LDR Exclusive (16 bit)
\details Executes a exclusive LDR instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
#define __LDREXH (uint16_t)__builtin_arm_ldrex
/**
\brief LDR Exclusive (32 bit)
\details Executes a exclusive LDR instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
#define __LDREXW (uint32_t)__builtin_arm_ldrex
/**
\brief STR Exclusive (8 bit)
\details Executes a exclusive STR instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STREXB (uint32_t)__builtin_arm_strex
/**
\brief STR Exclusive (16 bit)
\details Executes a exclusive STR instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STREXH (uint32_t)__builtin_arm_strex
/**
\brief STR Exclusive (32 bit)
\details Executes a exclusive STR instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STREXW (uint32_t)__builtin_arm_strex
/**
\brief Remove the exclusive lock
\details Removes the exclusive lock which is created by LDREX.
*/
#define __CLREX __builtin_arm_clrex
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
#if ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) )
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (1..32)
\return Saturated value
*/
#define __SSAT __builtin_arm_ssat
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (0..31)
\return Saturated value
*/
#define __USAT __builtin_arm_usat
/**
\brief Rotate Right with Extend (32 bit)
\details Moves each bit of a bitstring right by one bit.
The carry input is shifted in at the left end of the bitstring.
\param [in] value Value to rotate
\return Rotated value
*/
__STATIC_FORCEINLINE uint32_t __RRX(uint32_t value)
{
uint32_t result;
__ASM volatile ("rrx %0, %1" : __CMSIS_GCC_OUT_REG (result) : __CMSIS_GCC_USE_REG (value) );
return(result);
}
/**
\brief LDRT Unprivileged (8 bit)
\details Executes a Unprivileged LDRT instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDRBT(volatile uint8_t *ptr)
{
uint32_t result;
__ASM volatile ("ldrbt %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint8_t) result); /* Add explicit type cast here */
}
/**
\brief LDRT Unprivileged (16 bit)
\details Executes a Unprivileged LDRT instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDRHT(volatile uint16_t *ptr)
{
uint32_t result;
__ASM volatile ("ldrht %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint16_t) result); /* Add explicit type cast here */
}
/**
\brief LDRT Unprivileged (32 bit)
\details Executes a Unprivileged LDRT instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDRT(volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("ldrt %0, %1" : "=r" (result) : "Q" (*ptr) );
return(result);
}
/**
\brief STRT Unprivileged (8 bit)
\details Executes a Unprivileged STRT instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRBT(uint8_t value, volatile uint8_t *ptr)
{
__ASM volatile ("strbt %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief STRT Unprivileged (16 bit)
\details Executes a Unprivileged STRT instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRHT(uint16_t value, volatile uint16_t *ptr)
{
__ASM volatile ("strht %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief STRT Unprivileged (32 bit)
\details Executes a Unprivileged STRT instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STRT(uint32_t value, volatile uint32_t *ptr)
{
__ASM volatile ("strt %1, %0" : "=Q" (*ptr) : "r" (value) );
}
#else /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
/**
\brief Signed Saturate
\details Saturates a signed value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (1..32)
\return Saturated value
*/
__STATIC_FORCEINLINE int32_t __SSAT(int32_t val, uint32_t sat)
{
if ((sat >= 1U) && (sat <= 32U))
{
const int32_t max = (int32_t)((1U << (sat - 1U)) - 1U);
const int32_t min = -1 - max ;
if (val > max)
{
return max;
}
else if (val < min)
{
return min;
}
}
return val;
}
/**
\brief Unsigned Saturate
\details Saturates an unsigned value.
\param [in] value Value to be saturated
\param [in] sat Bit position to saturate to (0..31)
\return Saturated value
*/
__STATIC_FORCEINLINE uint32_t __USAT(int32_t val, uint32_t sat)
{
if (sat <= 31U)
{
const uint32_t max = ((1U << sat) - 1U);
if (val > (int32_t)max)
{
return max;
}
else if (val < 0)
{
return 0U;
}
}
return (uint32_t)val;
}
#endif /* ((defined (__ARM_ARCH_7M__ ) && (__ARM_ARCH_7M__ == 1)) || \
(defined (__ARM_ARCH_7EM__ ) && (__ARM_ARCH_7EM__ == 1)) || \
(defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) ) */
#if ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) )
/**
\brief Load-Acquire (8 bit)
\details Executes a LDAB instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
__STATIC_FORCEINLINE uint8_t __LDAB(volatile uint8_t *ptr)
{
uint32_t result;
__ASM volatile ("ldab %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint8_t) result);
}
/**
\brief Load-Acquire (16 bit)
\details Executes a LDAH instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
__STATIC_FORCEINLINE uint16_t __LDAH(volatile uint16_t *ptr)
{
uint32_t result;
__ASM volatile ("ldah %0, %1" : "=r" (result) : "Q" (*ptr) );
return ((uint16_t) result);
}
/**
\brief Load-Acquire (32 bit)
\details Executes a LDA instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
__STATIC_FORCEINLINE uint32_t __LDA(volatile uint32_t *ptr)
{
uint32_t result;
__ASM volatile ("lda %0, %1" : "=r" (result) : "Q" (*ptr) );
return(result);
}
/**
\brief Store-Release (8 bit)
\details Executes a STLB instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STLB(uint8_t value, volatile uint8_t *ptr)
{
__ASM volatile ("stlb %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Store-Release (16 bit)
\details Executes a STLH instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STLH(uint16_t value, volatile uint16_t *ptr)
{
__ASM volatile ("stlh %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Store-Release (32 bit)
\details Executes a STL instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
*/
__STATIC_FORCEINLINE void __STL(uint32_t value, volatile uint32_t *ptr)
{
__ASM volatile ("stl %1, %0" : "=Q" (*ptr) : "r" ((uint32_t)value) );
}
/**
\brief Load-Acquire Exclusive (8 bit)
\details Executes a LDAB exclusive instruction for 8 bit value.
\param [in] ptr Pointer to data
\return value of type uint8_t at (*ptr)
*/
#define __LDAEXB (uint8_t)__builtin_arm_ldaex
/**
\brief Load-Acquire Exclusive (16 bit)
\details Executes a LDAH exclusive instruction for 16 bit values.
\param [in] ptr Pointer to data
\return value of type uint16_t at (*ptr)
*/
#define __LDAEXH (uint16_t)__builtin_arm_ldaex
/**
\brief Load-Acquire Exclusive (32 bit)
\details Executes a LDA exclusive instruction for 32 bit values.
\param [in] ptr Pointer to data
\return value of type uint32_t at (*ptr)
*/
#define __LDAEX (uint32_t)__builtin_arm_ldaex
/**
\brief Store-Release Exclusive (8 bit)
\details Executes a STLB exclusive instruction for 8 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STLEXB (uint32_t)__builtin_arm_stlex
/**
\brief Store-Release Exclusive (16 bit)
\details Executes a STLH exclusive instruction for 16 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STLEXH (uint32_t)__builtin_arm_stlex
/**
\brief Store-Release Exclusive (32 bit)
\details Executes a STL exclusive instruction for 32 bit values.
\param [in] value Value to store
\param [in] ptr Pointer to location
\return 0 Function succeeded
\return 1 Function failed
*/
#define __STLEX (uint32_t)__builtin_arm_stlex
#endif /* ((defined (__ARM_ARCH_8M_MAIN__ ) && (__ARM_ARCH_8M_MAIN__ == 1)) || \
(defined (__ARM_ARCH_8M_BASE__ ) && (__ARM_ARCH_8M_BASE__ == 1)) ) */
/*@}*/ /* end of group CMSIS_Core_InstructionInterface */
/* ################### Compiler specific Intrinsics ########################### */
/** \defgroup CMSIS_SIMD_intrinsics CMSIS SIMD Intrinsics
Access to dedicated SIMD instructions
@{
*/
#if (defined (__ARM_FEATURE_DSP) && (__ARM_FEATURE_DSP == 1))
__STATIC_FORCEINLINE uint32_t __SADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHADD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhadd8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("ssub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHSUB8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhsub8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHADD16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhadd16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("ssub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHSUB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhsub16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHASX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhasx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("ssax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __QSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("qsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SHSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("shsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UQSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uqsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __UHSAX(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uhsax %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USAD8(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("usad8 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __USADA8(uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("usada8 %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
#define __SSAT16(ARG1,ARG2) \
({ \
int32_t __RES, __ARG1 = (ARG1); \
__ASM ("ssat16 %0, %1, %2" : "=r" (__RES) : "I" (ARG2), "r" (__ARG1) ); \
__RES; \
})
#define __USAT16(ARG1,ARG2) \
({ \
uint32_t __RES, __ARG1 = (ARG1); \
__ASM ("usat16 %0, %1, %2" : "=r" (__RES) : "I" (ARG2), "r" (__ARG1) ); \
__RES; \
})
__STATIC_FORCEINLINE uint32_t __UXTB16(uint32_t op1)
{
uint32_t result;
__ASM volatile ("uxtb16 %0, %1" : "=r" (result) : "r" (op1));
return(result);
}
__STATIC_FORCEINLINE uint32_t __UXTAB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("uxtab16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SXTB16(uint32_t op1)
{
uint32_t result;
__ASM volatile ("sxtb16 %0, %1" : "=r" (result) : "r" (op1));
return(result);
}
__STATIC_FORCEINLINE uint32_t __SXTAB16(uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sxtab16 %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMUAD (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smuad %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMUADX (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smuadx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLAD (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smlad %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLADX (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smladx %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint64_t __SMLALD (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlald %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlald %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint64_t __SMLALDX (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlaldx %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlaldx %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint32_t __SMUSD (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smusd %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMUSDX (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("smusdx %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLSD (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smlsd %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint32_t __SMLSDX (uint32_t op1, uint32_t op2, uint32_t op3)
{
uint32_t result;
__ASM volatile ("smlsdx %0, %1, %2, %3" : "=r" (result) : "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
__STATIC_FORCEINLINE uint64_t __SMLSLD (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlsld %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlsld %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint64_t __SMLSLDX (uint32_t op1, uint32_t op2, uint64_t acc)
{
union llreg_u{
uint32_t w32[2];
uint64_t w64;
} llr;
llr.w64 = acc;
#ifndef __ARMEB__ /* Little endian */
__ASM volatile ("smlsldx %0, %1, %2, %3" : "=r" (llr.w32[0]), "=r" (llr.w32[1]): "r" (op1), "r" (op2) , "0" (llr.w32[0]), "1" (llr.w32[1]) );
#else /* Big endian */
__ASM volatile ("smlsldx %0, %1, %2, %3" : "=r" (llr.w32[1]), "=r" (llr.w32[0]): "r" (op1), "r" (op2) , "0" (llr.w32[1]), "1" (llr.w32[0]) );
#endif
return(llr.w64);
}
__STATIC_FORCEINLINE uint32_t __SEL (uint32_t op1, uint32_t op2)
{
uint32_t result;
__ASM volatile ("sel %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE int32_t __QADD( int32_t op1, int32_t op2)
{
int32_t result;
__ASM volatile ("qadd %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
__STATIC_FORCEINLINE int32_t __QSUB( int32_t op1, int32_t op2)
{
int32_t result;
__ASM volatile ("qsub %0, %1, %2" : "=r" (result) : "r" (op1), "r" (op2) );
return(result);
}
#define __PKHBT(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0x0000FFFFUL) | \
((((uint32_t)(ARG2)) << (ARG3)) & 0xFFFF0000UL) )
#define __PKHTB(ARG1,ARG2,ARG3) ( ((((uint32_t)(ARG1)) ) & 0xFFFF0000UL) | \
((((uint32_t)(ARG2)) >> (ARG3)) & 0x0000FFFFUL) )
__STATIC_FORCEINLINE int32_t __SMMLA (int32_t op1, int32_t op2, int32_t op3)
{
int32_t result;
__ASM volatile ("smmla %0, %1, %2, %3" : "=r" (result): "r" (op1), "r" (op2), "r" (op3) );
return(result);
}
#endif /* (__ARM_FEATURE_DSP == 1) */
/*@} end of group CMSIS_SIMD_intrinsics */
#endif /* __CMSIS_ARMCLANG_H */
| 55,224 | C | 28.188689 | 143 | 0.606312 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_sc000.h | /**************************************************************************//**
* @file core_sc000.h
* @brief CMSIS SC000 Core Peripheral Access Layer Header File
* @version V5.0.6
* @date 12. November 2018
******************************************************************************/
/*
* Copyright (c) 2009-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_SC000_H_GENERIC
#define __CORE_SC000_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup SC000
@{
*/
#include "cmsis_version.h"
/* CMSIS SC000 definitions */
#define __SC000_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __SC000_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __SC000_CMSIS_VERSION ((__SC000_CMSIS_VERSION_MAIN << 16U) | \
__SC000_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_SC (000U) /*!< Cortex secure core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_SC000_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_SC000_H_DEPENDANT
#define __CORE_SC000_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __SC000_REV
#define __SC000_REV 0x0000U
#warning "__SC000_REV not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 2U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group SC000 */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core MPU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:28; /*!< bit: 0..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:15; /*!< bit: 9..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t _reserved1:3; /*!< bit: 25..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t _reserved0:1; /*!< bit: 0 Reserved */
uint32_t SPSEL:1; /*!< bit: 1 Stack to be used */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[1U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[31U];
__IOM uint32_t ICER[1U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[31U];
__IOM uint32_t ISPR[1U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[31U];
__IOM uint32_t ICPR[1U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[31U];
uint32_t RESERVED4[64U];
__IOM uint32_t IP[8U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register */
} NVIC_Type;
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
uint32_t RESERVED0[1U];
__IOM uint32_t SHP[2U]; /*!< Offset: 0x01C (R/W) System Handlers Priority Registers. [0] is RESERVED */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
uint32_t RESERVED1[154U];
__IOM uint32_t SFCR; /*!< Offset: 0x290 (R/W) Security Features Control Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_NMIPENDSET_Pos 31U /*!< SCB ICSR: NMIPENDSET Position */
#define SCB_ICSR_NMIPENDSET_Msk (1UL << SCB_ICSR_NMIPENDSET_Pos) /*!< SCB ICSR: NMIPENDSET Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_STKALIGN_Pos 9U /*!< SCB CCR: STKALIGN Position */
#define SCB_CCR_STKALIGN_Msk (1UL << SCB_CCR_STKALIGN_Pos) /*!< SCB CCR: STKALIGN Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCnSCB System Controls not in SCB (SCnSCB)
\brief Type definitions for the System Control and ID Register not in the SCB
@{
*/
/**
\brief Structure type to access the System Control and ID Register not in the SCB.
*/
typedef struct
{
uint32_t RESERVED0[2U];
__IOM uint32_t ACTLR; /*!< Offset: 0x008 (R/W) Auxiliary Control Register */
} SCnSCB_Type;
/* Auxiliary Control Register Definitions */
#define SCnSCB_ACTLR_DISMCYCINT_Pos 0U /*!< ACTLR: DISMCYCINT Position */
#define SCnSCB_ACTLR_DISMCYCINT_Msk (1UL /*<< SCnSCB_ACTLR_DISMCYCINT_Pos*/) /*!< ACTLR: DISMCYCINT Mask */
/*@} end of group CMSIS_SCnotSCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region RNRber Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RASR; /*!< Offset: 0x010 (R/W) MPU Region Attribute and Size Register */
} MPU_Type;
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_ADDR_Pos 8U /*!< MPU RBAR: ADDR Position */
#define MPU_RBAR_ADDR_Msk (0xFFFFFFUL << MPU_RBAR_ADDR_Pos) /*!< MPU RBAR: ADDR Mask */
#define MPU_RBAR_VALID_Pos 4U /*!< MPU RBAR: VALID Position */
#define MPU_RBAR_VALID_Msk (1UL << MPU_RBAR_VALID_Pos) /*!< MPU RBAR: VALID Mask */
#define MPU_RBAR_REGION_Pos 0U /*!< MPU RBAR: REGION Position */
#define MPU_RBAR_REGION_Msk (0xFUL /*<< MPU_RBAR_REGION_Pos*/) /*!< MPU RBAR: REGION Mask */
/* MPU Region Attribute and Size Register Definitions */
#define MPU_RASR_ATTRS_Pos 16U /*!< MPU RASR: MPU Region Attribute field Position */
#define MPU_RASR_ATTRS_Msk (0xFFFFUL << MPU_RASR_ATTRS_Pos) /*!< MPU RASR: MPU Region Attribute field Mask */
#define MPU_RASR_XN_Pos 28U /*!< MPU RASR: ATTRS.XN Position */
#define MPU_RASR_XN_Msk (1UL << MPU_RASR_XN_Pos) /*!< MPU RASR: ATTRS.XN Mask */
#define MPU_RASR_AP_Pos 24U /*!< MPU RASR: ATTRS.AP Position */
#define MPU_RASR_AP_Msk (0x7UL << MPU_RASR_AP_Pos) /*!< MPU RASR: ATTRS.AP Mask */
#define MPU_RASR_TEX_Pos 19U /*!< MPU RASR: ATTRS.TEX Position */
#define MPU_RASR_TEX_Msk (0x7UL << MPU_RASR_TEX_Pos) /*!< MPU RASR: ATTRS.TEX Mask */
#define MPU_RASR_S_Pos 18U /*!< MPU RASR: ATTRS.S Position */
#define MPU_RASR_S_Msk (1UL << MPU_RASR_S_Pos) /*!< MPU RASR: ATTRS.S Mask */
#define MPU_RASR_C_Pos 17U /*!< MPU RASR: ATTRS.C Position */
#define MPU_RASR_C_Msk (1UL << MPU_RASR_C_Pos) /*!< MPU RASR: ATTRS.C Mask */
#define MPU_RASR_B_Pos 16U /*!< MPU RASR: ATTRS.B Position */
#define MPU_RASR_B_Msk (1UL << MPU_RASR_B_Pos) /*!< MPU RASR: ATTRS.B Mask */
#define MPU_RASR_SRD_Pos 8U /*!< MPU RASR: Sub-Region Disable Position */
#define MPU_RASR_SRD_Msk (0xFFUL << MPU_RASR_SRD_Pos) /*!< MPU RASR: Sub-Region Disable Mask */
#define MPU_RASR_SIZE_Pos 1U /*!< MPU RASR: Region Size Field Position */
#define MPU_RASR_SIZE_Msk (0x1FUL << MPU_RASR_SIZE_Pos) /*!< MPU RASR: Region Size Field Mask */
#define MPU_RASR_ENABLE_Pos 0U /*!< MPU RASR: Region enable bit Position */
#define MPU_RASR_ENABLE_Msk (1UL /*<< MPU_RASR_ENABLE_Pos*/) /*!< MPU RASR: Region enable bit Disable Mask */
/*@} end of group CMSIS_MPU */
#endif
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief SC000 Core Debug Registers (DCB registers, SHCSR, and DFSR) are only accessible over DAP and not via processor.
Therefore they are not covered by the SC000 header file.
@{
*/
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCnSCB ((SCnSCB_Type *) SCS_BASE ) /*!< System control Register not in SCB */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
/*#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping not available for SC000 */
/*#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping not available for SC000 */
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
/*#define NVIC_GetActive __NVIC_GetActive not available for SC000 */
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* The following EXC_RETURN values are saved the LR on exception entry */
#define EXC_RETURN_HANDLER (0xFFFFFFF1UL) /* return to Handler mode, uses MSP after return */
#define EXC_RETURN_THREAD_MSP (0xFFFFFFF9UL) /* return to Thread mode, uses MSP after return */
#define EXC_RETURN_THREAD_PSP (0xFFFFFFFDUL) /* return to Thread mode, uses PSP after return */
/* Interrupt Priorities are WORD accessible only under Armv6-M */
/* The following MACROS handle generation of the register offset and byte masks */
#define _BIT_SHIFT(IRQn) ( ((((uint32_t)(int32_t)(IRQn)) ) & 0x03UL) * 8UL)
#define _SHP_IDX(IRQn) ( (((((uint32_t)(int32_t)(IRQn)) & 0x0FUL)-8UL) >> 2UL) )
#define _IP_IDX(IRQn) ( (((uint32_t)(int32_t)(IRQn)) >> 2UL) )
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[0U] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[0U] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IP[_IP_IDX(IRQn)] = ((uint32_t)(NVIC->IP[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB->SHP[_SHP_IDX(IRQn)] = ((uint32_t)(SCB->SHP[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IP[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB->SHP[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
/* ARM Application Note 321 states that the M0 and M0+ do not require the architectural barrier - assume SC000 is the same */
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
uint32_t *vectors = (uint32_t *)SCB->VTOR;
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = ((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
SCB_AIRCR_SYSRESETREQ_Msk);
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_SC000_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 46,407 | C | 44.231969 | 143 | 0.536816 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/core_armv8mbl.h | /**************************************************************************//**
* @file core_armv8mbl.h
* @brief CMSIS Armv8-M Baseline Core Peripheral Access Layer Header File
* @version V5.0.8
* @date 12. November 2018
******************************************************************************/
/*
* Copyright (c) 2009-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#if defined ( __ICCARM__ )
#pragma system_include /* treat file as system include file for MISRA check */
#elif defined (__clang__)
#pragma clang system_header /* treat file as system include file */
#endif
#ifndef __CORE_ARMV8MBL_H_GENERIC
#define __CORE_ARMV8MBL_H_GENERIC
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/**
\page CMSIS_MISRA_Exceptions MISRA-C:2004 Compliance Exceptions
CMSIS violates the following MISRA-C:2004 rules:
\li Required Rule 8.5, object/function definition in header file.<br>
Function definitions in header files are used to allow 'inlining'.
\li Required Rule 18.4, declaration of union type or object of union type: '{...}'.<br>
Unions are used for effective representation of core registers.
\li Advisory Rule 19.7, Function-like macro defined.<br>
Function-like macros are used to allow more efficient code.
*/
/*******************************************************************************
* CMSIS definitions
******************************************************************************/
/**
\ingroup Cortex_ARMv8MBL
@{
*/
#include "cmsis_version.h"
/* CMSIS definitions */
#define __ARMv8MBL_CMSIS_VERSION_MAIN (__CM_CMSIS_VERSION_MAIN) /*!< \deprecated [31:16] CMSIS HAL main version */
#define __ARMv8MBL_CMSIS_VERSION_SUB (__CM_CMSIS_VERSION_SUB) /*!< \deprecated [15:0] CMSIS HAL sub version */
#define __ARMv8MBL_CMSIS_VERSION ((__ARMv8MBL_CMSIS_VERSION_MAIN << 16U) | \
__ARMv8MBL_CMSIS_VERSION_SUB ) /*!< \deprecated CMSIS HAL version number */
#define __CORTEX_M ( 2U) /*!< Cortex-M Core */
/** __FPU_USED indicates whether an FPU is used or not.
This core does not support an FPU at all
*/
#define __FPU_USED 0U
#if defined ( __CC_ARM )
#if defined __TARGET_FPU_VFP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
#if defined __ARM_FP
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __GNUC__ )
#if defined (__VFP_FP__) && !defined(__SOFTFP__)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __ICCARM__ )
#if defined __ARMVFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TI_ARM__ )
#if defined __TI_VFP_SUPPORT__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __TASKING__ )
#if defined __FPU_VFP__
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#elif defined ( __CSMC__ )
#if ( __CSMC__ & 0x400U)
#error "Compiler generates FPU instructions for a device without an FPU (check __FPU_PRESENT)"
#endif
#endif
#include "cmsis_compiler.h" /* CMSIS compiler specific defines */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_ARMV8MBL_H_GENERIC */
#ifndef __CMSIS_GENERIC
#ifndef __CORE_ARMV8MBL_H_DEPENDANT
#define __CORE_ARMV8MBL_H_DEPENDANT
#ifdef __cplusplus
extern "C" {
#endif
/* check device defines and use defaults */
#if defined __CHECK_DEVICE_DEFINES
#ifndef __ARMv8MBL_REV
#define __ARMv8MBL_REV 0x0000U
#warning "__ARMv8MBL_REV not defined in device header file; using default!"
#endif
#ifndef __FPU_PRESENT
#define __FPU_PRESENT 0U
#warning "__FPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MPU_PRESENT
#define __MPU_PRESENT 0U
#warning "__MPU_PRESENT not defined in device header file; using default!"
#endif
#ifndef __SAUREGION_PRESENT
#define __SAUREGION_PRESENT 0U
#warning "__SAUREGION_PRESENT not defined in device header file; using default!"
#endif
#ifndef __VTOR_PRESENT
#define __VTOR_PRESENT 0U
#warning "__VTOR_PRESENT not defined in device header file; using default!"
#endif
#ifndef __NVIC_PRIO_BITS
#define __NVIC_PRIO_BITS 2U
#warning "__NVIC_PRIO_BITS not defined in device header file; using default!"
#endif
#ifndef __Vendor_SysTickConfig
#define __Vendor_SysTickConfig 0U
#warning "__Vendor_SysTickConfig not defined in device header file; using default!"
#endif
#ifndef __ETM_PRESENT
#define __ETM_PRESENT 0U
#warning "__ETM_PRESENT not defined in device header file; using default!"
#endif
#ifndef __MTB_PRESENT
#define __MTB_PRESENT 0U
#warning "__MTB_PRESENT not defined in device header file; using default!"
#endif
#endif
/* IO definitions (access restrictions to peripheral registers) */
/**
\defgroup CMSIS_glob_defs CMSIS Global Defines
<strong>IO Type Qualifiers</strong> are used
\li to specify the access to peripheral variables.
\li for automatic generation of peripheral register debug information.
*/
#ifdef __cplusplus
#define __I volatile /*!< Defines 'read only' permissions */
#else
#define __I volatile const /*!< Defines 'read only' permissions */
#endif
#define __O volatile /*!< Defines 'write only' permissions */
#define __IO volatile /*!< Defines 'read / write' permissions */
/* following defines should be used for structure members */
#define __IM volatile const /*! Defines 'read only' structure member permissions */
#define __OM volatile /*! Defines 'write only' structure member permissions */
#define __IOM volatile /*! Defines 'read / write' structure member permissions */
/*@} end of group ARMv8MBL */
/*******************************************************************************
* Register Abstraction
Core Register contain:
- Core Register
- Core NVIC Register
- Core SCB Register
- Core SysTick Register
- Core Debug Register
- Core MPU Register
- Core SAU Register
******************************************************************************/
/**
\defgroup CMSIS_core_register Defines and Type Definitions
\brief Type definitions and defines for Cortex-M processor based devices.
*/
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CORE Status and Control Registers
\brief Core Register type definitions.
@{
*/
/**
\brief Union type to access the Application Program Status Register (APSR).
*/
typedef union
{
struct
{
uint32_t _reserved0:28; /*!< bit: 0..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} APSR_Type;
/* APSR Register Definitions */
#define APSR_N_Pos 31U /*!< APSR: N Position */
#define APSR_N_Msk (1UL << APSR_N_Pos) /*!< APSR: N Mask */
#define APSR_Z_Pos 30U /*!< APSR: Z Position */
#define APSR_Z_Msk (1UL << APSR_Z_Pos) /*!< APSR: Z Mask */
#define APSR_C_Pos 29U /*!< APSR: C Position */
#define APSR_C_Msk (1UL << APSR_C_Pos) /*!< APSR: C Mask */
#define APSR_V_Pos 28U /*!< APSR: V Position */
#define APSR_V_Msk (1UL << APSR_V_Pos) /*!< APSR: V Mask */
/**
\brief Union type to access the Interrupt Program Status Register (IPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:23; /*!< bit: 9..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} IPSR_Type;
/* IPSR Register Definitions */
#define IPSR_ISR_Pos 0U /*!< IPSR: ISR Position */
#define IPSR_ISR_Msk (0x1FFUL /*<< IPSR_ISR_Pos*/) /*!< IPSR: ISR Mask */
/**
\brief Union type to access the Special-Purpose Program Status Registers (xPSR).
*/
typedef union
{
struct
{
uint32_t ISR:9; /*!< bit: 0.. 8 Exception number */
uint32_t _reserved0:15; /*!< bit: 9..23 Reserved */
uint32_t T:1; /*!< bit: 24 Thumb bit (read 0) */
uint32_t _reserved1:3; /*!< bit: 25..27 Reserved */
uint32_t V:1; /*!< bit: 28 Overflow condition code flag */
uint32_t C:1; /*!< bit: 29 Carry condition code flag */
uint32_t Z:1; /*!< bit: 30 Zero condition code flag */
uint32_t N:1; /*!< bit: 31 Negative condition code flag */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} xPSR_Type;
/* xPSR Register Definitions */
#define xPSR_N_Pos 31U /*!< xPSR: N Position */
#define xPSR_N_Msk (1UL << xPSR_N_Pos) /*!< xPSR: N Mask */
#define xPSR_Z_Pos 30U /*!< xPSR: Z Position */
#define xPSR_Z_Msk (1UL << xPSR_Z_Pos) /*!< xPSR: Z Mask */
#define xPSR_C_Pos 29U /*!< xPSR: C Position */
#define xPSR_C_Msk (1UL << xPSR_C_Pos) /*!< xPSR: C Mask */
#define xPSR_V_Pos 28U /*!< xPSR: V Position */
#define xPSR_V_Msk (1UL << xPSR_V_Pos) /*!< xPSR: V Mask */
#define xPSR_T_Pos 24U /*!< xPSR: T Position */
#define xPSR_T_Msk (1UL << xPSR_T_Pos) /*!< xPSR: T Mask */
#define xPSR_ISR_Pos 0U /*!< xPSR: ISR Position */
#define xPSR_ISR_Msk (0x1FFUL /*<< xPSR_ISR_Pos*/) /*!< xPSR: ISR Mask */
/**
\brief Union type to access the Control Registers (CONTROL).
*/
typedef union
{
struct
{
uint32_t nPRIV:1; /*!< bit: 0 Execution privilege in Thread mode */
uint32_t SPSEL:1; /*!< bit: 1 Stack-pointer select */
uint32_t _reserved1:30; /*!< bit: 2..31 Reserved */
} b; /*!< Structure used for bit access */
uint32_t w; /*!< Type used for word access */
} CONTROL_Type;
/* CONTROL Register Definitions */
#define CONTROL_SPSEL_Pos 1U /*!< CONTROL: SPSEL Position */
#define CONTROL_SPSEL_Msk (1UL << CONTROL_SPSEL_Pos) /*!< CONTROL: SPSEL Mask */
#define CONTROL_nPRIV_Pos 0U /*!< CONTROL: nPRIV Position */
#define CONTROL_nPRIV_Msk (1UL /*<< CONTROL_nPRIV_Pos*/) /*!< CONTROL: nPRIV Mask */
/*@} end of group CMSIS_CORE */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_NVIC Nested Vectored Interrupt Controller (NVIC)
\brief Type definitions for the NVIC Registers
@{
*/
/**
\brief Structure type to access the Nested Vectored Interrupt Controller (NVIC).
*/
typedef struct
{
__IOM uint32_t ISER[16U]; /*!< Offset: 0x000 (R/W) Interrupt Set Enable Register */
uint32_t RESERVED0[16U];
__IOM uint32_t ICER[16U]; /*!< Offset: 0x080 (R/W) Interrupt Clear Enable Register */
uint32_t RSERVED1[16U];
__IOM uint32_t ISPR[16U]; /*!< Offset: 0x100 (R/W) Interrupt Set Pending Register */
uint32_t RESERVED2[16U];
__IOM uint32_t ICPR[16U]; /*!< Offset: 0x180 (R/W) Interrupt Clear Pending Register */
uint32_t RESERVED3[16U];
__IOM uint32_t IABR[16U]; /*!< Offset: 0x200 (R/W) Interrupt Active bit Register */
uint32_t RESERVED4[16U];
__IOM uint32_t ITNS[16U]; /*!< Offset: 0x280 (R/W) Interrupt Non-Secure State Register */
uint32_t RESERVED5[16U];
__IOM uint32_t IPR[124U]; /*!< Offset: 0x300 (R/W) Interrupt Priority Register */
} NVIC_Type;
/*@} end of group CMSIS_NVIC */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SCB System Control Block (SCB)
\brief Type definitions for the System Control Block Registers
@{
*/
/**
\brief Structure type to access the System Control Block (SCB).
*/
typedef struct
{
__IM uint32_t CPUID; /*!< Offset: 0x000 (R/ ) CPUID Base Register */
__IOM uint32_t ICSR; /*!< Offset: 0x004 (R/W) Interrupt Control and State Register */
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
__IOM uint32_t VTOR; /*!< Offset: 0x008 (R/W) Vector Table Offset Register */
#else
uint32_t RESERVED0;
#endif
__IOM uint32_t AIRCR; /*!< Offset: 0x00C (R/W) Application Interrupt and Reset Control Register */
__IOM uint32_t SCR; /*!< Offset: 0x010 (R/W) System Control Register */
__IOM uint32_t CCR; /*!< Offset: 0x014 (R/W) Configuration Control Register */
uint32_t RESERVED1;
__IOM uint32_t SHPR[2U]; /*!< Offset: 0x01C (R/W) System Handlers Priority Registers. [0] is RESERVED */
__IOM uint32_t SHCSR; /*!< Offset: 0x024 (R/W) System Handler Control and State Register */
} SCB_Type;
/* SCB CPUID Register Definitions */
#define SCB_CPUID_IMPLEMENTER_Pos 24U /*!< SCB CPUID: IMPLEMENTER Position */
#define SCB_CPUID_IMPLEMENTER_Msk (0xFFUL << SCB_CPUID_IMPLEMENTER_Pos) /*!< SCB CPUID: IMPLEMENTER Mask */
#define SCB_CPUID_VARIANT_Pos 20U /*!< SCB CPUID: VARIANT Position */
#define SCB_CPUID_VARIANT_Msk (0xFUL << SCB_CPUID_VARIANT_Pos) /*!< SCB CPUID: VARIANT Mask */
#define SCB_CPUID_ARCHITECTURE_Pos 16U /*!< SCB CPUID: ARCHITECTURE Position */
#define SCB_CPUID_ARCHITECTURE_Msk (0xFUL << SCB_CPUID_ARCHITECTURE_Pos) /*!< SCB CPUID: ARCHITECTURE Mask */
#define SCB_CPUID_PARTNO_Pos 4U /*!< SCB CPUID: PARTNO Position */
#define SCB_CPUID_PARTNO_Msk (0xFFFUL << SCB_CPUID_PARTNO_Pos) /*!< SCB CPUID: PARTNO Mask */
#define SCB_CPUID_REVISION_Pos 0U /*!< SCB CPUID: REVISION Position */
#define SCB_CPUID_REVISION_Msk (0xFUL /*<< SCB_CPUID_REVISION_Pos*/) /*!< SCB CPUID: REVISION Mask */
/* SCB Interrupt Control State Register Definitions */
#define SCB_ICSR_PENDNMISET_Pos 31U /*!< SCB ICSR: PENDNMISET Position */
#define SCB_ICSR_PENDNMISET_Msk (1UL << SCB_ICSR_PENDNMISET_Pos) /*!< SCB ICSR: PENDNMISET Mask */
#define SCB_ICSR_NMIPENDSET_Pos SCB_ICSR_PENDNMISET_Pos /*!< SCB ICSR: NMIPENDSET Position, backward compatibility */
#define SCB_ICSR_NMIPENDSET_Msk SCB_ICSR_PENDNMISET_Msk /*!< SCB ICSR: NMIPENDSET Mask, backward compatibility */
#define SCB_ICSR_PENDNMICLR_Pos 30U /*!< SCB ICSR: PENDNMICLR Position */
#define SCB_ICSR_PENDNMICLR_Msk (1UL << SCB_ICSR_PENDNMICLR_Pos) /*!< SCB ICSR: PENDNMICLR Mask */
#define SCB_ICSR_PENDSVSET_Pos 28U /*!< SCB ICSR: PENDSVSET Position */
#define SCB_ICSR_PENDSVSET_Msk (1UL << SCB_ICSR_PENDSVSET_Pos) /*!< SCB ICSR: PENDSVSET Mask */
#define SCB_ICSR_PENDSVCLR_Pos 27U /*!< SCB ICSR: PENDSVCLR Position */
#define SCB_ICSR_PENDSVCLR_Msk (1UL << SCB_ICSR_PENDSVCLR_Pos) /*!< SCB ICSR: PENDSVCLR Mask */
#define SCB_ICSR_PENDSTSET_Pos 26U /*!< SCB ICSR: PENDSTSET Position */
#define SCB_ICSR_PENDSTSET_Msk (1UL << SCB_ICSR_PENDSTSET_Pos) /*!< SCB ICSR: PENDSTSET Mask */
#define SCB_ICSR_PENDSTCLR_Pos 25U /*!< SCB ICSR: PENDSTCLR Position */
#define SCB_ICSR_PENDSTCLR_Msk (1UL << SCB_ICSR_PENDSTCLR_Pos) /*!< SCB ICSR: PENDSTCLR Mask */
#define SCB_ICSR_STTNS_Pos 24U /*!< SCB ICSR: STTNS Position (Security Extension) */
#define SCB_ICSR_STTNS_Msk (1UL << SCB_ICSR_STTNS_Pos) /*!< SCB ICSR: STTNS Mask (Security Extension) */
#define SCB_ICSR_ISRPREEMPT_Pos 23U /*!< SCB ICSR: ISRPREEMPT Position */
#define SCB_ICSR_ISRPREEMPT_Msk (1UL << SCB_ICSR_ISRPREEMPT_Pos) /*!< SCB ICSR: ISRPREEMPT Mask */
#define SCB_ICSR_ISRPENDING_Pos 22U /*!< SCB ICSR: ISRPENDING Position */
#define SCB_ICSR_ISRPENDING_Msk (1UL << SCB_ICSR_ISRPENDING_Pos) /*!< SCB ICSR: ISRPENDING Mask */
#define SCB_ICSR_VECTPENDING_Pos 12U /*!< SCB ICSR: VECTPENDING Position */
#define SCB_ICSR_VECTPENDING_Msk (0x1FFUL << SCB_ICSR_VECTPENDING_Pos) /*!< SCB ICSR: VECTPENDING Mask */
#define SCB_ICSR_RETTOBASE_Pos 11U /*!< SCB ICSR: RETTOBASE Position */
#define SCB_ICSR_RETTOBASE_Msk (1UL << SCB_ICSR_RETTOBASE_Pos) /*!< SCB ICSR: RETTOBASE Mask */
#define SCB_ICSR_VECTACTIVE_Pos 0U /*!< SCB ICSR: VECTACTIVE Position */
#define SCB_ICSR_VECTACTIVE_Msk (0x1FFUL /*<< SCB_ICSR_VECTACTIVE_Pos*/) /*!< SCB ICSR: VECTACTIVE Mask */
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
/* SCB Vector Table Offset Register Definitions */
#define SCB_VTOR_TBLOFF_Pos 7U /*!< SCB VTOR: TBLOFF Position */
#define SCB_VTOR_TBLOFF_Msk (0x1FFFFFFUL << SCB_VTOR_TBLOFF_Pos) /*!< SCB VTOR: TBLOFF Mask */
#endif
/* SCB Application Interrupt and Reset Control Register Definitions */
#define SCB_AIRCR_VECTKEY_Pos 16U /*!< SCB AIRCR: VECTKEY Position */
#define SCB_AIRCR_VECTKEY_Msk (0xFFFFUL << SCB_AIRCR_VECTKEY_Pos) /*!< SCB AIRCR: VECTKEY Mask */
#define SCB_AIRCR_VECTKEYSTAT_Pos 16U /*!< SCB AIRCR: VECTKEYSTAT Position */
#define SCB_AIRCR_VECTKEYSTAT_Msk (0xFFFFUL << SCB_AIRCR_VECTKEYSTAT_Pos) /*!< SCB AIRCR: VECTKEYSTAT Mask */
#define SCB_AIRCR_ENDIANESS_Pos 15U /*!< SCB AIRCR: ENDIANESS Position */
#define SCB_AIRCR_ENDIANESS_Msk (1UL << SCB_AIRCR_ENDIANESS_Pos) /*!< SCB AIRCR: ENDIANESS Mask */
#define SCB_AIRCR_PRIS_Pos 14U /*!< SCB AIRCR: PRIS Position */
#define SCB_AIRCR_PRIS_Msk (1UL << SCB_AIRCR_PRIS_Pos) /*!< SCB AIRCR: PRIS Mask */
#define SCB_AIRCR_BFHFNMINS_Pos 13U /*!< SCB AIRCR: BFHFNMINS Position */
#define SCB_AIRCR_BFHFNMINS_Msk (1UL << SCB_AIRCR_BFHFNMINS_Pos) /*!< SCB AIRCR: BFHFNMINS Mask */
#define SCB_AIRCR_SYSRESETREQS_Pos 3U /*!< SCB AIRCR: SYSRESETREQS Position */
#define SCB_AIRCR_SYSRESETREQS_Msk (1UL << SCB_AIRCR_SYSRESETREQS_Pos) /*!< SCB AIRCR: SYSRESETREQS Mask */
#define SCB_AIRCR_SYSRESETREQ_Pos 2U /*!< SCB AIRCR: SYSRESETREQ Position */
#define SCB_AIRCR_SYSRESETREQ_Msk (1UL << SCB_AIRCR_SYSRESETREQ_Pos) /*!< SCB AIRCR: SYSRESETREQ Mask */
#define SCB_AIRCR_VECTCLRACTIVE_Pos 1U /*!< SCB AIRCR: VECTCLRACTIVE Position */
#define SCB_AIRCR_VECTCLRACTIVE_Msk (1UL << SCB_AIRCR_VECTCLRACTIVE_Pos) /*!< SCB AIRCR: VECTCLRACTIVE Mask */
/* SCB System Control Register Definitions */
#define SCB_SCR_SEVONPEND_Pos 4U /*!< SCB SCR: SEVONPEND Position */
#define SCB_SCR_SEVONPEND_Msk (1UL << SCB_SCR_SEVONPEND_Pos) /*!< SCB SCR: SEVONPEND Mask */
#define SCB_SCR_SLEEPDEEPS_Pos 3U /*!< SCB SCR: SLEEPDEEPS Position */
#define SCB_SCR_SLEEPDEEPS_Msk (1UL << SCB_SCR_SLEEPDEEPS_Pos) /*!< SCB SCR: SLEEPDEEPS Mask */
#define SCB_SCR_SLEEPDEEP_Pos 2U /*!< SCB SCR: SLEEPDEEP Position */
#define SCB_SCR_SLEEPDEEP_Msk (1UL << SCB_SCR_SLEEPDEEP_Pos) /*!< SCB SCR: SLEEPDEEP Mask */
#define SCB_SCR_SLEEPONEXIT_Pos 1U /*!< SCB SCR: SLEEPONEXIT Position */
#define SCB_SCR_SLEEPONEXIT_Msk (1UL << SCB_SCR_SLEEPONEXIT_Pos) /*!< SCB SCR: SLEEPONEXIT Mask */
/* SCB Configuration Control Register Definitions */
#define SCB_CCR_BP_Pos 18U /*!< SCB CCR: BP Position */
#define SCB_CCR_BP_Msk (1UL << SCB_CCR_BP_Pos) /*!< SCB CCR: BP Mask */
#define SCB_CCR_IC_Pos 17U /*!< SCB CCR: IC Position */
#define SCB_CCR_IC_Msk (1UL << SCB_CCR_IC_Pos) /*!< SCB CCR: IC Mask */
#define SCB_CCR_DC_Pos 16U /*!< SCB CCR: DC Position */
#define SCB_CCR_DC_Msk (1UL << SCB_CCR_DC_Pos) /*!< SCB CCR: DC Mask */
#define SCB_CCR_STKOFHFNMIGN_Pos 10U /*!< SCB CCR: STKOFHFNMIGN Position */
#define SCB_CCR_STKOFHFNMIGN_Msk (1UL << SCB_CCR_STKOFHFNMIGN_Pos) /*!< SCB CCR: STKOFHFNMIGN Mask */
#define SCB_CCR_BFHFNMIGN_Pos 8U /*!< SCB CCR: BFHFNMIGN Position */
#define SCB_CCR_BFHFNMIGN_Msk (1UL << SCB_CCR_BFHFNMIGN_Pos) /*!< SCB CCR: BFHFNMIGN Mask */
#define SCB_CCR_DIV_0_TRP_Pos 4U /*!< SCB CCR: DIV_0_TRP Position */
#define SCB_CCR_DIV_0_TRP_Msk (1UL << SCB_CCR_DIV_0_TRP_Pos) /*!< SCB CCR: DIV_0_TRP Mask */
#define SCB_CCR_UNALIGN_TRP_Pos 3U /*!< SCB CCR: UNALIGN_TRP Position */
#define SCB_CCR_UNALIGN_TRP_Msk (1UL << SCB_CCR_UNALIGN_TRP_Pos) /*!< SCB CCR: UNALIGN_TRP Mask */
#define SCB_CCR_USERSETMPEND_Pos 1U /*!< SCB CCR: USERSETMPEND Position */
#define SCB_CCR_USERSETMPEND_Msk (1UL << SCB_CCR_USERSETMPEND_Pos) /*!< SCB CCR: USERSETMPEND Mask */
/* SCB System Handler Control and State Register Definitions */
#define SCB_SHCSR_HARDFAULTPENDED_Pos 21U /*!< SCB SHCSR: HARDFAULTPENDED Position */
#define SCB_SHCSR_HARDFAULTPENDED_Msk (1UL << SCB_SHCSR_HARDFAULTPENDED_Pos) /*!< SCB SHCSR: HARDFAULTPENDED Mask */
#define SCB_SHCSR_SVCALLPENDED_Pos 15U /*!< SCB SHCSR: SVCALLPENDED Position */
#define SCB_SHCSR_SVCALLPENDED_Msk (1UL << SCB_SHCSR_SVCALLPENDED_Pos) /*!< SCB SHCSR: SVCALLPENDED Mask */
#define SCB_SHCSR_SYSTICKACT_Pos 11U /*!< SCB SHCSR: SYSTICKACT Position */
#define SCB_SHCSR_SYSTICKACT_Msk (1UL << SCB_SHCSR_SYSTICKACT_Pos) /*!< SCB SHCSR: SYSTICKACT Mask */
#define SCB_SHCSR_PENDSVACT_Pos 10U /*!< SCB SHCSR: PENDSVACT Position */
#define SCB_SHCSR_PENDSVACT_Msk (1UL << SCB_SHCSR_PENDSVACT_Pos) /*!< SCB SHCSR: PENDSVACT Mask */
#define SCB_SHCSR_SVCALLACT_Pos 7U /*!< SCB SHCSR: SVCALLACT Position */
#define SCB_SHCSR_SVCALLACT_Msk (1UL << SCB_SHCSR_SVCALLACT_Pos) /*!< SCB SHCSR: SVCALLACT Mask */
#define SCB_SHCSR_NMIACT_Pos 5U /*!< SCB SHCSR: NMIACT Position */
#define SCB_SHCSR_NMIACT_Msk (1UL << SCB_SHCSR_NMIACT_Pos) /*!< SCB SHCSR: NMIACT Mask */
#define SCB_SHCSR_HARDFAULTACT_Pos 2U /*!< SCB SHCSR: HARDFAULTACT Position */
#define SCB_SHCSR_HARDFAULTACT_Msk (1UL << SCB_SHCSR_HARDFAULTACT_Pos) /*!< SCB SHCSR: HARDFAULTACT Mask */
/*@} end of group CMSIS_SCB */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SysTick System Tick Timer (SysTick)
\brief Type definitions for the System Timer Registers.
@{
*/
/**
\brief Structure type to access the System Timer (SysTick).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SysTick Control and Status Register */
__IOM uint32_t LOAD; /*!< Offset: 0x004 (R/W) SysTick Reload Value Register */
__IOM uint32_t VAL; /*!< Offset: 0x008 (R/W) SysTick Current Value Register */
__IM uint32_t CALIB; /*!< Offset: 0x00C (R/ ) SysTick Calibration Register */
} SysTick_Type;
/* SysTick Control / Status Register Definitions */
#define SysTick_CTRL_COUNTFLAG_Pos 16U /*!< SysTick CTRL: COUNTFLAG Position */
#define SysTick_CTRL_COUNTFLAG_Msk (1UL << SysTick_CTRL_COUNTFLAG_Pos) /*!< SysTick CTRL: COUNTFLAG Mask */
#define SysTick_CTRL_CLKSOURCE_Pos 2U /*!< SysTick CTRL: CLKSOURCE Position */
#define SysTick_CTRL_CLKSOURCE_Msk (1UL << SysTick_CTRL_CLKSOURCE_Pos) /*!< SysTick CTRL: CLKSOURCE Mask */
#define SysTick_CTRL_TICKINT_Pos 1U /*!< SysTick CTRL: TICKINT Position */
#define SysTick_CTRL_TICKINT_Msk (1UL << SysTick_CTRL_TICKINT_Pos) /*!< SysTick CTRL: TICKINT Mask */
#define SysTick_CTRL_ENABLE_Pos 0U /*!< SysTick CTRL: ENABLE Position */
#define SysTick_CTRL_ENABLE_Msk (1UL /*<< SysTick_CTRL_ENABLE_Pos*/) /*!< SysTick CTRL: ENABLE Mask */
/* SysTick Reload Register Definitions */
#define SysTick_LOAD_RELOAD_Pos 0U /*!< SysTick LOAD: RELOAD Position */
#define SysTick_LOAD_RELOAD_Msk (0xFFFFFFUL /*<< SysTick_LOAD_RELOAD_Pos*/) /*!< SysTick LOAD: RELOAD Mask */
/* SysTick Current Register Definitions */
#define SysTick_VAL_CURRENT_Pos 0U /*!< SysTick VAL: CURRENT Position */
#define SysTick_VAL_CURRENT_Msk (0xFFFFFFUL /*<< SysTick_VAL_CURRENT_Pos*/) /*!< SysTick VAL: CURRENT Mask */
/* SysTick Calibration Register Definitions */
#define SysTick_CALIB_NOREF_Pos 31U /*!< SysTick CALIB: NOREF Position */
#define SysTick_CALIB_NOREF_Msk (1UL << SysTick_CALIB_NOREF_Pos) /*!< SysTick CALIB: NOREF Mask */
#define SysTick_CALIB_SKEW_Pos 30U /*!< SysTick CALIB: SKEW Position */
#define SysTick_CALIB_SKEW_Msk (1UL << SysTick_CALIB_SKEW_Pos) /*!< SysTick CALIB: SKEW Mask */
#define SysTick_CALIB_TENMS_Pos 0U /*!< SysTick CALIB: TENMS Position */
#define SysTick_CALIB_TENMS_Msk (0xFFFFFFUL /*<< SysTick_CALIB_TENMS_Pos*/) /*!< SysTick CALIB: TENMS Mask */
/*@} end of group CMSIS_SysTick */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_DWT Data Watchpoint and Trace (DWT)
\brief Type definitions for the Data Watchpoint and Trace (DWT)
@{
*/
/**
\brief Structure type to access the Data Watchpoint and Trace Register (DWT).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) Control Register */
uint32_t RESERVED0[6U];
__IM uint32_t PCSR; /*!< Offset: 0x01C (R/ ) Program Counter Sample Register */
__IOM uint32_t COMP0; /*!< Offset: 0x020 (R/W) Comparator Register 0 */
uint32_t RESERVED1[1U];
__IOM uint32_t FUNCTION0; /*!< Offset: 0x028 (R/W) Function Register 0 */
uint32_t RESERVED2[1U];
__IOM uint32_t COMP1; /*!< Offset: 0x030 (R/W) Comparator Register 1 */
uint32_t RESERVED3[1U];
__IOM uint32_t FUNCTION1; /*!< Offset: 0x038 (R/W) Function Register 1 */
uint32_t RESERVED4[1U];
__IOM uint32_t COMP2; /*!< Offset: 0x040 (R/W) Comparator Register 2 */
uint32_t RESERVED5[1U];
__IOM uint32_t FUNCTION2; /*!< Offset: 0x048 (R/W) Function Register 2 */
uint32_t RESERVED6[1U];
__IOM uint32_t COMP3; /*!< Offset: 0x050 (R/W) Comparator Register 3 */
uint32_t RESERVED7[1U];
__IOM uint32_t FUNCTION3; /*!< Offset: 0x058 (R/W) Function Register 3 */
uint32_t RESERVED8[1U];
__IOM uint32_t COMP4; /*!< Offset: 0x060 (R/W) Comparator Register 4 */
uint32_t RESERVED9[1U];
__IOM uint32_t FUNCTION4; /*!< Offset: 0x068 (R/W) Function Register 4 */
uint32_t RESERVED10[1U];
__IOM uint32_t COMP5; /*!< Offset: 0x070 (R/W) Comparator Register 5 */
uint32_t RESERVED11[1U];
__IOM uint32_t FUNCTION5; /*!< Offset: 0x078 (R/W) Function Register 5 */
uint32_t RESERVED12[1U];
__IOM uint32_t COMP6; /*!< Offset: 0x080 (R/W) Comparator Register 6 */
uint32_t RESERVED13[1U];
__IOM uint32_t FUNCTION6; /*!< Offset: 0x088 (R/W) Function Register 6 */
uint32_t RESERVED14[1U];
__IOM uint32_t COMP7; /*!< Offset: 0x090 (R/W) Comparator Register 7 */
uint32_t RESERVED15[1U];
__IOM uint32_t FUNCTION7; /*!< Offset: 0x098 (R/W) Function Register 7 */
uint32_t RESERVED16[1U];
__IOM uint32_t COMP8; /*!< Offset: 0x0A0 (R/W) Comparator Register 8 */
uint32_t RESERVED17[1U];
__IOM uint32_t FUNCTION8; /*!< Offset: 0x0A8 (R/W) Function Register 8 */
uint32_t RESERVED18[1U];
__IOM uint32_t COMP9; /*!< Offset: 0x0B0 (R/W) Comparator Register 9 */
uint32_t RESERVED19[1U];
__IOM uint32_t FUNCTION9; /*!< Offset: 0x0B8 (R/W) Function Register 9 */
uint32_t RESERVED20[1U];
__IOM uint32_t COMP10; /*!< Offset: 0x0C0 (R/W) Comparator Register 10 */
uint32_t RESERVED21[1U];
__IOM uint32_t FUNCTION10; /*!< Offset: 0x0C8 (R/W) Function Register 10 */
uint32_t RESERVED22[1U];
__IOM uint32_t COMP11; /*!< Offset: 0x0D0 (R/W) Comparator Register 11 */
uint32_t RESERVED23[1U];
__IOM uint32_t FUNCTION11; /*!< Offset: 0x0D8 (R/W) Function Register 11 */
uint32_t RESERVED24[1U];
__IOM uint32_t COMP12; /*!< Offset: 0x0E0 (R/W) Comparator Register 12 */
uint32_t RESERVED25[1U];
__IOM uint32_t FUNCTION12; /*!< Offset: 0x0E8 (R/W) Function Register 12 */
uint32_t RESERVED26[1U];
__IOM uint32_t COMP13; /*!< Offset: 0x0F0 (R/W) Comparator Register 13 */
uint32_t RESERVED27[1U];
__IOM uint32_t FUNCTION13; /*!< Offset: 0x0F8 (R/W) Function Register 13 */
uint32_t RESERVED28[1U];
__IOM uint32_t COMP14; /*!< Offset: 0x100 (R/W) Comparator Register 14 */
uint32_t RESERVED29[1U];
__IOM uint32_t FUNCTION14; /*!< Offset: 0x108 (R/W) Function Register 14 */
uint32_t RESERVED30[1U];
__IOM uint32_t COMP15; /*!< Offset: 0x110 (R/W) Comparator Register 15 */
uint32_t RESERVED31[1U];
__IOM uint32_t FUNCTION15; /*!< Offset: 0x118 (R/W) Function Register 15 */
} DWT_Type;
/* DWT Control Register Definitions */
#define DWT_CTRL_NUMCOMP_Pos 28U /*!< DWT CTRL: NUMCOMP Position */
#define DWT_CTRL_NUMCOMP_Msk (0xFUL << DWT_CTRL_NUMCOMP_Pos) /*!< DWT CTRL: NUMCOMP Mask */
#define DWT_CTRL_NOTRCPKT_Pos 27U /*!< DWT CTRL: NOTRCPKT Position */
#define DWT_CTRL_NOTRCPKT_Msk (0x1UL << DWT_CTRL_NOTRCPKT_Pos) /*!< DWT CTRL: NOTRCPKT Mask */
#define DWT_CTRL_NOEXTTRIG_Pos 26U /*!< DWT CTRL: NOEXTTRIG Position */
#define DWT_CTRL_NOEXTTRIG_Msk (0x1UL << DWT_CTRL_NOEXTTRIG_Pos) /*!< DWT CTRL: NOEXTTRIG Mask */
#define DWT_CTRL_NOCYCCNT_Pos 25U /*!< DWT CTRL: NOCYCCNT Position */
#define DWT_CTRL_NOCYCCNT_Msk (0x1UL << DWT_CTRL_NOCYCCNT_Pos) /*!< DWT CTRL: NOCYCCNT Mask */
#define DWT_CTRL_NOPRFCNT_Pos 24U /*!< DWT CTRL: NOPRFCNT Position */
#define DWT_CTRL_NOPRFCNT_Msk (0x1UL << DWT_CTRL_NOPRFCNT_Pos) /*!< DWT CTRL: NOPRFCNT Mask */
/* DWT Comparator Function Register Definitions */
#define DWT_FUNCTION_ID_Pos 27U /*!< DWT FUNCTION: ID Position */
#define DWT_FUNCTION_ID_Msk (0x1FUL << DWT_FUNCTION_ID_Pos) /*!< DWT FUNCTION: ID Mask */
#define DWT_FUNCTION_MATCHED_Pos 24U /*!< DWT FUNCTION: MATCHED Position */
#define DWT_FUNCTION_MATCHED_Msk (0x1UL << DWT_FUNCTION_MATCHED_Pos) /*!< DWT FUNCTION: MATCHED Mask */
#define DWT_FUNCTION_DATAVSIZE_Pos 10U /*!< DWT FUNCTION: DATAVSIZE Position */
#define DWT_FUNCTION_DATAVSIZE_Msk (0x3UL << DWT_FUNCTION_DATAVSIZE_Pos) /*!< DWT FUNCTION: DATAVSIZE Mask */
#define DWT_FUNCTION_ACTION_Pos 4U /*!< DWT FUNCTION: ACTION Position */
#define DWT_FUNCTION_ACTION_Msk (0x3UL << DWT_FUNCTION_ACTION_Pos) /*!< DWT FUNCTION: ACTION Mask */
#define DWT_FUNCTION_MATCH_Pos 0U /*!< DWT FUNCTION: MATCH Position */
#define DWT_FUNCTION_MATCH_Msk (0xFUL /*<< DWT_FUNCTION_MATCH_Pos*/) /*!< DWT FUNCTION: MATCH Mask */
/*@}*/ /* end of group CMSIS_DWT */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_TPI Trace Port Interface (TPI)
\brief Type definitions for the Trace Port Interface (TPI)
@{
*/
/**
\brief Structure type to access the Trace Port Interface Register (TPI).
*/
typedef struct
{
__IM uint32_t SSPSR; /*!< Offset: 0x000 (R/ ) Supported Parallel Port Sizes Register */
__IOM uint32_t CSPSR; /*!< Offset: 0x004 (R/W) Current Parallel Port Sizes Register */
uint32_t RESERVED0[2U];
__IOM uint32_t ACPR; /*!< Offset: 0x010 (R/W) Asynchronous Clock Prescaler Register */
uint32_t RESERVED1[55U];
__IOM uint32_t SPPR; /*!< Offset: 0x0F0 (R/W) Selected Pin Protocol Register */
uint32_t RESERVED2[131U];
__IM uint32_t FFSR; /*!< Offset: 0x300 (R/ ) Formatter and Flush Status Register */
__IOM uint32_t FFCR; /*!< Offset: 0x304 (R/W) Formatter and Flush Control Register */
__IOM uint32_t PSCR; /*!< Offset: 0x308 (R/W) Periodic Synchronization Control Register */
uint32_t RESERVED3[809U];
__OM uint32_t LAR; /*!< Offset: 0xFB0 ( /W) Software Lock Access Register */
__IM uint32_t LSR; /*!< Offset: 0xFB4 (R/ ) Software Lock Status Register */
uint32_t RESERVED4[4U];
__IM uint32_t TYPE; /*!< Offset: 0xFC8 (R/ ) Device Identifier Register */
__IM uint32_t DEVTYPE; /*!< Offset: 0xFCC (R/ ) Device Type Register */
} TPI_Type;
/* TPI Asynchronous Clock Prescaler Register Definitions */
#define TPI_ACPR_SWOSCALER_Pos 0U /*!< TPI ACPR: SWOSCALER Position */
#define TPI_ACPR_SWOSCALER_Msk (0xFFFFUL /*<< TPI_ACPR_SWOSCALER_Pos*/) /*!< TPI ACPR: SWOSCALER Mask */
/* TPI Selected Pin Protocol Register Definitions */
#define TPI_SPPR_TXMODE_Pos 0U /*!< TPI SPPR: TXMODE Position */
#define TPI_SPPR_TXMODE_Msk (0x3UL /*<< TPI_SPPR_TXMODE_Pos*/) /*!< TPI SPPR: TXMODE Mask */
/* TPI Formatter and Flush Status Register Definitions */
#define TPI_FFSR_FtNonStop_Pos 3U /*!< TPI FFSR: FtNonStop Position */
#define TPI_FFSR_FtNonStop_Msk (0x1UL << TPI_FFSR_FtNonStop_Pos) /*!< TPI FFSR: FtNonStop Mask */
#define TPI_FFSR_TCPresent_Pos 2U /*!< TPI FFSR: TCPresent Position */
#define TPI_FFSR_TCPresent_Msk (0x1UL << TPI_FFSR_TCPresent_Pos) /*!< TPI FFSR: TCPresent Mask */
#define TPI_FFSR_FtStopped_Pos 1U /*!< TPI FFSR: FtStopped Position */
#define TPI_FFSR_FtStopped_Msk (0x1UL << TPI_FFSR_FtStopped_Pos) /*!< TPI FFSR: FtStopped Mask */
#define TPI_FFSR_FlInProg_Pos 0U /*!< TPI FFSR: FlInProg Position */
#define TPI_FFSR_FlInProg_Msk (0x1UL /*<< TPI_FFSR_FlInProg_Pos*/) /*!< TPI FFSR: FlInProg Mask */
/* TPI Formatter and Flush Control Register Definitions */
#define TPI_FFCR_TrigIn_Pos 8U /*!< TPI FFCR: TrigIn Position */
#define TPI_FFCR_TrigIn_Msk (0x1UL << TPI_FFCR_TrigIn_Pos) /*!< TPI FFCR: TrigIn Mask */
#define TPI_FFCR_FOnMan_Pos 6U /*!< TPI FFCR: FOnMan Position */
#define TPI_FFCR_FOnMan_Msk (0x1UL << TPI_FFCR_FOnMan_Pos) /*!< TPI FFCR: FOnMan Mask */
#define TPI_FFCR_EnFCont_Pos 1U /*!< TPI FFCR: EnFCont Position */
#define TPI_FFCR_EnFCont_Msk (0x1UL << TPI_FFCR_EnFCont_Pos) /*!< TPI FFCR: EnFCont Mask */
/* TPI Periodic Synchronization Control Register Definitions */
#define TPI_PSCR_PSCount_Pos 0U /*!< TPI PSCR: PSCount Position */
#define TPI_PSCR_PSCount_Msk (0x1FUL /*<< TPI_PSCR_PSCount_Pos*/) /*!< TPI PSCR: TPSCount Mask */
/* TPI Software Lock Status Register Definitions */
#define TPI_LSR_nTT_Pos 1U /*!< TPI LSR: Not thirty-two bit. Position */
#define TPI_LSR_nTT_Msk (0x1UL << TPI_LSR_nTT_Pos) /*!< TPI LSR: Not thirty-two bit. Mask */
#define TPI_LSR_SLK_Pos 1U /*!< TPI LSR: Software Lock status Position */
#define TPI_LSR_SLK_Msk (0x1UL << TPI_LSR_SLK_Pos) /*!< TPI LSR: Software Lock status Mask */
#define TPI_LSR_SLI_Pos 0U /*!< TPI LSR: Software Lock implemented Position */
#define TPI_LSR_SLI_Msk (0x1UL /*<< TPI_LSR_SLI_Pos*/) /*!< TPI LSR: Software Lock implemented Mask */
/* TPI DEVID Register Definitions */
#define TPI_DEVID_NRZVALID_Pos 11U /*!< TPI DEVID: NRZVALID Position */
#define TPI_DEVID_NRZVALID_Msk (0x1UL << TPI_DEVID_NRZVALID_Pos) /*!< TPI DEVID: NRZVALID Mask */
#define TPI_DEVID_MANCVALID_Pos 10U /*!< TPI DEVID: MANCVALID Position */
#define TPI_DEVID_MANCVALID_Msk (0x1UL << TPI_DEVID_MANCVALID_Pos) /*!< TPI DEVID: MANCVALID Mask */
#define TPI_DEVID_PTINVALID_Pos 9U /*!< TPI DEVID: PTINVALID Position */
#define TPI_DEVID_PTINVALID_Msk (0x1UL << TPI_DEVID_PTINVALID_Pos) /*!< TPI DEVID: PTINVALID Mask */
#define TPI_DEVID_FIFOSZ_Pos 6U /*!< TPI DEVID: FIFO depth Position */
#define TPI_DEVID_FIFOSZ_Msk (0x7UL << TPI_DEVID_FIFOSZ_Pos) /*!< TPI DEVID: FIFO depth Mask */
/* TPI DEVTYPE Register Definitions */
#define TPI_DEVTYPE_SubType_Pos 4U /*!< TPI DEVTYPE: SubType Position */
#define TPI_DEVTYPE_SubType_Msk (0xFUL /*<< TPI_DEVTYPE_SubType_Pos*/) /*!< TPI DEVTYPE: SubType Mask */
#define TPI_DEVTYPE_MajorType_Pos 0U /*!< TPI DEVTYPE: MajorType Position */
#define TPI_DEVTYPE_MajorType_Msk (0xFUL << TPI_DEVTYPE_MajorType_Pos) /*!< TPI DEVTYPE: MajorType Mask */
/*@}*/ /* end of group CMSIS_TPI */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_MPU Memory Protection Unit (MPU)
\brief Type definitions for the Memory Protection Unit (MPU)
@{
*/
/**
\brief Structure type to access the Memory Protection Unit (MPU).
*/
typedef struct
{
__IM uint32_t TYPE; /*!< Offset: 0x000 (R/ ) MPU Type Register */
__IOM uint32_t CTRL; /*!< Offset: 0x004 (R/W) MPU Control Register */
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) MPU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) MPU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) MPU Region Limit Address Register */
uint32_t RESERVED0[7U];
union {
__IOM uint32_t MAIR[2];
struct {
__IOM uint32_t MAIR0; /*!< Offset: 0x030 (R/W) MPU Memory Attribute Indirection Register 0 */
__IOM uint32_t MAIR1; /*!< Offset: 0x034 (R/W) MPU Memory Attribute Indirection Register 1 */
};
};
} MPU_Type;
#define MPU_TYPE_RALIASES 1U
/* MPU Type Register Definitions */
#define MPU_TYPE_IREGION_Pos 16U /*!< MPU TYPE: IREGION Position */
#define MPU_TYPE_IREGION_Msk (0xFFUL << MPU_TYPE_IREGION_Pos) /*!< MPU TYPE: IREGION Mask */
#define MPU_TYPE_DREGION_Pos 8U /*!< MPU TYPE: DREGION Position */
#define MPU_TYPE_DREGION_Msk (0xFFUL << MPU_TYPE_DREGION_Pos) /*!< MPU TYPE: DREGION Mask */
#define MPU_TYPE_SEPARATE_Pos 0U /*!< MPU TYPE: SEPARATE Position */
#define MPU_TYPE_SEPARATE_Msk (1UL /*<< MPU_TYPE_SEPARATE_Pos*/) /*!< MPU TYPE: SEPARATE Mask */
/* MPU Control Register Definitions */
#define MPU_CTRL_PRIVDEFENA_Pos 2U /*!< MPU CTRL: PRIVDEFENA Position */
#define MPU_CTRL_PRIVDEFENA_Msk (1UL << MPU_CTRL_PRIVDEFENA_Pos) /*!< MPU CTRL: PRIVDEFENA Mask */
#define MPU_CTRL_HFNMIENA_Pos 1U /*!< MPU CTRL: HFNMIENA Position */
#define MPU_CTRL_HFNMIENA_Msk (1UL << MPU_CTRL_HFNMIENA_Pos) /*!< MPU CTRL: HFNMIENA Mask */
#define MPU_CTRL_ENABLE_Pos 0U /*!< MPU CTRL: ENABLE Position */
#define MPU_CTRL_ENABLE_Msk (1UL /*<< MPU_CTRL_ENABLE_Pos*/) /*!< MPU CTRL: ENABLE Mask */
/* MPU Region Number Register Definitions */
#define MPU_RNR_REGION_Pos 0U /*!< MPU RNR: REGION Position */
#define MPU_RNR_REGION_Msk (0xFFUL /*<< MPU_RNR_REGION_Pos*/) /*!< MPU RNR: REGION Mask */
/* MPU Region Base Address Register Definitions */
#define MPU_RBAR_BASE_Pos 5U /*!< MPU RBAR: BASE Position */
#define MPU_RBAR_BASE_Msk (0x7FFFFFFUL << MPU_RBAR_BASE_Pos) /*!< MPU RBAR: BASE Mask */
#define MPU_RBAR_SH_Pos 3U /*!< MPU RBAR: SH Position */
#define MPU_RBAR_SH_Msk (0x3UL << MPU_RBAR_SH_Pos) /*!< MPU RBAR: SH Mask */
#define MPU_RBAR_AP_Pos 1U /*!< MPU RBAR: AP Position */
#define MPU_RBAR_AP_Msk (0x3UL << MPU_RBAR_AP_Pos) /*!< MPU RBAR: AP Mask */
#define MPU_RBAR_XN_Pos 0U /*!< MPU RBAR: XN Position */
#define MPU_RBAR_XN_Msk (01UL /*<< MPU_RBAR_XN_Pos*/) /*!< MPU RBAR: XN Mask */
/* MPU Region Limit Address Register Definitions */
#define MPU_RLAR_LIMIT_Pos 5U /*!< MPU RLAR: LIMIT Position */
#define MPU_RLAR_LIMIT_Msk (0x7FFFFFFUL << MPU_RLAR_LIMIT_Pos) /*!< MPU RLAR: LIMIT Mask */
#define MPU_RLAR_AttrIndx_Pos 1U /*!< MPU RLAR: AttrIndx Position */
#define MPU_RLAR_AttrIndx_Msk (0x7UL << MPU_RLAR_AttrIndx_Pos) /*!< MPU RLAR: AttrIndx Mask */
#define MPU_RLAR_EN_Pos 0U /*!< MPU RLAR: EN Position */
#define MPU_RLAR_EN_Msk (1UL /*<< MPU_RLAR_EN_Pos*/) /*!< MPU RLAR: EN Mask */
/* MPU Memory Attribute Indirection Register 0 Definitions */
#define MPU_MAIR0_Attr3_Pos 24U /*!< MPU MAIR0: Attr3 Position */
#define MPU_MAIR0_Attr3_Msk (0xFFUL << MPU_MAIR0_Attr3_Pos) /*!< MPU MAIR0: Attr3 Mask */
#define MPU_MAIR0_Attr2_Pos 16U /*!< MPU MAIR0: Attr2 Position */
#define MPU_MAIR0_Attr2_Msk (0xFFUL << MPU_MAIR0_Attr2_Pos) /*!< MPU MAIR0: Attr2 Mask */
#define MPU_MAIR0_Attr1_Pos 8U /*!< MPU MAIR0: Attr1 Position */
#define MPU_MAIR0_Attr1_Msk (0xFFUL << MPU_MAIR0_Attr1_Pos) /*!< MPU MAIR0: Attr1 Mask */
#define MPU_MAIR0_Attr0_Pos 0U /*!< MPU MAIR0: Attr0 Position */
#define MPU_MAIR0_Attr0_Msk (0xFFUL /*<< MPU_MAIR0_Attr0_Pos*/) /*!< MPU MAIR0: Attr0 Mask */
/* MPU Memory Attribute Indirection Register 1 Definitions */
#define MPU_MAIR1_Attr7_Pos 24U /*!< MPU MAIR1: Attr7 Position */
#define MPU_MAIR1_Attr7_Msk (0xFFUL << MPU_MAIR1_Attr7_Pos) /*!< MPU MAIR1: Attr7 Mask */
#define MPU_MAIR1_Attr6_Pos 16U /*!< MPU MAIR1: Attr6 Position */
#define MPU_MAIR1_Attr6_Msk (0xFFUL << MPU_MAIR1_Attr6_Pos) /*!< MPU MAIR1: Attr6 Mask */
#define MPU_MAIR1_Attr5_Pos 8U /*!< MPU MAIR1: Attr5 Position */
#define MPU_MAIR1_Attr5_Msk (0xFFUL << MPU_MAIR1_Attr5_Pos) /*!< MPU MAIR1: Attr5 Mask */
#define MPU_MAIR1_Attr4_Pos 0U /*!< MPU MAIR1: Attr4 Position */
#define MPU_MAIR1_Attr4_Msk (0xFFUL /*<< MPU_MAIR1_Attr4_Pos*/) /*!< MPU MAIR1: Attr4 Mask */
/*@} end of group CMSIS_MPU */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_SAU Security Attribution Unit (SAU)
\brief Type definitions for the Security Attribution Unit (SAU)
@{
*/
/**
\brief Structure type to access the Security Attribution Unit (SAU).
*/
typedef struct
{
__IOM uint32_t CTRL; /*!< Offset: 0x000 (R/W) SAU Control Register */
__IM uint32_t TYPE; /*!< Offset: 0x004 (R/ ) SAU Type Register */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
__IOM uint32_t RNR; /*!< Offset: 0x008 (R/W) SAU Region Number Register */
__IOM uint32_t RBAR; /*!< Offset: 0x00C (R/W) SAU Region Base Address Register */
__IOM uint32_t RLAR; /*!< Offset: 0x010 (R/W) SAU Region Limit Address Register */
#endif
} SAU_Type;
/* SAU Control Register Definitions */
#define SAU_CTRL_ALLNS_Pos 1U /*!< SAU CTRL: ALLNS Position */
#define SAU_CTRL_ALLNS_Msk (1UL << SAU_CTRL_ALLNS_Pos) /*!< SAU CTRL: ALLNS Mask */
#define SAU_CTRL_ENABLE_Pos 0U /*!< SAU CTRL: ENABLE Position */
#define SAU_CTRL_ENABLE_Msk (1UL /*<< SAU_CTRL_ENABLE_Pos*/) /*!< SAU CTRL: ENABLE Mask */
/* SAU Type Register Definitions */
#define SAU_TYPE_SREGION_Pos 0U /*!< SAU TYPE: SREGION Position */
#define SAU_TYPE_SREGION_Msk (0xFFUL /*<< SAU_TYPE_SREGION_Pos*/) /*!< SAU TYPE: SREGION Mask */
#if defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U)
/* SAU Region Number Register Definitions */
#define SAU_RNR_REGION_Pos 0U /*!< SAU RNR: REGION Position */
#define SAU_RNR_REGION_Msk (0xFFUL /*<< SAU_RNR_REGION_Pos*/) /*!< SAU RNR: REGION Mask */
/* SAU Region Base Address Register Definitions */
#define SAU_RBAR_BADDR_Pos 5U /*!< SAU RBAR: BADDR Position */
#define SAU_RBAR_BADDR_Msk (0x7FFFFFFUL << SAU_RBAR_BADDR_Pos) /*!< SAU RBAR: BADDR Mask */
/* SAU Region Limit Address Register Definitions */
#define SAU_RLAR_LADDR_Pos 5U /*!< SAU RLAR: LADDR Position */
#define SAU_RLAR_LADDR_Msk (0x7FFFFFFUL << SAU_RLAR_LADDR_Pos) /*!< SAU RLAR: LADDR Mask */
#define SAU_RLAR_NSC_Pos 1U /*!< SAU RLAR: NSC Position */
#define SAU_RLAR_NSC_Msk (1UL << SAU_RLAR_NSC_Pos) /*!< SAU RLAR: NSC Mask */
#define SAU_RLAR_ENABLE_Pos 0U /*!< SAU RLAR: ENABLE Position */
#define SAU_RLAR_ENABLE_Msk (1UL /*<< SAU_RLAR_ENABLE_Pos*/) /*!< SAU RLAR: ENABLE Mask */
#endif /* defined (__SAUREGION_PRESENT) && (__SAUREGION_PRESENT == 1U) */
/*@} end of group CMSIS_SAU */
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_CoreDebug Core Debug Registers (CoreDebug)
\brief Type definitions for the Core Debug Registers
@{
*/
/**
\brief Structure type to access the Core Debug Register (CoreDebug).
*/
typedef struct
{
__IOM uint32_t DHCSR; /*!< Offset: 0x000 (R/W) Debug Halting Control and Status Register */
__OM uint32_t DCRSR; /*!< Offset: 0x004 ( /W) Debug Core Register Selector Register */
__IOM uint32_t DCRDR; /*!< Offset: 0x008 (R/W) Debug Core Register Data Register */
__IOM uint32_t DEMCR; /*!< Offset: 0x00C (R/W) Debug Exception and Monitor Control Register */
uint32_t RESERVED4[1U];
__IOM uint32_t DAUTHCTRL; /*!< Offset: 0x014 (R/W) Debug Authentication Control Register */
__IOM uint32_t DSCSR; /*!< Offset: 0x018 (R/W) Debug Security Control and Status Register */
} CoreDebug_Type;
/* Debug Halting Control and Status Register Definitions */
#define CoreDebug_DHCSR_DBGKEY_Pos 16U /*!< CoreDebug DHCSR: DBGKEY Position */
#define CoreDebug_DHCSR_DBGKEY_Msk (0xFFFFUL << CoreDebug_DHCSR_DBGKEY_Pos) /*!< CoreDebug DHCSR: DBGKEY Mask */
#define CoreDebug_DHCSR_S_RESTART_ST_Pos 26U /*!< CoreDebug DHCSR: S_RESTART_ST Position */
#define CoreDebug_DHCSR_S_RESTART_ST_Msk (1UL << CoreDebug_DHCSR_S_RESTART_ST_Pos) /*!< CoreDebug DHCSR: S_RESTART_ST Mask */
#define CoreDebug_DHCSR_S_RESET_ST_Pos 25U /*!< CoreDebug DHCSR: S_RESET_ST Position */
#define CoreDebug_DHCSR_S_RESET_ST_Msk (1UL << CoreDebug_DHCSR_S_RESET_ST_Pos) /*!< CoreDebug DHCSR: S_RESET_ST Mask */
#define CoreDebug_DHCSR_S_RETIRE_ST_Pos 24U /*!< CoreDebug DHCSR: S_RETIRE_ST Position */
#define CoreDebug_DHCSR_S_RETIRE_ST_Msk (1UL << CoreDebug_DHCSR_S_RETIRE_ST_Pos) /*!< CoreDebug DHCSR: S_RETIRE_ST Mask */
#define CoreDebug_DHCSR_S_LOCKUP_Pos 19U /*!< CoreDebug DHCSR: S_LOCKUP Position */
#define CoreDebug_DHCSR_S_LOCKUP_Msk (1UL << CoreDebug_DHCSR_S_LOCKUP_Pos) /*!< CoreDebug DHCSR: S_LOCKUP Mask */
#define CoreDebug_DHCSR_S_SLEEP_Pos 18U /*!< CoreDebug DHCSR: S_SLEEP Position */
#define CoreDebug_DHCSR_S_SLEEP_Msk (1UL << CoreDebug_DHCSR_S_SLEEP_Pos) /*!< CoreDebug DHCSR: S_SLEEP Mask */
#define CoreDebug_DHCSR_S_HALT_Pos 17U /*!< CoreDebug DHCSR: S_HALT Position */
#define CoreDebug_DHCSR_S_HALT_Msk (1UL << CoreDebug_DHCSR_S_HALT_Pos) /*!< CoreDebug DHCSR: S_HALT Mask */
#define CoreDebug_DHCSR_S_REGRDY_Pos 16U /*!< CoreDebug DHCSR: S_REGRDY Position */
#define CoreDebug_DHCSR_S_REGRDY_Msk (1UL << CoreDebug_DHCSR_S_REGRDY_Pos) /*!< CoreDebug DHCSR: S_REGRDY Mask */
#define CoreDebug_DHCSR_C_MASKINTS_Pos 3U /*!< CoreDebug DHCSR: C_MASKINTS Position */
#define CoreDebug_DHCSR_C_MASKINTS_Msk (1UL << CoreDebug_DHCSR_C_MASKINTS_Pos) /*!< CoreDebug DHCSR: C_MASKINTS Mask */
#define CoreDebug_DHCSR_C_STEP_Pos 2U /*!< CoreDebug DHCSR: C_STEP Position */
#define CoreDebug_DHCSR_C_STEP_Msk (1UL << CoreDebug_DHCSR_C_STEP_Pos) /*!< CoreDebug DHCSR: C_STEP Mask */
#define CoreDebug_DHCSR_C_HALT_Pos 1U /*!< CoreDebug DHCSR: C_HALT Position */
#define CoreDebug_DHCSR_C_HALT_Msk (1UL << CoreDebug_DHCSR_C_HALT_Pos) /*!< CoreDebug DHCSR: C_HALT Mask */
#define CoreDebug_DHCSR_C_DEBUGEN_Pos 0U /*!< CoreDebug DHCSR: C_DEBUGEN Position */
#define CoreDebug_DHCSR_C_DEBUGEN_Msk (1UL /*<< CoreDebug_DHCSR_C_DEBUGEN_Pos*/) /*!< CoreDebug DHCSR: C_DEBUGEN Mask */
/* Debug Core Register Selector Register Definitions */
#define CoreDebug_DCRSR_REGWnR_Pos 16U /*!< CoreDebug DCRSR: REGWnR Position */
#define CoreDebug_DCRSR_REGWnR_Msk (1UL << CoreDebug_DCRSR_REGWnR_Pos) /*!< CoreDebug DCRSR: REGWnR Mask */
#define CoreDebug_DCRSR_REGSEL_Pos 0U /*!< CoreDebug DCRSR: REGSEL Position */
#define CoreDebug_DCRSR_REGSEL_Msk (0x1FUL /*<< CoreDebug_DCRSR_REGSEL_Pos*/) /*!< CoreDebug DCRSR: REGSEL Mask */
/* Debug Exception and Monitor Control Register */
#define CoreDebug_DEMCR_DWTENA_Pos 24U /*!< CoreDebug DEMCR: DWTENA Position */
#define CoreDebug_DEMCR_DWTENA_Msk (1UL << CoreDebug_DEMCR_DWTENA_Pos) /*!< CoreDebug DEMCR: DWTENA Mask */
#define CoreDebug_DEMCR_VC_HARDERR_Pos 10U /*!< CoreDebug DEMCR: VC_HARDERR Position */
#define CoreDebug_DEMCR_VC_HARDERR_Msk (1UL << CoreDebug_DEMCR_VC_HARDERR_Pos) /*!< CoreDebug DEMCR: VC_HARDERR Mask */
#define CoreDebug_DEMCR_VC_CORERESET_Pos 0U /*!< CoreDebug DEMCR: VC_CORERESET Position */
#define CoreDebug_DEMCR_VC_CORERESET_Msk (1UL /*<< CoreDebug_DEMCR_VC_CORERESET_Pos*/) /*!< CoreDebug DEMCR: VC_CORERESET Mask */
/* Debug Authentication Control Register Definitions */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos 3U /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Position */
#define CoreDebug_DAUTHCTRL_INTSPNIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPNIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPNIDEN, Mask */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos 2U /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPNIDENSEL_Msk (1UL << CoreDebug_DAUTHCTRL_SPNIDENSEL_Pos) /*!< CoreDebug DAUTHCTRL: SPNIDENSEL Mask */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Pos 1U /*!< CoreDebug DAUTHCTRL: INTSPIDEN Position */
#define CoreDebug_DAUTHCTRL_INTSPIDEN_Msk (1UL << CoreDebug_DAUTHCTRL_INTSPIDEN_Pos) /*!< CoreDebug DAUTHCTRL: INTSPIDEN Mask */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Pos 0U /*!< CoreDebug DAUTHCTRL: SPIDENSEL Position */
#define CoreDebug_DAUTHCTRL_SPIDENSEL_Msk (1UL /*<< CoreDebug_DAUTHCTRL_SPIDENSEL_Pos*/) /*!< CoreDebug DAUTHCTRL: SPIDENSEL Mask */
/* Debug Security Control and Status Register Definitions */
#define CoreDebug_DSCSR_CDS_Pos 16U /*!< CoreDebug DSCSR: CDS Position */
#define CoreDebug_DSCSR_CDS_Msk (1UL << CoreDebug_DSCSR_CDS_Pos) /*!< CoreDebug DSCSR: CDS Mask */
#define CoreDebug_DSCSR_SBRSEL_Pos 1U /*!< CoreDebug DSCSR: SBRSEL Position */
#define CoreDebug_DSCSR_SBRSEL_Msk (1UL << CoreDebug_DSCSR_SBRSEL_Pos) /*!< CoreDebug DSCSR: SBRSEL Mask */
#define CoreDebug_DSCSR_SBRSELEN_Pos 0U /*!< CoreDebug DSCSR: SBRSELEN Position */
#define CoreDebug_DSCSR_SBRSELEN_Msk (1UL /*<< CoreDebug_DSCSR_SBRSELEN_Pos*/) /*!< CoreDebug DSCSR: SBRSELEN Mask */
/*@} end of group CMSIS_CoreDebug */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_bitfield Core register bit field macros
\brief Macros for use with bit field definitions (xxx_Pos, xxx_Msk).
@{
*/
/**
\brief Mask and shift a bit field value for use in a register bit range.
\param[in] field Name of the register bit field.
\param[in] value Value of the bit field. This parameter is interpreted as an uint32_t type.
\return Masked and shifted value.
*/
#define _VAL2FLD(field, value) (((uint32_t)(value) << field ## _Pos) & field ## _Msk)
/**
\brief Mask and shift a register value to extract a bit filed value.
\param[in] field Name of the register bit field.
\param[in] value Value of register. This parameter is interpreted as an uint32_t type.
\return Masked and shifted bit field value.
*/
#define _FLD2VAL(field, value) (((uint32_t)(value) & field ## _Msk) >> field ## _Pos)
/*@} end of group CMSIS_core_bitfield */
/**
\ingroup CMSIS_core_register
\defgroup CMSIS_core_base Core Definitions
\brief Definitions for base addresses, unions, and structures.
@{
*/
/* Memory mapping of Core Hardware */
#define SCS_BASE (0xE000E000UL) /*!< System Control Space Base Address */
#define DWT_BASE (0xE0001000UL) /*!< DWT Base Address */
#define TPI_BASE (0xE0040000UL) /*!< TPI Base Address */
#define CoreDebug_BASE (0xE000EDF0UL) /*!< Core Debug Base Address */
#define SysTick_BASE (SCS_BASE + 0x0010UL) /*!< SysTick Base Address */
#define NVIC_BASE (SCS_BASE + 0x0100UL) /*!< NVIC Base Address */
#define SCB_BASE (SCS_BASE + 0x0D00UL) /*!< System Control Block Base Address */
#define SCB ((SCB_Type *) SCB_BASE ) /*!< SCB configuration struct */
#define SysTick ((SysTick_Type *) SysTick_BASE ) /*!< SysTick configuration struct */
#define NVIC ((NVIC_Type *) NVIC_BASE ) /*!< NVIC configuration struct */
#define DWT ((DWT_Type *) DWT_BASE ) /*!< DWT configuration struct */
#define TPI ((TPI_Type *) TPI_BASE ) /*!< TPI configuration struct */
#define CoreDebug ((CoreDebug_Type *) CoreDebug_BASE ) /*!< Core Debug configuration struct */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE (SCS_BASE + 0x0D90UL) /*!< Memory Protection Unit */
#define MPU ((MPU_Type *) MPU_BASE ) /*!< Memory Protection Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SAU_BASE (SCS_BASE + 0x0DD0UL) /*!< Security Attribution Unit */
#define SAU ((SAU_Type *) SAU_BASE ) /*!< Security Attribution Unit */
#endif
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
#define SCS_BASE_NS (0xE002E000UL) /*!< System Control Space Base Address (non-secure address space) */
#define CoreDebug_BASE_NS (0xE002EDF0UL) /*!< Core Debug Base Address (non-secure address space) */
#define SysTick_BASE_NS (SCS_BASE_NS + 0x0010UL) /*!< SysTick Base Address (non-secure address space) */
#define NVIC_BASE_NS (SCS_BASE_NS + 0x0100UL) /*!< NVIC Base Address (non-secure address space) */
#define SCB_BASE_NS (SCS_BASE_NS + 0x0D00UL) /*!< System Control Block Base Address (non-secure address space) */
#define SCB_NS ((SCB_Type *) SCB_BASE_NS ) /*!< SCB configuration struct (non-secure address space) */
#define SysTick_NS ((SysTick_Type *) SysTick_BASE_NS ) /*!< SysTick configuration struct (non-secure address space) */
#define NVIC_NS ((NVIC_Type *) NVIC_BASE_NS ) /*!< NVIC configuration struct (non-secure address space) */
#define CoreDebug_NS ((CoreDebug_Type *) CoreDebug_BASE_NS) /*!< Core Debug configuration struct (non-secure address space) */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#define MPU_BASE_NS (SCS_BASE_NS + 0x0D90UL) /*!< Memory Protection Unit (non-secure address space) */
#define MPU_NS ((MPU_Type *) MPU_BASE_NS ) /*!< Memory Protection Unit (non-secure address space) */
#endif
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} */
/*******************************************************************************
* Hardware Abstraction Layer
Core Function Interface contains:
- Core NVIC Functions
- Core SysTick Functions
- Core Register Access Functions
******************************************************************************/
/**
\defgroup CMSIS_Core_FunctionInterface Functions and Instructions Reference
*/
/* ########################## NVIC functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_NVICFunctions NVIC Functions
\brief Functions that manage interrupts and exceptions via the NVIC.
@{
*/
#ifdef CMSIS_NVIC_VIRTUAL
#ifndef CMSIS_NVIC_VIRTUAL_HEADER_FILE
#define CMSIS_NVIC_VIRTUAL_HEADER_FILE "cmsis_nvic_virtual.h"
#endif
#include CMSIS_NVIC_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetPriorityGrouping __NVIC_SetPriorityGrouping
#define NVIC_GetPriorityGrouping __NVIC_GetPriorityGrouping
#define NVIC_EnableIRQ __NVIC_EnableIRQ
#define NVIC_GetEnableIRQ __NVIC_GetEnableIRQ
#define NVIC_DisableIRQ __NVIC_DisableIRQ
#define NVIC_GetPendingIRQ __NVIC_GetPendingIRQ
#define NVIC_SetPendingIRQ __NVIC_SetPendingIRQ
#define NVIC_ClearPendingIRQ __NVIC_ClearPendingIRQ
#define NVIC_GetActive __NVIC_GetActive
#define NVIC_SetPriority __NVIC_SetPriority
#define NVIC_GetPriority __NVIC_GetPriority
#define NVIC_SystemReset __NVIC_SystemReset
#endif /* CMSIS_NVIC_VIRTUAL */
#ifdef CMSIS_VECTAB_VIRTUAL
#ifndef CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#define CMSIS_VECTAB_VIRTUAL_HEADER_FILE "cmsis_vectab_virtual.h"
#endif
#include CMSIS_VECTAB_VIRTUAL_HEADER_FILE
#else
#define NVIC_SetVector __NVIC_SetVector
#define NVIC_GetVector __NVIC_GetVector
#endif /* (CMSIS_VECTAB_VIRTUAL) */
#define NVIC_USER_IRQ_OFFSET 16
/* Special LR values for Secure/Non-Secure call handling and exception handling */
/* Function Return Payload (from ARMv8-M Architecture Reference Manual) LR value on entry from Secure BLXNS */
#define FNC_RETURN (0xFEFFFFFFUL) /* bit [0] ignored when processing a branch */
/* The following EXC_RETURN mask values are used to evaluate the LR on exception entry */
#define EXC_RETURN_PREFIX (0xFF000000UL) /* bits [31:24] set to indicate an EXC_RETURN value */
#define EXC_RETURN_S (0x00000040UL) /* bit [6] stack used to push registers: 0=Non-secure 1=Secure */
#define EXC_RETURN_DCRS (0x00000020UL) /* bit [5] stacking rules for called registers: 0=skipped 1=saved */
#define EXC_RETURN_FTYPE (0x00000010UL) /* bit [4] allocate stack for floating-point context: 0=done 1=skipped */
#define EXC_RETURN_MODE (0x00000008UL) /* bit [3] processor mode for return: 0=Handler mode 1=Thread mode */
#define EXC_RETURN_SPSEL (0x00000004UL) /* bit [2] stack pointer used to restore context: 0=MSP 1=PSP */
#define EXC_RETURN_ES (0x00000001UL) /* bit [0] security state exception was taken to: 0=Non-secure 1=Secure */
/* Integrity Signature (from ARMv8-M Architecture Reference Manual) for exception context stacking */
#if defined (__FPU_PRESENT) && (__FPU_PRESENT == 1U) /* Value for processors with floating-point extension: */
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125AUL) /* bit [0] SFTC must match LR bit[4] EXC_RETURN_FTYPE */
#else
#define EXC_INTEGRITY_SIGNATURE (0xFEFA125BUL) /* Value for processors without floating-point extension */
#endif
/* Interrupt Priorities are WORD accessible only under Armv6-M */
/* The following MACROS handle generation of the register offset and byte masks */
#define _BIT_SHIFT(IRQn) ( ((((uint32_t)(int32_t)(IRQn)) ) & 0x03UL) * 8UL)
#define _SHP_IDX(IRQn) ( (((((uint32_t)(int32_t)(IRQn)) & 0x0FUL)-8UL) >> 2UL) )
#define _IP_IDX(IRQn) ( (((uint32_t)(int32_t)(IRQn)) >> 2UL) )
#define __NVIC_SetPriorityGrouping(X) (void)(X)
#define __NVIC_GetPriorityGrouping() (0U)
/**
\brief Enable Interrupt
\details Enables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_EnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
__COMPILER_BARRIER();
NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__COMPILER_BARRIER();
}
}
/**
\brief Get Interrupt Enable status
\details Returns a device specific interrupt enable status from the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetEnableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt
\details Disables a device specific interrupt in the NVIC interrupt controller.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_DisableIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
__DSB();
__ISB();
}
}
/**
\brief Get Pending Interrupt
\details Reads the NVIC pending register and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt
\details Sets the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_SetPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt
\details Clears the pending bit of a device specific interrupt in the NVIC pending register.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void __NVIC_ClearPendingIRQ(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt
\details Reads the active register in the NVIC and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t __NVIC_GetActive(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Get Interrupt Target State
\details Reads the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
\return 1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_GetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Target State
\details Sets the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_SetTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] |= ((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Clear Interrupt Target State
\details Clears the interrupt target field in the NVIC and returns the interrupt target bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 if interrupt is assigned to Secure
1 if interrupt is assigned to Non Secure
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t NVIC_ClearTargetState(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] &= ~((uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL)));
return((uint32_t)(((NVIC->ITNS[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/**
\brief Set Interrupt Priority
\details Sets the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every processor exception.
*/
__STATIC_INLINE void __NVIC_SetPriority(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC->IPR[_IP_IDX(IRQn)] = ((uint32_t)(NVIC->IPR[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB->SHPR[_SHP_IDX(IRQn)] = ((uint32_t)(SCB->SHPR[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority
\details Reads the priority of a device specific interrupt or a processor exception.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority.
Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t __NVIC_GetPriority(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC->IPR[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB->SHPR[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
/**
\brief Encode Priority
\details Encodes the priority for an interrupt with the given priority group,
preemptive priority value, and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS), the smallest possible priority group is set.
\param [in] PriorityGroup Used priority group.
\param [in] PreemptPriority Preemptive priority value (starting from 0).
\param [in] SubPriority Subpriority value (starting from 0).
\return Encoded priority. Value can be used in the function \ref NVIC_SetPriority().
*/
__STATIC_INLINE uint32_t NVIC_EncodePriority (uint32_t PriorityGroup, uint32_t PreemptPriority, uint32_t SubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
return (
((PreemptPriority & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL)) << SubPriorityBits) |
((SubPriority & (uint32_t)((1UL << (SubPriorityBits )) - 1UL)))
);
}
/**
\brief Decode Priority
\details Decodes an interrupt priority value with a given priority group to
preemptive priority value and subpriority value.
In case of a conflict between priority grouping and available
priority bits (__NVIC_PRIO_BITS) the smallest possible priority group is set.
\param [in] Priority Priority value, which can be retrieved with the function \ref NVIC_GetPriority().
\param [in] PriorityGroup Used priority group.
\param [out] pPreemptPriority Preemptive priority value (starting from 0).
\param [out] pSubPriority Subpriority value (starting from 0).
*/
__STATIC_INLINE void NVIC_DecodePriority (uint32_t Priority, uint32_t PriorityGroup, uint32_t* const pPreemptPriority, uint32_t* const pSubPriority)
{
uint32_t PriorityGroupTmp = (PriorityGroup & (uint32_t)0x07UL); /* only values 0..7 are used */
uint32_t PreemptPriorityBits;
uint32_t SubPriorityBits;
PreemptPriorityBits = ((7UL - PriorityGroupTmp) > (uint32_t)(__NVIC_PRIO_BITS)) ? (uint32_t)(__NVIC_PRIO_BITS) : (uint32_t)(7UL - PriorityGroupTmp);
SubPriorityBits = ((PriorityGroupTmp + (uint32_t)(__NVIC_PRIO_BITS)) < (uint32_t)7UL) ? (uint32_t)0UL : (uint32_t)((PriorityGroupTmp - 7UL) + (uint32_t)(__NVIC_PRIO_BITS));
*pPreemptPriority = (Priority >> SubPriorityBits) & (uint32_t)((1UL << (PreemptPriorityBits)) - 1UL);
*pSubPriority = (Priority ) & (uint32_t)((1UL << (SubPriorityBits )) - 1UL);
}
/**
\brief Set Interrupt Vector
\details Sets an interrupt vector in SRAM based interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
VTOR must been relocated to SRAM before.
If VTOR is not present address 0 must be mapped to SRAM.
\param [in] IRQn Interrupt number
\param [in] vector Address of interrupt handler function
*/
__STATIC_INLINE void __NVIC_SetVector(IRQn_Type IRQn, uint32_t vector)
{
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
uint32_t *vectors = (uint32_t *)SCB->VTOR;
#else
uint32_t *vectors = (uint32_t *)0x0U;
#endif
vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET] = vector;
__DSB();
}
/**
\brief Get Interrupt Vector
\details Reads an interrupt vector from interrupt vector table.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Address of interrupt handler function
*/
__STATIC_INLINE uint32_t __NVIC_GetVector(IRQn_Type IRQn)
{
#if defined (__VTOR_PRESENT) && (__VTOR_PRESENT == 1U)
uint32_t *vectors = (uint32_t *)SCB->VTOR;
#else
uint32_t *vectors = (uint32_t *)0x0U;
#endif
return vectors[(int32_t)IRQn + NVIC_USER_IRQ_OFFSET];
}
/**
\brief System Reset
\details Initiates a system reset request to reset the MCU.
*/
__NO_RETURN __STATIC_INLINE void __NVIC_SystemReset(void)
{
__DSB(); /* Ensure all outstanding memory accesses included
buffered write are completed before reset */
SCB->AIRCR = ((0x5FAUL << SCB_AIRCR_VECTKEY_Pos) |
SCB_AIRCR_SYSRESETREQ_Msk);
__DSB(); /* Ensure completion of memory access */
for(;;) /* wait until reset */
{
__NOP();
}
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable Interrupt (non-secure)
\details Enables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_EnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Interrupt Enable status (non-secure)
\details Returns a device specific interrupt enable status from the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt is not enabled.
\return 1 Interrupt is enabled.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetEnableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISER[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Disable Interrupt (non-secure)
\details Disables a device specific interrupt in the non-secure NVIC interrupt controller when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_DisableIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICER[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Pending Interrupt (non-secure)
\details Reads the NVIC pending register in the non-secure NVIC when in secure state and returns the pending bit for the specified device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not pending.
\return 1 Interrupt status is pending.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Pending Interrupt (non-secure)
\details Sets the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_SetPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ISPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Clear Pending Interrupt (non-secure)
\details Clears the pending bit of a device specific interrupt in the non-secure NVIC pending register when in secure state.
\param [in] IRQn Device specific interrupt number.
\note IRQn must not be negative.
*/
__STATIC_INLINE void TZ_NVIC_ClearPendingIRQ_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->ICPR[(((uint32_t)IRQn) >> 5UL)] = (uint32_t)(1UL << (((uint32_t)IRQn) & 0x1FUL));
}
}
/**
\brief Get Active Interrupt (non-secure)
\details Reads the active register in non-secure NVIC when in secure state and returns the active bit for the device specific interrupt.
\param [in] IRQn Device specific interrupt number.
\return 0 Interrupt status is not active.
\return 1 Interrupt status is active.
\note IRQn must not be negative.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetActive_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IABR[(((uint32_t)IRQn) >> 5UL)] & (1UL << (((uint32_t)IRQn) & 0x1FUL))) != 0UL) ? 1UL : 0UL));
}
else
{
return(0U);
}
}
/**
\brief Set Interrupt Priority (non-secure)
\details Sets the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\param [in] priority Priority to set.
\note The priority cannot be set for every non-secure processor exception.
*/
__STATIC_INLINE void TZ_NVIC_SetPriority_NS(IRQn_Type IRQn, uint32_t priority)
{
if ((int32_t)(IRQn) >= 0)
{
NVIC_NS->IPR[_IP_IDX(IRQn)] = ((uint32_t)(NVIC_NS->IPR[_IP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
else
{
SCB_NS->SHPR[_SHP_IDX(IRQn)] = ((uint32_t)(SCB_NS->SHPR[_SHP_IDX(IRQn)] & ~(0xFFUL << _BIT_SHIFT(IRQn))) |
(((priority << (8U - __NVIC_PRIO_BITS)) & (uint32_t)0xFFUL) << _BIT_SHIFT(IRQn)));
}
}
/**
\brief Get Interrupt Priority (non-secure)
\details Reads the priority of a non-secure device specific interrupt or a non-secure processor exception when in secure state.
The interrupt number can be positive to specify a device specific interrupt,
or negative to specify a processor exception.
\param [in] IRQn Interrupt number.
\return Interrupt Priority. Value is aligned automatically to the implemented priority bits of the microcontroller.
*/
__STATIC_INLINE uint32_t TZ_NVIC_GetPriority_NS(IRQn_Type IRQn)
{
if ((int32_t)(IRQn) >= 0)
{
return((uint32_t)(((NVIC_NS->IPR[ _IP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
else
{
return((uint32_t)(((SCB_NS->SHPR[_SHP_IDX(IRQn)] >> _BIT_SHIFT(IRQn) ) & (uint32_t)0xFFUL) >> (8U - __NVIC_PRIO_BITS)));
}
}
#endif /* defined (__ARM_FEATURE_CMSE) &&(__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_NVICFunctions */
/* ########################## MPU functions #################################### */
#if defined (__MPU_PRESENT) && (__MPU_PRESENT == 1U)
#include "mpu_armv8.h"
#endif
/* ########################## FPU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_FpuFunctions FPU Functions
\brief Function that provides FPU type.
@{
*/
/**
\brief get FPU type
\details returns the FPU type
\returns
- \b 0: No FPU
- \b 1: Single precision FPU
- \b 2: Double + Single precision FPU
*/
__STATIC_INLINE uint32_t SCB_GetFPUType(void)
{
return 0U; /* No FPU */
}
/*@} end of CMSIS_Core_FpuFunctions */
/* ########################## SAU functions #################################### */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SAUFunctions SAU Functions
\brief Functions that configure the SAU.
@{
*/
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief Enable SAU
\details Enables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Enable(void)
{
SAU->CTRL |= (SAU_CTRL_ENABLE_Msk);
}
/**
\brief Disable SAU
\details Disables the Security Attribution Unit (SAU).
*/
__STATIC_INLINE void TZ_SAU_Disable(void)
{
SAU->CTRL &= ~(SAU_CTRL_ENABLE_Msk);
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
/*@} end of CMSIS_Core_SAUFunctions */
/* ################################## SysTick function ############################################ */
/**
\ingroup CMSIS_Core_FunctionInterface
\defgroup CMSIS_Core_SysTickFunctions SysTick Functions
\brief Functions that configure the System.
@{
*/
#if defined (__Vendor_SysTickConfig) && (__Vendor_SysTickConfig == 0U)
/**
\brief System Tick Configuration
\details Initializes the System Timer and its interrupt, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>SysTick_Config</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t SysTick_Config(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
NVIC_SetPriority (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U)
/**
\brief System Tick Configuration (non-secure)
\details Initializes the non-secure System Timer and its interrupt when in secure state, and starts the System Tick Timer.
Counter is in free running mode to generate periodic interrupts.
\param [in] ticks Number of ticks between two interrupts.
\return 0 Function succeeded.
\return 1 Function failed.
\note When the variable <b>__Vendor_SysTickConfig</b> is set to 1, then the
function <b>TZ_SysTick_Config_NS</b> is not included. In this case, the file <b><i>device</i>.h</b>
must contain a vendor-specific implementation of this function.
*/
__STATIC_INLINE uint32_t TZ_SysTick_Config_NS(uint32_t ticks)
{
if ((ticks - 1UL) > SysTick_LOAD_RELOAD_Msk)
{
return (1UL); /* Reload value impossible */
}
SysTick_NS->LOAD = (uint32_t)(ticks - 1UL); /* set reload register */
TZ_NVIC_SetPriority_NS (SysTick_IRQn, (1UL << __NVIC_PRIO_BITS) - 1UL); /* set Priority for Systick Interrupt */
SysTick_NS->VAL = 0UL; /* Load the SysTick Counter Value */
SysTick_NS->CTRL = SysTick_CTRL_CLKSOURCE_Msk |
SysTick_CTRL_TICKINT_Msk |
SysTick_CTRL_ENABLE_Msk; /* Enable SysTick IRQ and SysTick Timer */
return (0UL); /* Function successful */
}
#endif /* defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */
#endif
/*@} end of CMSIS_Core_SysTickFunctions */
#ifdef __cplusplus
}
#endif
#endif /* __CORE_ARMV8MBL_H_DEPENDANT */
#endif /* __CMSIS_GENERIC */
| 96,139 | C | 49.020812 | 178 | 0.547239 |
Tbarkin121/GuardDog/stm32/AnymalNet/Drivers/CMSIS/Include/cmsis_compiler.h | /**************************************************************************//**
* @file cmsis_compiler.h
* @brief CMSIS compiler generic header file
* @version V5.1.0
* @date 09. October 2018
******************************************************************************/
/*
* Copyright (c) 2009-2018 Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: Apache-2.0
*
* Licensed under the Apache License, Version 2.0 (the License); you may
* not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef __CMSIS_COMPILER_H
#define __CMSIS_COMPILER_H
#include <stdint.h>
/*
* Arm Compiler 4/5
*/
#if defined ( __CC_ARM )
#include "cmsis_armcc.h"
/*
* Arm Compiler 6.6 LTM (armclang)
*/
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050) && (__ARMCC_VERSION < 6100100)
#include "cmsis_armclang_ltm.h"
/*
* Arm Compiler above 6.10.1 (armclang)
*/
#elif defined (__ARMCC_VERSION) && (__ARMCC_VERSION >= 6100100)
#include "cmsis_armclang.h"
/*
* GNU Compiler
*/
#elif defined ( __GNUC__ )
#include "cmsis_gcc.h"
/*
* IAR Compiler
*/
#elif defined ( __ICCARM__ )
#include <cmsis_iccarm.h>
/*
* TI Arm Compiler
*/
#elif defined ( __TI_ARM__ )
#include <cmsis_ccs.h>
#ifndef __ASM
#define __ASM __asm
#endif
#ifndef __INLINE
#define __INLINE inline
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static inline
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE __STATIC_INLINE
#endif
#ifndef __NO_RETURN
#define __NO_RETURN __attribute__((noreturn))
#endif
#ifndef __USED
#define __USED __attribute__((used))
#endif
#ifndef __WEAK
#define __WEAK __attribute__((weak))
#endif
#ifndef __PACKED
#define __PACKED __attribute__((packed))
#endif
#ifndef __PACKED_STRUCT
#define __PACKED_STRUCT struct __attribute__((packed))
#endif
#ifndef __PACKED_UNION
#define __PACKED_UNION union __attribute__((packed))
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
struct __attribute__((packed)) T_UINT32 { uint32_t v; };
#define __UNALIGNED_UINT32(x) (((struct T_UINT32 *)(x))->v)
#endif
#ifndef __UNALIGNED_UINT16_WRITE
__PACKED_STRUCT T_UINT16_WRITE { uint16_t v; };
#define __UNALIGNED_UINT16_WRITE(addr, val) (void)((((struct T_UINT16_WRITE *)(void*)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT16_READ
__PACKED_STRUCT T_UINT16_READ { uint16_t v; };
#define __UNALIGNED_UINT16_READ(addr) (((const struct T_UINT16_READ *)(const void *)(addr))->v)
#endif
#ifndef __UNALIGNED_UINT32_WRITE
__PACKED_STRUCT T_UINT32_WRITE { uint32_t v; };
#define __UNALIGNED_UINT32_WRITE(addr, val) (void)((((struct T_UINT32_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT32_READ
__PACKED_STRUCT T_UINT32_READ { uint32_t v; };
#define __UNALIGNED_UINT32_READ(addr) (((const struct T_UINT32_READ *)(const void *)(addr))->v)
#endif
#ifndef __ALIGNED
#define __ALIGNED(x) __attribute__((aligned(x)))
#endif
#ifndef __RESTRICT
#define __RESTRICT __restrict
#endif
#ifndef __COMPILER_BARRIER
#warning No compiler specific solution for __COMPILER_BARRIER. __COMPILER_BARRIER is ignored.
#define __COMPILER_BARRIER() (void)0
#endif
/*
* TASKING Compiler
*/
#elif defined ( __TASKING__ )
/*
* The CMSIS functions have been implemented as intrinsics in the compiler.
* Please use "carm -?i" to get an up to date list of all intrinsics,
* Including the CMSIS ones.
*/
#ifndef __ASM
#define __ASM __asm
#endif
#ifndef __INLINE
#define __INLINE inline
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static inline
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE __STATIC_INLINE
#endif
#ifndef __NO_RETURN
#define __NO_RETURN __attribute__((noreturn))
#endif
#ifndef __USED
#define __USED __attribute__((used))
#endif
#ifndef __WEAK
#define __WEAK __attribute__((weak))
#endif
#ifndef __PACKED
#define __PACKED __packed__
#endif
#ifndef __PACKED_STRUCT
#define __PACKED_STRUCT struct __packed__
#endif
#ifndef __PACKED_UNION
#define __PACKED_UNION union __packed__
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
struct __packed__ T_UINT32 { uint32_t v; };
#define __UNALIGNED_UINT32(x) (((struct T_UINT32 *)(x))->v)
#endif
#ifndef __UNALIGNED_UINT16_WRITE
__PACKED_STRUCT T_UINT16_WRITE { uint16_t v; };
#define __UNALIGNED_UINT16_WRITE(addr, val) (void)((((struct T_UINT16_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT16_READ
__PACKED_STRUCT T_UINT16_READ { uint16_t v; };
#define __UNALIGNED_UINT16_READ(addr) (((const struct T_UINT16_READ *)(const void *)(addr))->v)
#endif
#ifndef __UNALIGNED_UINT32_WRITE
__PACKED_STRUCT T_UINT32_WRITE { uint32_t v; };
#define __UNALIGNED_UINT32_WRITE(addr, val) (void)((((struct T_UINT32_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT32_READ
__PACKED_STRUCT T_UINT32_READ { uint32_t v; };
#define __UNALIGNED_UINT32_READ(addr) (((const struct T_UINT32_READ *)(const void *)(addr))->v)
#endif
#ifndef __ALIGNED
#define __ALIGNED(x) __align(x)
#endif
#ifndef __RESTRICT
#warning No compiler specific solution for __RESTRICT. __RESTRICT is ignored.
#define __RESTRICT
#endif
#ifndef __COMPILER_BARRIER
#warning No compiler specific solution for __COMPILER_BARRIER. __COMPILER_BARRIER is ignored.
#define __COMPILER_BARRIER() (void)0
#endif
/*
* COSMIC Compiler
*/
#elif defined ( __CSMC__ )
#include <cmsis_csm.h>
#ifndef __ASM
#define __ASM _asm
#endif
#ifndef __INLINE
#define __INLINE inline
#endif
#ifndef __STATIC_INLINE
#define __STATIC_INLINE static inline
#endif
#ifndef __STATIC_FORCEINLINE
#define __STATIC_FORCEINLINE __STATIC_INLINE
#endif
#ifndef __NO_RETURN
// NO RETURN is automatically detected hence no warning here
#define __NO_RETURN
#endif
#ifndef __USED
#warning No compiler specific solution for __USED. __USED is ignored.
#define __USED
#endif
#ifndef __WEAK
#define __WEAK __weak
#endif
#ifndef __PACKED
#define __PACKED @packed
#endif
#ifndef __PACKED_STRUCT
#define __PACKED_STRUCT @packed struct
#endif
#ifndef __PACKED_UNION
#define __PACKED_UNION @packed union
#endif
#ifndef __UNALIGNED_UINT32 /* deprecated */
@packed struct T_UINT32 { uint32_t v; };
#define __UNALIGNED_UINT32(x) (((struct T_UINT32 *)(x))->v)
#endif
#ifndef __UNALIGNED_UINT16_WRITE
__PACKED_STRUCT T_UINT16_WRITE { uint16_t v; };
#define __UNALIGNED_UINT16_WRITE(addr, val) (void)((((struct T_UINT16_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT16_READ
__PACKED_STRUCT T_UINT16_READ { uint16_t v; };
#define __UNALIGNED_UINT16_READ(addr) (((const struct T_UINT16_READ *)(const void *)(addr))->v)
#endif
#ifndef __UNALIGNED_UINT32_WRITE
__PACKED_STRUCT T_UINT32_WRITE { uint32_t v; };
#define __UNALIGNED_UINT32_WRITE(addr, val) (void)((((struct T_UINT32_WRITE *)(void *)(addr))->v) = (val))
#endif
#ifndef __UNALIGNED_UINT32_READ
__PACKED_STRUCT T_UINT32_READ { uint32_t v; };
#define __UNALIGNED_UINT32_READ(addr) (((const struct T_UINT32_READ *)(const void *)(addr))->v)
#endif
#ifndef __ALIGNED
#warning No compiler specific solution for __ALIGNED. __ALIGNED is ignored.
#define __ALIGNED(x)
#endif
#ifndef __RESTRICT
#warning No compiler specific solution for __RESTRICT. __RESTRICT is ignored.
#define __RESTRICT
#endif
#ifndef __COMPILER_BARRIER
#warning No compiler specific solution for __COMPILER_BARRIER. __COMPILER_BARRIER is ignored.
#define __COMPILER_BARRIER() (void)0
#endif
#else
#error Unknown compiler.
#endif
#endif /* __CMSIS_COMPILER_H */
| 9,481 | C | 32.387324 | 113 | 0.559224 |
teerameth/omni.isaac.fiborobotlab/config/extension.toml | [core]
reloadable = true
order = 0
[package]
version = "0.1.1"
category = "Simulation"
title = "Isaac Sim fiborobotlab"
description = "fiborobotlab package for Isaac Sim"
authors = ["NVIDIA"]
repository = ""
keywords = ["isaac", "urdf", "import"]
changelog = "docs/CHANGELOG.md"
readme = "docs/README.md"
preview_image = "data/preview.png"
icon = "data/icon.png"
writeTarget.kit = true
[dependencies]
"omni.isaac.urdf" = {}
[[python.module]]
name = "omni.isaac.fiborobotlab"
#[[python.module]]
#name = "omni.isaac.fiborobotlab.mooncake"
[[python.module]]
name = "omni.isaac.fiborobotlab.mooncake.scripts.import_mooncake"
[[python.module]]
name = "omni.isaac.fiborobotlab.obike.scripts.import_obike"
[[python.module]]
name = "omni.isaac.fiborobotlab.taufinder.scripts.import_taufinder"
[[python.module]]
name = "omni.isaac.fiborobotlab.hello_world_extension"
[[python.module]]
name = "omni.isaac.fiborobotlab.hello_world"
[[python.module]]
name = "omni.isaac.fiborobotlab.hanuman.scripts.import_hanuman"
[[native.plugin]]
path = "bin/*.plugin"
recursive = false
[[test]]
# this is to catch issues where our assimp is out of sync with the one that comes with
# asset importer as this can cause segfaults due to binary incompatibility.
dependencies = ["omni.kit.tool.asset_importer"]
| 1,297 | TOML | 22.6 | 87 | 0.730918 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/hello_world.py | # Copyright (c) 2020-2021, NVIDIA CORPORATION. All rights reserved.
#
# NVIDIA CORPORATION and its licensors retain all intellectual property
# and proprietary rights in and to this software, related documentation
# and any modifications thereto. Any use, reproduction, disclosure or
# distribution of this software and related documentation without an express
# license agreement from NVIDIA CORPORATION is strictly prohibited.
from omni.isaac.examples.base_sample import BaseSample
# Note: checkout the required tutorials at https://docs.omniverse.nvidia.com/app_isaacsim/app_isaacsim/overview.html
class HelloWorld(BaseSample):
def __init__(self) -> None:
super().__init__()
return
def setup_scene(self):
world = self.get_world()
world.scene.add_default_ground_plane()
return
async def setup_post_load(self):
return
async def setup_pre_reset(self):
return
async def setup_post_reset(self):
return
def world_cleanup(self):
return
| 1,040 | Python | 27.916666 | 116 | 0.708654 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/hello_world_extension.py | # Copyright (c) 2020-2021, NVIDIA CORPORATION. All rights reserved.
#
# NVIDIA CORPORATION and its licensors retain all intellectual property
# and proprietary rights in and to this software, related documentation
# and any modifications thereto. Any use, reproduction, disclosure or
# distribution of this software and related documentation without an express
# license agreement from NVIDIA CORPORATION is strictly prohibited.
import os
from omni.isaac.examples.base_sample import BaseSampleExtension
from omni.isaac.examples.hello_world import HelloWorld
class HelloWorldExtension(BaseSampleExtension):
def on_startup(self, ext_id: str):
super().on_startup(ext_id)
super().start_extension(
menu_name="",
submenu_name="",
name="Hello Mooncake",
title="Hello Mooncake Title",
doc_link="",
overview="",
file_path=os.path.abspath(__file__),
sample=HelloWorld(),
)
return
| 1,007 | Python | 34.999999 | 76 | 0.682224 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/rlgames_train.py | from omniisaacgymenvs.utils.hydra_cfg.hydra_utils import *
from omniisaacgymenvs.utils.hydra_cfg.reformat import omegaconf_to_dict, print_dict
from omniisaacgymenvs.utils.rlgames.rlgames_utils import RLGPUAlgoObserver, RLGPUEnv
from omniisaacgymenvs.utils.config_utils.path_utils import retrieve_checkpoint_path
from omniisaacgymenvs.envs.vec_env_rlgames import VecEnvRLGames
import hydra
from omegaconf import DictConfig
from rl_games.common import env_configurations, vecenv
from rl_games.torch_runner import Runner
import os
class RLGTrainer():
def __init__(self, cfg, cfg_dict):
self.cfg = cfg
self.cfg_dict = cfg_dict
def launch_rlg_hydra(self, env):
# `create_rlgpu_env` is environment construction function which is passed to RL Games and called internally.
# We use the helper function here to specify the environment config.
self.cfg_dict["task"]["test"] = self.cfg.test
# register the rl-games adapter to use inside the runner
vecenv.register('RLGPU',
lambda config_name, num_actors, **kwargs: RLGPUEnv(config_name, num_actors, **kwargs))
env_configurations.register('rlgpu', {
'vecenv_type': 'RLGPU',
'env_creator': lambda **kwargs: env
})
self.rlg_config_dict = omegaconf_to_dict(self.cfg.train)
def run(self):
# create runner and set the settings
runner = Runner(RLGPUAlgoObserver())
runner.load(self.rlg_config_dict)
runner.reset()
# dump config dict
experiment_dir = os.path.join('runs', self.cfg.train.params.config.name)
os.makedirs(experiment_dir, exist_ok=True)
with open(os.path.join(experiment_dir, 'config.yaml'), 'w') as f:
f.write(OmegaConf.to_yaml(self.cfg))
runner.run({
'train': not self.cfg.test,
'play': self.cfg.test,
'checkpoint': self.cfg.checkpoint,
'sigma': None
})
@hydra.main(config_name="config", config_path="./cfg")
def parse_hydra_configs(cfg: DictConfig):
# ensure checkpoints can be specified as relative paths
if cfg.checkpoint:
cfg.checkpoint = retrieve_checkpoint_path(cfg.checkpoint)
if cfg.checkpoint is None:
quit()
cfg_dict = omegaconf_to_dict(cfg)
print_dict(cfg_dict)
headless = cfg.headless
env = VecEnvRLGames(headless=headless)
from scripts.sim_config import SimConfig
sim_config = SimConfig(cfg_dict)
cfg = DictConfig(sim_config.config)
from cartpole_task import CartpoleTask
task = CartpoleTask(name="Cartpole",
sim_config=sim_config,
env=env
)
env.set_task(task=task, sim_params=sim_config.get_physics_params(), backend="torch", init_sim=True)
# task = initialize_task(cfg_dict, env)
print(cfg)
# sets seed. if seed is -1 will pick a random one
from omni.isaac.core.utils.torch.maths import set_seed
cfg.seed = set_seed(cfg.seed, torch_deterministic=cfg.torch_deterministic)
rlg_trainer = RLGTrainer(cfg, cfg_dict)
rlg_trainer.launch_rlg_hydra(env)
rlg_trainer.run()
env.close()
if __name__ == '__main__':
parse_hydra_configs()
| 3,258 | Python | 31.919192 | 116 | 0.657766 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/cartpole.py | # Copyright (c) 2018-2022, NVIDIA Corporation
# All rights reserved.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions are met:
#
# 1. Redistributions of source code must retain the above copyright notice, this
# list of conditions and the following disclaimer.
#
# 2. Redistributions in binary form must reproduce the above copyright notice,
# this list of conditions and the following disclaimer in the documentation
# and/or other materials provided with the distribution.
#
# 3. Neither the name of the copyright holder nor the names of its
# contributors may be used to endorse or promote products derived from
# this software without specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
# AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
# IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
# DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
# FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
# DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
# SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
# CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
# OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
from typing import Optional
import numpy as np
import torch
from omni.isaac.core.robots.robot import Robot
from omni.isaac.core.utils.nucleus import get_assets_root_path
from omni.isaac.core.utils.stage import add_reference_to_stage
import carb
class Cartpole(Robot):
def __init__(
self,
prim_path: str,
name: Optional[str] = "Cartpole",
usd_path: Optional[str] = None,
translation: Optional[np.ndarray] = None,
orientation: Optional[np.ndarray] = None,
) -> None:
self._usd_path = usd_path
self._name = name
if self._usd_path is None:
assets_root_path = get_assets_root_path()
if assets_root_path is None:
carb.log_error("Could not find Isaac Sim assets folder")
self._usd_path = assets_root_path + "/Isaac/Robots/Cartpole/cartpole.usd"
add_reference_to_stage(self._usd_path, prim_path)
super().__init__(
prim_path=prim_path,
name=name,
translation=translation,
orientation=orientation,
articulation_controller=None,
)
| 2,702 | Python | 39.343283 | 85 | 0.710585 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/cartpole_task.py | from omniisaacgymenvs.tasks.base.rl_task import RLTask
from cartpole import Cartpole
from omni.isaac.core.articulations import ArticulationView
from omni.isaac.core.utils.prims import get_prim_at_path
import numpy as np
import torch
import math
class CartpoleTask(RLTask):
def __init__(
self,
name,
sim_config,
env,
offset=None
) -> None:
self._sim_config = sim_config
self._cfg = sim_config.config
self._task_cfg = sim_config.task_config
self._num_envs = self._task_cfg["env"]["numEnvs"]
self._env_spacing = self._task_cfg["env"]["envSpacing"]
self._cartpole_positions = torch.tensor([0.0, 0.0, 2.0])
self._reset_dist = self._task_cfg["env"]["resetDist"]
self._max_push_effort = self._task_cfg["env"]["maxEffort"]
self._max_episode_length = 500
self._num_observations = 2
self._num_actions = 1
RLTask.__init__(self, name, env)
return
def set_up_scene(self, scene) -> None:
self.get_cartpole()
super().set_up_scene(scene)
self._cartpoles = ArticulationView(prim_paths_expr="/World/envs/.*/Cartpole", name="cartpole_view")
scene.add(self._cartpoles)
return
def get_cartpole(self):
cartpole = Cartpole(prim_path=self.default_zero_env_path + "/Cartpole", name="Cartpole", translation=self._cartpole_positions)
# applies articulation settings from the task configuration yaml file
self._sim_config.apply_articulation_settings("Cartpole", get_prim_at_path(cartpole.prim_path), self._sim_config.parse_actor_config("Cartpole"))
def get_observations(self) -> dict:
dof_pos = self._cartpoles.get_joint_positions(clone=False)
dof_vel = self._cartpoles.get_joint_velocities(clone=False)
cart_pos = dof_pos[:, self._cart_dof_idx]
cart_vel = dof_vel[:, self._cart_dof_idx]
pole_pos = dof_pos[:, self._pole_dof_idx]
pole_vel = dof_vel[:, self._pole_dof_idx]
# self.obs_buf[:, 0] = cart_pos
# self.obs_buf[:, 1] = cart_vel
# self.obs_buf[:, 2] = pole_pos
# self.obs_buf[:, 3] = pole_vel
self.obs_buf[:, 0] = cart_pos
self.obs_buf[:, 1] = pole_pos
observations = {
self._cartpoles.name: {
"obs_buf": self.obs_buf
}
}
return observations
def pre_physics_step(self, actions) -> None:
reset_env_ids = self.reset_buf.nonzero(as_tuple=False).squeeze(-1)
if len(reset_env_ids) > 0:
self.reset_idx(reset_env_ids)
actions = actions.to(self._device)
forces = torch.zeros((self._cartpoles.count, self._cartpoles.num_dof), dtype=torch.float32, device=self._device)
forces[:, self._cart_dof_idx] = self._max_push_effort * actions[:, 0]
indices = torch.arange(self._cartpoles.count, dtype=torch.int32, device=self._device)
self._cartpoles.set_joint_efforts(forces, indices=indices)
def reset_idx(self, env_ids):
num_resets = len(env_ids)
# randomize DOF positions
dof_pos = torch.zeros((num_resets, self._cartpoles.num_dof), device=self._device)
dof_pos[:, self._cart_dof_idx] = 1.0 * (1.0 - 2.0 * torch.rand(num_resets, device=self._device))
dof_pos[:, self._pole_dof_idx] = 0.125 * math.pi * (1.0 - 2.0 * torch.rand(num_resets, device=self._device))
# randomize DOF velocities
dof_vel = torch.zeros((num_resets, self._cartpoles.num_dof), device=self._device)
dof_vel[:, self._cart_dof_idx] = 0.5 * (1.0 - 2.0 * torch.rand(num_resets, device=self._device))
dof_vel[:, self._pole_dof_idx] = 0.25 * math.pi * (1.0 - 2.0 * torch.rand(num_resets, device=self._device))
# apply resets
indices = env_ids.to(dtype=torch.int32)
self._cartpoles.set_joint_positions(dof_pos, indices=indices)
self._cartpoles.set_joint_velocities(dof_vel, indices=indices)
# bookkeeping
self.reset_buf[env_ids] = 0
self.progress_buf[env_ids] = 0
def post_reset(self):
self._cart_dof_idx = self._cartpoles.get_dof_index("cartJoint")
self._pole_dof_idx = self._cartpoles.get_dof_index("poleJoint")
# randomize all envs
indices = torch.arange(self._cartpoles.count, dtype=torch.int64, device=self._device)
self.reset_idx(indices)
def calculate_metrics(self) -> None:
dof_pos = self._cartpoles.get_joint_positions(clone=False)
dof_vel = self._cartpoles.get_joint_velocities(clone=False)
cart_pos = dof_pos[:, self._cart_dof_idx]
cart_vel = dof_vel[:, self._cart_dof_idx]
pole_angle = dof_pos[:, self._pole_dof_idx]
pole_vel = dof_vel[:, self._pole_dof_idx]
reward = 1.0 - pole_angle * pole_angle - 0.01 * torch.abs(cart_vel) - 0.005 * torch.abs(pole_vel)
reward = torch.where(torch.abs(cart_pos) > self._reset_dist, torch.ones_like(reward) * -2.0, reward)
reward = torch.where(torch.abs(pole_angle) > np.pi / 2, torch.ones_like(reward) * -2.0, reward)
self.rew_buf[:] = reward
def is_done(self) -> None:
dof_pos = self._cartpoles.get_joint_positions(clone=False)
cart_pos = dof_pos[:, self._cart_dof_idx]
pole_pos = dof_pos[:, self._pole_dof_idx]
resets = torch.where(torch.abs(cart_pos) > self._reset_dist, 1, 0)
resets = torch.where(torch.abs(pole_pos) > math.pi / 2, 1, resets)
resets = torch.where(self.progress_buf >= self._max_episode_length, 1, resets)
self.reset_buf[:] = resets
| 5,640 | Python | 38.725352 | 151 | 0.611348 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/cartpole_example.py | #!/usr/bin/env -S HOME=${HOME} ${HOME}/.local/share/ov/pkg/isaac_sim-2022.1.0/python.sh
from omni.isaac.gym.vec_env import VecEnvBase
env = VecEnvBase(headless=False)
from cartpole_task import CartpoleTask
task = CartpoleTask(name="Cartpole")
env.set_task(task, backend="torch")
from stable_baselines3 import PPO
# create agent from stable baselines
model = PPO(
"MlpPolicy",
env,
n_steps=1000,
batch_size=1000,
n_epochs=20,
learning_rate=0.001,
gamma=0.99,
device="cuda:0",
ent_coef=0.0,
vf_coef=0.5,
max_grad_norm=1.0,
verbose=1,
tensorboard_log="./cartpole_tensorboard"
)
model.learn(total_timesteps=100000)
model.save("ppo_cartpole")
env.close() | 757 | Python | 24.266666 | 87 | 0.642008 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/cfg/config.yaml |
# Task name - used to pick the class to load
task_name: ${task.name}
# experiment name. defaults to name of training config
experiment: ''
# if set to positive integer, overrides the default number of environments
num_envs: ''
# seed - set to -1 to choose random seed
seed: 42
# set to True for deterministic performance
torch_deterministic: False
# set the maximum number of learning iterations to train for. overrides default per-environment setting
max_iterations: ''
## Device config
physics_engine: 'physx'
# whether to use cpu or gpu pipeline
pipeline: 'gpu'
# whether to use cpu or gpu physx
sim_device: 'gpu'
# used for gpu pipeline only - device id for running sim and task
device_id: 0
# device to run RL
rl_device: 'cuda:0'
## PhysX arguments
num_threads: 8 # Number of worker threads per scene used by PhysX - for CPU PhysX only.
solver_type: 1 # 0: pgs, 1: tgs
# RLGames Arguments
# test - if set, run policy in inference mode (requires setting checkpoint to load)
test: False
# used to set checkpoint path
checkpoint: ''
# disables rendering
headless: False
# set default task and default training config based on task
defaults:
- task: Cartpole
- train: ${task}PPO
- hydra/job_logging: disabled
# set the directory where the output files get saved
hydra:
output_subdir: null
run:
dir: .
| 1,327 | YAML | 23.592592 | 103 | 0.736247 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/cfg/task/Cartpole.yaml | # used to create the object
name: Cartpole
physics_engine: ${..physics_engine}
# if given, will override the device setting in gym.
env:
numEnvs: ${resolve_default:256,${...num_envs}}
envSpacing: 4.0
resetDist: 3.0
maxEffort: 400.0
clipObservations: 5.0
clipActions: 1.0
controlFrequencyInv: 2 # 60 Hz
sim:
dt: 0.0083 # 1/120 s
use_gpu_pipeline: ${eq:${...pipeline},"gpu"}
gravity: [0.0, 0.0, -9.81]
add_ground_plane: True
add_distant_light: True
use_flatcache: True
enable_scene_query_support: False
default_physics_material:
static_friction: 1.0
dynamic_friction: 1.0
restitution: 0.0
physx:
worker_thread_count: ${....num_threads}
solver_type: ${....solver_type}
use_gpu: ${eq:${....sim_device},"gpu"} # set to False to run on CPU
solver_position_iteration_count: 4
solver_velocity_iteration_count: 0
contact_offset: 0.02
rest_offset: 0.001
bounce_threshold_velocity: 0.2
friction_offset_threshold: 0.04
friction_correlation_distance: 0.025
enable_sleeping: True
enable_stabilization: True
max_depenetration_velocity: 100.0
# GPU buffers
gpu_max_rigid_contact_count: 524288
gpu_max_rigid_patch_count: 81920
gpu_found_lost_pairs_capacity: 1024
gpu_found_lost_aggregate_pairs_capacity: 262144
gpu_total_aggregate_pairs_capacity: 1024
gpu_max_soft_body_contacts: 1048576
gpu_max_particle_contacts: 1048576
gpu_heap_capacity: 67108864
gpu_temp_buffer_capacity: 16777216
gpu_max_num_partitions: 8
Cartpole:
# -1 to use default values
override_usd_defaults: False
fixed_base: False
enable_self_collisions: False
enable_gyroscopic_forces: True
# also in stage params
# per-actor
solver_position_iteration_count: 4
solver_velocity_iteration_count: 0
sleep_threshold: 0.005
stabilization_threshold: 0.001
# per-body
density: -1
max_depenetration_velocity: 100.0
# per-shape
contact_offset: 0.02
rest_offset: 0.001 | 2,026 | YAML | 26.026666 | 71 | 0.682132 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/cfg/train/CartpolePPO.yaml | params:
seed: ${...seed}
algo:
name: a2c_continuous
model:
name: continuous_a2c_logstd
network:
name: actor_critic
separate: False
space:
continuous:
mu_activation: None
sigma_activation: None
mu_init:
name: default
sigma_init:
name: const_initializer
val: 0
fixed_sigma: True
mlp:
units: [32, 32]
activation: elu
initializer:
name: default
regularizer:
name: None
rnn:
name: 'lstm'
units: 32
layers: 1
before_mlp: False
concat_input: True
layer_norm: True
load_checkpoint: ${if:${...checkpoint},True,False} # flag which sets whether to load the checkpoint
load_path: ${...checkpoint} # path to the checkpoint to load
config:
name: ${resolve_default:Cartpole,${....experiment}}
full_experiment_name: ${.name}
device: ${....rl_device}
device_name: ${....rl_device}
env_name: rlgpu
ppo: True
mixed_precision: False
normalize_input: True
normalize_value: True
num_actors: ${....task.env.numEnvs}
reward_shaper:
scale_value: 0.1
normalize_advantage: True
gamma: 0.99
tau: 0.95
learning_rate: 3e-4
lr_schedule: adaptive
kl_threshold: 0.008
score_to_win: 20000
max_epochs: ${resolve_default:1000,${....max_iterations}}
save_best_after: 50
save_frequency: 25
grad_norm: 1.0
entropy_coef: 0.0
truncate_grads: True
e_clip: 0.2
horizon_length: 16
minibatch_size: 2048
mini_epochs: 8
critic_coef: 4
clip_value: True
seq_len: 4
bounds_loss_coef: 0.0001 | 1,681 | YAML | 21.131579 | 101 | 0.587745 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/cartpole/scripts/sim_config.py | from omniisaacgymenvs.utils.config_utils.default_scene_params import *
import copy
import omni.usd
class SimConfig():
def __init__(self, config: dict = None):
if config is None:
config = dict()
self._config = config
self._cfg = config.get("task", dict())
self._parse_config()
if self._config["test"] == True:
self._sim_params["enable_scene_query_support"] = True
def _parse_config(self):
# general sim parameter
self._sim_params = copy.deepcopy(default_sim_params)
self._default_physics_material = copy.deepcopy(default_physics_material)
sim_cfg = self._cfg.get("sim", None)
if sim_cfg is not None:
for opt in sim_cfg.keys():
if opt in self._sim_params:
if opt == "default_physics_material":
for material_opt in sim_cfg[opt]:
self._default_physics_material[material_opt] = sim_cfg[opt][material_opt]
else:
self._sim_params[opt] = sim_cfg[opt]
else:
print("Sim params does not have attribute: ", opt)
self._sim_params["default_physics_material"] = self._default_physics_material
# physx parameters
self._physx_params = copy.deepcopy(default_physx_params)
if sim_cfg is not None and "physx" in sim_cfg:
for opt in sim_cfg["physx"].keys():
if opt in self._physx_params:
self._physx_params[opt] = sim_cfg["physx"][opt]
else:
print("Physx sim params does not have attribute: ", opt)
self._sanitize_device()
def _sanitize_device(self):
if self._sim_params["use_gpu_pipeline"]:
self._physx_params["use_gpu"] = True
# device should be in sync with pipeline
if self._sim_params["use_gpu_pipeline"]:
self._config["sim_device"] = f"cuda:{self._config['device_id']}"
else:
self._config["sim_device"] = "cpu"
# also write to physics params for setting sim device
self._physx_params["sim_device"] = self._config["sim_device"]
print("Pipeline: ", "GPU" if self._sim_params["use_gpu_pipeline"] else "CPU")
print("Pipeline Device: ", self._config["sim_device"])
print("Sim Device: ", "GPU" if self._physx_params["use_gpu"] else "CPU")
def parse_actor_config(self, actor_name):
actor_params = copy.deepcopy(default_actor_options)
if "sim" in self._cfg and actor_name in self._cfg["sim"]:
actor_cfg = self._cfg["sim"][actor_name]
for opt in actor_cfg.keys():
if actor_cfg[opt] != -1 and opt in actor_params:
actor_params[opt] = actor_cfg[opt]
elif opt not in actor_params:
print("Actor params does not have attribute: ", opt)
return actor_params
def _get_actor_config_value(self, actor_name, attribute_name, attribute=None):
actor_params = self.parse_actor_config(actor_name)
if attribute is not None:
if attribute_name not in actor_params:
return attribute.Get()
if actor_params[attribute_name] != -1:
return actor_params[attribute_name]
elif actor_params["override_usd_defaults"] and not attribute.IsAuthored():
return self._physx_params[attribute_name]
else:
if actor_params[attribute_name] != -1:
return actor_params[attribute_name]
@property
def sim_params(self):
return self._sim_params
@property
def config(self):
return self._config
@property
def task_config(self):
return self._cfg
@property
def physx_params(self):
return self._physx_params
def get_physics_params(self):
return {**self.sim_params, **self.physx_params}
def _get_physx_collision_api(self, prim):
from pxr import UsdPhysics, PhysxSchema
physx_collision_api = PhysxSchema.PhysxCollisionAPI(prim)
if not physx_collision_api:
physx_collision_api = PhysxSchema.PhysxCollisionAPI.Apply(prim)
return physx_collision_api
def _get_physx_rigid_body_api(self, prim):
from pxr import UsdPhysics, PhysxSchema
physx_rb_api = PhysxSchema.PhysxRigidBodyAPI(prim)
if not physx_rb_api:
physx_rb_api = PhysxSchema.PhysxRigidBodyAPI.Apply(prim)
return physx_rb_api
def _get_physx_articulation_api(self, prim):
from pxr import UsdPhysics, PhysxSchema
arti_api = PhysxSchema.PhysxArticulationAPI(prim)
if not arti_api:
arti_api = PhysxSchema.PhysxArticulationAPI.Apply(prim)
return arti_api
def set_contact_offset(self, name, prim, value=None):
physx_collision_api = self._get_physx_collision_api(prim)
contact_offset = physx_collision_api.GetContactOffsetAttr()
# if not contact_offset:
# contact_offset = physx_collision_api.CreateContactOffsetAttr()
if value is None:
value = self._get_actor_config_value(name, "contact_offset", contact_offset)
if value != -1:
contact_offset.Set(value)
def set_rest_offset(self, name, prim, value=None):
physx_collision_api = self._get_physx_collision_api(prim)
rest_offset = physx_collision_api.GetRestOffsetAttr()
# if not rest_offset:
# rest_offset = physx_collision_api.CreateRestOffsetAttr()
if value is None:
value = self._get_actor_config_value(name, "rest_offset", rest_offset)
if value != -1:
rest_offset.Set(value)
def set_position_iteration(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
solver_position_iteration_count = physx_rb_api.GetSolverPositionIterationCountAttr()
if value is None:
value = self._get_actor_config_value(name, "solver_position_iteration_count", solver_position_iteration_count)
if value != -1:
solver_position_iteration_count.Set(value)
def set_velocity_iteration(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
solver_velocity_iteration_count = physx_rb_api.GetSolverVelocityIterationCountAttr()
if value is None:
value = self._get_actor_config_value(name, "solver_velocity_iteration_count", solver_position_iteration_count)
if value != -1:
solver_velocity_iteration_count.Set(value)
def set_max_depenetration_velocity(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
max_depenetration_velocity = physx_rb_api.GetMaxDepenetrationVelocityAttr()
if value is None:
value = self._get_actor_config_value(name, "max_depenetration_velocity", max_depenetration_velocity)
if value != -1:
max_depenetration_velocity.Set(value)
def set_sleep_threshold(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
sleep_threshold = physx_rb_api.GetSleepThresholdAttr()
if value is None:
value = self._get_actor_config_value(name, "sleep_threshold", sleep_threshold)
if value != -1:
sleep_threshold.Set(value)
def set_stabilization_threshold(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
stabilization_threshold = physx_rb_api.GetStabilizationThresholdAttr()
if value is None:
value = self._get_actor_config_value(name, "stabilization_threshold", stabilization_threshold)
if value != -1:
stabilization_threshold.Set(value)
def set_gyroscopic_forces(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
enable_gyroscopic_forces = physx_rb_api.GetEnableGyroscopicForcesAttr()
if value is None:
value = self._get_actor_config_value(name, "enable_gyroscopic_forces", enable_gyroscopic_forces)
if value != -1:
enable_gyroscopic_forces.Set(value)
def set_density(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
density = physx_rb_api.GetDensityAttr()
if value is None:
value = self._get_actor_config_value(name, "density", density)
if value != -1:
density.Set(value)
# auto-compute mass
self.set_mass(prim, 0.0)
def set_mass(self, name, prim, value=None):
physx_rb_api = self._get_physx_rigid_body_api(prim)
mass = physx_rb_api.GetMassAttr()
if value is None:
value = self._get_actor_config_value(name, "mass", mass)
if value != -1:
mass.Set(value)
def retain_acceleration(self, prim):
# retain accelerations if running with more than one substep
physx_rb_api = self._get_physx_rigid_body_api(prim)
if self._sim_params["substeps"] > 1:
physx_rb_api.GetRetainAccelerationsAttr().Set(True)
def add_fixed_base(self, name, prim, cfg, value=None):
from pxr import UsdPhysics, PhysxSchema
stage = omni.usd.get_context().get_stage()
if value is None:
value = self._get_actor_config_value(name, "fixed_base")
if value:
root_joint_path = f"{prim.GetPath()}_fixedBaseRootJoint"
joint = UsdPhysics.Joint.Define(stage, root_joint_path)
joint.CreateBody1Rel().SetTargets([prim.GetPath()])
self.apply_articulation_settings(name, joint.GetPrim(), cfg, force_articulation=True)
def set_articulation_position_iteration(self, name, prim, value=None):
arti_api = self._get_physx_articulation_api(prim)
solver_position_iteration_count = arti_api.GetSolverPositionIterationCountAttr()
if value is None:
value = self._get_actor_config_value(name, "solver_position_iteration_count", solver_position_iteration_count)
if value != -1:
solver_position_iteration_count.Set(value)
def set_articulation_velocity_iteration(self, name, prim, value=None):
arti_api = self._get_physx_articulation_api(prim)
solver_velocity_iteration_count = arti_api.GetSolverVelocityIterationCountAttr()
if value is None:
value = self._get_actor_config_value(name, "solver_velocity_iteration_count", solver_position_iteration_count)
if value != -1:
solver_velocity_iteration_count.Set(value)
def set_articulation_sleep_threshold(self, name, prim, value=None):
arti_api = self._get_physx_articulation_api(prim)
sleep_threshold = arti_api.GetSleepThresholdAttr()
if value is None:
value = self._get_actor_config_value(name, "sleep_threshold", sleep_threshold)
if value != -1:
sleep_threshold.Set(value)
def set_articulation_stabilization_threshold(self, name, prim, value=None):
arti_api = self._get_physx_articulation_api(prim)
stabilization_threshold = arti_api.GetStabilizationThresholdAttr()
if value is None:
value = self._get_actor_config_value(name, "stabilization_threshold", stabilization_threshold)
if value != -1:
stabilization_threshold.Set(value)
def apply_rigid_body_settings(self, name, prim, cfg, is_articulation):
from pxr import UsdPhysics, PhysxSchema
stage = omni.usd.get_context().get_stage()
rb_api = UsdPhysics.RigidBodyAPI.Get(stage, prim.GetPath())
physx_rb_api = PhysxSchema.PhysxRigidBodyAPI.Get(stage, prim.GetPath())
if not physx_rb_api:
physx_rb_api = PhysxSchema.PhysxRigidBodyAPI.Apply(prim)
# if it's a body in an articulation, it's handled at articulation root
if not is_articulation:
self.add_fixed_base(name, prim, cfg, cfg["fixed_base"])
self.set_position_iteration(name, prim, cfg["solver_position_iteration_count"])
self.set_velocity_iteration(name, prim, cfg["solver_velocity_iteration_count"])
self.set_max_depenetration_velocity(name, prim, cfg["max_depenetration_velocity"])
self.set_sleep_threshold(name, prim, cfg["sleep_threshold"])
self.set_stabilization_threshold(name, prim, cfg["stabilization_threshold"])
self.set_gyroscopic_forces(name, prim, cfg["enable_gyroscopic_forces"])
# density and mass
mass_api = UsdPhysics.MassAPI.Get(stage, prim.GetPath())
if mass_api is None:
mass_api = UsdPhysics.MassAPI.Apply(prim)
mass_attr = mass_api.GetMassAttr()
density_attr = mass_api.GetDensityAttr()
if not mass_attr:
mass_attr = mass_api.CreateMassAttr()
if not density_attr:
density_attr = mass_api.CreateDensityAttr()
if cfg["density"] != -1:
density_attr.Set(cfg["density"])
mass_attr.Set(0.0) # mass is to be computed
elif cfg["override_usd_defaults"] and not density_attr.IsAuthored() and not mass_attr.IsAuthored():
density_attr.Set(self._physx_params["density"])
self.retain_acceleration(prim)
def apply_rigid_shape_settings(self, name, prim, cfg):
from pxr import UsdPhysics, PhysxSchema
stage = omni.usd.get_context().get_stage()
# collision APIs
collision_api = UsdPhysics.CollisionAPI(prim)
if not collision_api:
collision_api = UsdPhysics.CollisionAPI.Apply(prim)
physx_collision_api = PhysxSchema.PhysxCollisionAPI(prim)
if not physx_collision_api:
physx_collision_api = PhysxSchema.PhysxCollisionAPI.Apply(prim)
self.set_contact_offset(name, prim, cfg["contact_offset"])
self.set_rest_offset(name, prim, cfg["rest_offset"])
def apply_articulation_settings(self, name, prim, cfg, force_articulation=False):
from pxr import UsdPhysics, PhysxSchema
stage = omni.usd.get_context().get_stage()
is_articulation = False
# check if is articulation
prims = [prim]
while len(prims) > 0:
prim = prims.pop(0)
articulation_api = UsdPhysics.ArticulationRootAPI.Get(stage, prim.GetPath())
physx_articulation_api = PhysxSchema.PhysxArticulationAPI.Get(stage, prim.GetPath())
if articulation_api or physx_articulation_api:
is_articulation = True
if not is_articulation and force_articulation:
articulation_api = UsdPhysics.ArticulationRootAPI.Apply(prim)
physx_articulation_api = PhysxSchema.PhysxArticulationAPI.Apply(prim)
# parse through all children prims
prims = [prim]
while len(prims) > 0:
prim = prims.pop(0)
rb = UsdPhysics.RigidBodyAPI(prim)
collision_body = UsdPhysics.CollisionAPI(prim)
articulation = UsdPhysics.ArticulationRootAPI(prim)
if rb:
self.apply_rigid_body_settings(name, prim, cfg, is_articulation)
if collision_body:
self.apply_rigid_shape_settings(name, prim, cfg)
if articulation:
articulation_api = UsdPhysics.ArticulationRootAPI.Get(stage, prim.GetPath())
physx_articulation_api = PhysxSchema.PhysxArticulationAPI.Get(stage, prim.GetPath())
# enable self collisions
enable_self_collisions = physx_articulation_api.GetEnabledSelfCollisionsAttr()
if cfg["enable_self_collisions"] != -1:
enable_self_collisions.Set(cfg["enable_self_collisions"])
if not force_articulation:
self.add_fixed_base(name, prim, cfg, cfg["fixed_base"])
self.set_articulation_position_iteration(name, prim, cfg["solver_position_iteration_count"])
self.set_articulation_velocity_iteration(name, prim, cfg["solver_velocity_iteration_count"])
self.set_articulation_sleep_threshold(name, prim, cfg["sleep_threshold"])
self.set_articulation_stabilization_threshold(name, prim, cfg["stabilization_threshold"])
children_prims = prim.GetPrim().GetChildren()
prims = prims + children_prims
| 16,516 | Python | 43.761517 | 122 | 0.626181 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/mooncake/train_ppo.py | from env import MoonCakeEnv
import gym
from stable_baselines3 import PPO
from stable_baselines3.common.env_util import make_vec_env
my_env = MoonCakeEnv(headless=False)
# Parallel environments
# env = make_vec_env("CartPole-v1", n_envs=4)
model = PPO("MlpPolicy", my_env, verbose=1)
model.learn(total_timesteps=25000)
model.save("ppo_cartpole")
#
# del model # remove to demonstrate saving and loading
#
# model = PPO.load("ppo_cartpole")
#
# obs = env.reset()
# while True:
# action, _states = model.predict(obs)
# obs, rewards, dones, info = env.step(action)
# env.render() | 589 | Python | 25.818181 | 58 | 0.716469 |
teerameth/omni.isaac.fiborobotlab/omni/isaac/fiborobotlab/mooncake/train_karn.py | from env_karn import MoonCakeEnv
from stable_baselines3 import PPO
from stable_baselines3.ppo import CnnPolicy, MlpPolicy
from stable_baselines3.common.callbacks import CheckpointCallback
import torch as th
log_dir = "./mlp_policy"
# set headles to false to visualize training
my_env = MoonCakeEnv(headless=False)
policy_kwargs = dict(activation_fn=th.nn.Tanh, net_arch=[16, dict(pi=[64, 32], vf=[64, 32])])
total_timesteps = 500000
checkpoint_callback = CheckpointCallback(save_freq=10000, save_path=log_dir, name_prefix="mooncake_policy_checkpoint")
# model = PPO(
# CnnPolicy,
# my_env,
# policy_kwargs=policy_kwargs,
# verbose=1,
# n_steps=10000,
# batch_size=1000,
# learning_rate=0.00025,
# gamma=0.9995,
# device="cuda",
# ent_coef=0,
# vf_coef=0.5,
# max_grad_norm=10,
# tensorboard_log=log_dir,
# )
model = PPO(MlpPolicy,
my_env,
verbose=1,
n_steps=10000,
batch_size=100,
learning_rate=0.00025,
)
model.learn(total_timesteps=total_timesteps, callback=[checkpoint_callback])
model.save(log_dir + "/mooncake_policy")
my_env.close()
| 1,169 | Python | 26.209302 | 118 | 0.66296 |
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