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AudioValidation / ggml /src /ggml-cann /kernels /dup.cpp
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#include "kernel_operator.h"
#include <cmath>
using namespace AscendC;
#define BUFFER_NUM 2
template <typename SRC_T, typename DST_T>
class DupByRows {
public:
__aicore__ inline DupByRows() {}
__aicore__ inline void init(GM_ADDR src, GM_ADDR dst, int64_t *input_ne_ub,
size_t *input_nb_ub) {
/* Dup by rows when src is contigous on first dimension and dst is
contiguous, each kernel process one row.
*/
// Input has four dims.
int64_t op_block_num = GetBlockNum();
int64_t op_block_idx = GetBlockIdx();
// param
num_rows = input_ne_ub[1] * input_ne_ub[2] * input_ne_ub[3];
num_elem = input_ne_ub[0];
// index for (ne[1], ne[2], ne[3]): (idx_ne1, idx_ne2, idx_ne3)
idx_ne3 = op_block_idx / (input_ne_ub[1] * input_ne_ub[2]);
idx_ne2 = (op_block_idx - idx_ne3 * (input_ne_ub[1] * input_ne_ub[2]))
/ (input_ne_ub[1]);
idx_ne1 = op_block_idx - idx_ne3 * (input_ne_ub[1] * input_ne_ub[2])
- idx_ne2 * input_ne_ub[1];
// src may not contiguous in dim [1,2,3], so stride decited by ne&nb
src_stride = input_nb_ub[3] * idx_ne3 + input_nb_ub[2] * idx_ne2
+ input_nb_ub[1] * idx_ne1;
// dst is contiguous
dst_stride = op_block_idx * (input_ne_ub[0] * sizeof(DST_T));
src_gm.SetGlobalBuffer(reinterpret_cast<__gm__ SRC_T *>(src +
src_stride));
dst_gm.SetGlobalBuffer(reinterpret_cast<__gm__ DST_T *>(dst +
dst_stride));
pipe.InitBuffer(src_queue, BUFFER_NUM, (sizeof(SRC_T) * num_elem +
32 - 1) / 32 * 32);
pipe.InitBuffer(dst_queue, BUFFER_NUM, (sizeof(DST_T) * num_elem +
32 - 1) / 32 * 32);
}
__aicore__ inline void copy_in() {
LocalTensor<SRC_T> src_local = src_queue.AllocTensor<SRC_T>();
DataCopyExtParams dataCopyParams;
dataCopyParams.blockCount = 1;
dataCopyParams.blockLen = num_elem * sizeof(SRC_T);
DataCopyPadExtParams<SRC_T> padParams;
DataCopyPad(src_local, src_gm, dataCopyParams, padParams);
src_queue.EnQue(src_local);
}
__aicore__ inline void copy_out() {
LocalTensor<DST_T> dst_local = dst_queue.DeQue<DST_T>();
DataCopyExtParams dataCopyParams;
dataCopyParams.blockCount = 1;
dataCopyParams.blockLen = num_elem * sizeof(DST_T);
DataCopyPad(dst_gm, dst_local, dataCopyParams);
dst_queue.FreeTensor(dst_local);
}
__aicore__ inline void dup() {
// main process, copy one row data from src to dst.
copy_in();
LocalTensor<SRC_T> src_local = src_queue.DeQue<SRC_T>();
LocalTensor<DST_T> dst_local = dst_queue.AllocTensor<DST_T>();
int32_t BLOCK_NUM = 32 / sizeof(DST_T);
DataCopy(dst_local, src_local, (num_elem + BLOCK_NUM - 1)
/ BLOCK_NUM * BLOCK_NUM);
dst_queue.EnQue<DST_T>(dst_local);
src_queue.FreeTensor(src_local);
copy_out();
}
__aicore__ inline void dup_with_cast() {
// main process, copy one row data from src to dst.
// cast dtype from src to dst.
copy_in();
LocalTensor<SRC_T> src_local = src_queue.DeQue<SRC_T>();
LocalTensor<DST_T> dst_local = dst_queue.AllocTensor<DST_T>();
Cast(dst_local, src_local, RoundMode::CAST_NONE, num_elem);
dst_queue.EnQue<DST_T>(dst_local);
src_queue.FreeTensor(src_local);
copy_out();
}
private:
TPipe pipe;
GlobalTensor<SRC_T> src_gm;
GlobalTensor<DST_T> dst_gm;
int64_t num_rows;
int64_t num_elem;
int64_t idx_ne3;
int64_t idx_ne2;
int64_t idx_ne1;
int64_t src_stride;
int64_t dst_stride;
TQue<QuePosition::VECIN, BUFFER_NUM> src_queue;
TQue<QuePosition::VECOUT, BUFFER_NUM> dst_queue;
};
template <typename T>
__aicore__ inline void copy_to_ub(GM_ADDR gm, T *ub, size_t size) {
auto gm_ptr = (__gm__ uint8_t *)gm;
auto ub_ptr = (uint8_t *)(ub);
for (int32_t i = 0; i < size; ++i, ++ub_ptr, ++gm_ptr) {
*ub_ptr = *gm_ptr;
}
}
extern "C" __global__ __aicore__ void ascendc_dup_by_rows_fp16(
GM_ADDR src_gm,
GM_ADDR dst_gm,
GM_ADDR input_ne_gm,
GM_ADDR input_nb_gm,
GM_ADDR output_ne_gm,
GM_ADDR output_nb_gm) {
int64_t input_ne_ub[4];
size_t input_nb_ub[4];
int64_t output_ne_ub[4];
size_t output_nb_ub[4];
copy_to_ub(input_ne_gm, input_ne_ub, 32);
copy_to_ub(input_nb_gm, input_nb_ub, 32);
copy_to_ub(output_ne_gm, output_ne_ub, 32);
copy_to_ub(output_nb_gm, output_nb_ub, 32);
DupByRows<half, half> op;
op.init(src_gm, dst_gm, input_ne_ub, input_nb_ub);
op.dup();
}
extern "C" __global__ __aicore__ void ascendc_dup_by_rows_fp32(
GM_ADDR src_gm,
GM_ADDR dst_gm,
GM_ADDR input_ne_gm,
GM_ADDR input_nb_gm,
GM_ADDR output_ne_gm,
GM_ADDR output_nb_gm) {
int64_t input_ne_ub[4];
size_t input_nb_ub[4];
int64_t output_ne_ub[4];
size_t output_nb_ub[4];
copy_to_ub(input_ne_gm, input_ne_ub, 32);
copy_to_ub(input_nb_gm, input_nb_ub, 32);
copy_to_ub(output_ne_gm, output_ne_ub, 32);
copy_to_ub(output_nb_gm, output_nb_ub, 32);
DupByRows<float_t, float_t> op;
op.init(src_gm, dst_gm, input_ne_ub, input_nb_ub);
op.dup();
}
extern "C" __global__ __aicore__ void ascendc_dup_by_rows_fp32_to_fp16(
GM_ADDR src_gm,
GM_ADDR dst_gm,
GM_ADDR input_ne_gm,
GM_ADDR input_nb_gm,
GM_ADDR output_ne_gm,
GM_ADDR output_nb_gm) {
int64_t input_ne_ub[4];
size_t input_nb_ub[4];
int64_t output_ne_ub[4];
size_t output_nb_ub[4];
copy_to_ub(input_ne_gm, input_ne_ub, 32);
copy_to_ub(input_nb_gm, input_nb_ub, 32);
copy_to_ub(output_ne_gm, output_ne_ub, 32);
copy_to_ub(output_nb_gm, output_nb_ub, 32);
DupByRows<float_t, half> op;
op.init(src_gm, dst_gm, input_ne_ub, input_nb_ub);
op.dup_with_cast();
}
extern "C" __global__ __aicore__ void ascendc_dup_by_rows_fp16_to_fp32(
GM_ADDR src_gm,
GM_ADDR dst_gm,
GM_ADDR input_ne_gm,
GM_ADDR input_nb_gm,
GM_ADDR output_ne_gm,
GM_ADDR output_nb_gm) {
// copy params from gm to ub.
int64_t input_ne_ub[4];
size_t input_nb_ub[4];
int64_t output_ne_ub[4];
size_t output_nb_ub[4];
copy_to_ub(input_ne_gm, input_ne_ub, 32);
copy_to_ub(input_nb_gm, input_nb_ub, 32);
copy_to_ub(output_ne_gm, output_ne_ub, 32);
copy_to_ub(output_nb_gm, output_nb_ub, 32);
DupByRows<half, float_t> op;
op.init(src_gm, dst_gm, input_ne_ub, input_nb_ub);
op.dup_with_cast();
}